Program - NSS/MIC

Transcription

Program - NSS/MIC

2012 IEEE NSS/MIC/RTSD Anaheim, California
27 October - 3 November 2012
IEEE Nuclear Science Symposium and
Medical Imaging Conference
19th International Workshop on
Room-Temperature Semiconductor
X-Ray and Gamma-Ray Detectors
Conference Program
Sponsoring Institutes
and Companies
The 2012 Nuclear Science Symposium
and Medical Imaging Conference is
Sponsored by:
The Nuclear and Plasma Sciences
Society of the Institute of Electrical
and Electronics Engineers
With generous
contributions from:
• DOE/NNSA
Office
of
Nonproliferation and Verification
Research & Development, NA-22
• GE Healthcare
• FLIR
• Kromek
• National Institutes of Health
• ORTEC
• Philips
• Siemens
• Toshiba
In cooperation with:
• Brookhaven National Laboratory,
USA
• CEA Saclay, France
• DESY, Germany
• IAEA, Austria
• Lawrence Berkeley National Lab,
USA
• Northrop Grumman Corp. USA
• University of Washington, USA
Adventure Tower
Outpost
Explorer
Nile
Adventure
Safari
Wilderness
Western
Tiki
Amazon
Oasis
Pioneer
Columbia
Mississippi
Mark Twain
Frontier
Board Room
Frontier Tower
Mark Twain Terrace
D
A
Pacific Ballroom
A
C
Pacific Ballroom Foyer
Cristal Cove Room
Paradise Pier Hotel
Ground Level
Paradise Pier Hotel
Upper Level
Congo
Zambezi
Convention Center
Ground Level
First Level
Basement Level
Table of Contents
Color Code
3
Session3
Daily Program
3
Additional Daily Schedule Colors
3
Welcome from the General Chair
4
Registration & Fees
6
Electronic Registration
6
On-site Registration
6
Badge Policies 7
Registration Hours at the Conference
7
Conference Registration Fees
8
Luncheon/Dinner Fees
8
Short Course Fees
8
Cancellation and Refund Policy
8
IEEE Membership
9
General Information
10
Hotel and Conference Center
10
Transportation10
Parking11
Weather11
Message Board
11
Computer Access
11
Special Social Activities
11
Companion Program
13
Presentation & Poster Guidelines
20
Oral Presentation Instructions
20
Poster Presentation Instructions
20
Publications21
Conference Record
21
Transactions on Nuclear Science (TNS) 22
Transactions on Medical Imaging (TMI)
23
Comparison of Requirements
23
Short Course Program
25
Industrial Program
38
List of Exhibitors (as of July 10, 2012)
39
ExhibitorTechnical Sessions
40
Special Focus Workshops
41
Special Events
44
Linear Collider Event
46
Nuclear Science Symposium - NSS
53
NSS PlenaryTalks
55
NSS LuncheonTalk
60
NSS Refresher Courses
62
Medical Imaging Conference - MIC
64
MIC PlenaryTalks
66
MIC Refresher Courses 69
RTSD71
Table of Contents 1
19th International Workshop on Room-Temperature Semiconductor X- and
Gamma Ray Detectors
71
Joint Sessions
72
Scientific Program
73
Sunday - Workshop Oral Presentations
75
Monday - NSS Oral Presentations
81
Monday - RTSD Oral Presentations
84
Monday - Linear Collider Event Oral Presentations
86
Monday - NSS Poster Presentations
87
Monday - RTSD Poster Presentations
106
Tuesday - NSS Oral Presentations 117
Tuesday - RTSD Oral Presentations
124
Tuesday - Joint Oral Presentations
125
Tuesday - Linear Collider Event Oral Presentations
127
Tuesday - NSS Poster Presentations
129
Tuesday - RTSD Poster Presentations
148
Wednesday - NSS Oral Presentations
155
Wednesday - MIC Oral Presentations
166
Wednesday - RTSD Oral Presentations
169
Thursday - NSS Oral Presentations
177
Thursday - MIC Oral Presentations
188
Thursday - RTSD Oral Presentations
193
Thursday - MIC Poster Presentations
196
Friday - NSS Oral Presentations
215
Friday - MIC Oral Presentations
218
Friday - RTSD Oral Presentations
221
Friday - Joint Oral Presentations
223
Friday - Workshop Oral Presentations
224
Friday - MIC Poster Presentations
226
Saturday - MIC Oral Presentations
255
Saturday - MIC Poster Presentations
256
Author Index
271
Contributions from Collaborations
271
Contributions from Individuals
272
Acknowledgement318
NSSTopic Conveners
319
NSS Reviewers 319
MIC Reviewer
325
RTSD Steering Committee
331
Conference Information and Promotion (CIP) Committee
331
Contact Information
336
2013 NSS/MIC/RTSD
344
2 Table of Contents Color Code
We have implemented a simple color coding scheme in an effort to
provide a guide in the use of this program booklet and to consistently
indicate the content of any given section.
The program section is divided by weekday to provide a complete
package of sessions for each conference day. Each daily section
includes oral, poster, joint, and special sessions and workshops.
The page color for oral and poster session content is reversed for
clarity: oral presentation listings are contained in colored pages with
the day indicated with a lighter watermark. Poster presentation pages
are light color with a darker watermark.
At the beginning of each day, a Daily Schedule is presented to give an
overview of the events for the respective day. The Daily Schedule uses
the same colors used for each respective program. The colors shown
below are used as indicated.
Session
NSS Sessions
MIC Sessions
RTSD Sessions
Joint Sessions
Workshops or Special Events Sessions
Daily Program
Sunday
Monday
Tuesday
Wednesday
Thursday
Friday
Saturday
Additional Daily Schedule Colors
Industrial Exhibit
Short Courses
Social Activities
Color Code 3
Welcome from the General Chair
D
ear Colleagues and Friends,
it’s Fall and it’s time for the
NSS/MIC/RTSD meeting again!
The 2012 IEEE Nuclear Science Symposium
and Medical Imaging Conference, together
with the Workshop on Room-Temperature
Semiconductor X-Ray and Gamma-Ray
Detectors will be held at the Disneyland
Hotel (Anaheim, California), from October
Tom Lewellen
29th to November 3rd. This meeting has
always been a great opportunity to get together with old friends
and to make new ones, to exchange ideas and share knowledge and
experience in the nuclear science and medical imaging fields - and
2012 will be no exception.
Our technical chairs have once again assembled a varied and
outstanding program of presentations. As with previous meetings,
there will be short courses on the preceding Saturday and Sunday
(October 27 and 28) continuing on through Monday. There will also
be refresher courses on several NSS and MIC topics during the week.
In addition, we anticipate having several workshops. For example,
there will be a two-day Linear Collider Event (October 29-30). Details
can be found on the conference web site (www.nss-mic.org/2012).
space will be specifically set up to allow both the exhibitors and
attendees ample space for discussions and exploration of common
interests.
Overall, the traditional excellence of the NSS, MIC, and RTSD
programs will be continued and enhanced in 2012 with the
combination of outstanding presentations, educational sessions,
special emphasis seminars, and a venue that will promote the informal
exchange of ideas and information.
Social events include the exhibitor reception on Tuesday, the general
conference reception on Wednesday, and the NSS Luncheon, RTSD
Luncheon, and MIC Dinner. There will also be other events for
smaller groups such as the Gold Reception and the special Women
In Engineering session. And if all goes well, we should have a few
additional surprises along the way. All in all, a very full week.
I look forward to seeing you in Anaheim.
Tom Lewellen
General Chair
While the venue will be relaxing, offering many options when one is
not attending sessions, the main purpose of this meeting continues to
be the exchange of information in the many scientific and engineering
disciplines represented by the attendees. The NSS portion of the
conference is an ideal forum for scientists and engineers in the field
of nuclear science, radiation instrumentation, software engineering,
data acquisition, and related applications to present their work and
network with their colleagues from around the world. Similarly, the
MIC has consistently provided one of the most productive forums
for the exchange of information on the physics, engineering, and
mathematics of Nuclear Medicine. The MIC goes further with many
contributions from other areas of medical imaging, including X-ray
and magnetic resonance imaging. The RTSD is an ideal companion
to the NSS and MIC programs with topics of interest common to
both fields. The conference will be making special efforts to obtain
support grants for students to attend this important meeting and take
full advantage of the unique scientific and educational opportunity.
The conference will also include an industrial exhibition where the
providers and developers of many of the technologies and services
used by our attendees will be presenting their products. The exhibit
4 Welcome from the General Chair Welcome from the General Chair 5
Registration & Fees
P re-registration is advisable
to save time and money,
and to ensure your
registration package will be
available for collection when
you arrive. The only registration
method is through the conference
web site, where you can pay by
Christina
Visa, MasterCard, American
Sanders
Express or Discover through our
secure web server. Checks or money orders must be drawn on or paid
through a U.S. bank and be in U.S. dollars. Note: Checks WILL
NOT be accepted on-site. On-site payment will only be accepted
with credit card, money order or cash. Wire transfers will be accepted
only under special circumstances, and will be charged a $25 service
fee. For wire transfer information please contact TDMG (see below).
Note: The online registration site will be closed on Wednesday,
October 24 at at midnight EDT and will reopen on Friday, October
26 at 17:00 EDT.
Badge Policies
All badges and conference materials must be picked up at the
Registration desk. Government issued photo identification (e.g.,
driver’s license, passport) is required. For security purposes, all attendees
are required to wear their badge for entry into session rooms. It is your
responsibility to ensure that you have your badge at all times. There is
a charge of $10 for badge replacement. No exceptions will be made.
Attendee Badges
•
•
•
•
Access into all scientific sessions
Access to the Conference Reception and Exhibitor Reception
Access to the Exhibit Hall and Poster Sessions
Access to tours and meals for which tickets have been purchased
Companion Badges
Note: Registration and payment must be received by October 12,
2012 to qualify for reduced registration, lunch, tours, dinner and
short course fees.
• Access to tours and meals for which tickets have been purchased
• Access to the Conference Reception and Exhibitor Reception
Electronic Registration
The IEEE Registration Desk will be located in the Center Lounge
of the Disneyland Hotel Exhibition Center.
Only electronic registration is accepted. Click on the Conference
Registration link at: https://www.nss-mic.org/2012 and follow
the instructions. You may update an existing registration at
https://www.nss-mic.org/2012/registration/reg_rev.asp.
To make payment by mail:
Send payment (made out to IEEE 2012 NSS/MIC) to:
IEEE 2012 NSS/MIC
c/o TDMG Meetings Dept.
110 Painters Mill Road, Suite 36
Owings Mills, MD 21117 USA
Tel: +1 800 437 4589 (US and Canada only)
+1 410 363 1300 (08:30-17:30 EDT)
Fax: +1 410 559 0160 (attn: IEEE 2012 NSS/MIC)
An acknowledgement of your registration will be sent upon its
receipt and payment. Please address any questions via e-mail to
[email protected] (Attn: IEEE 2012 NSS/MIC) or by phone.
Registration Hours at the Conference
Registration and general information will be available during the
following times at the IEEE Registration Desk.
Friday, October 26
17:00-20:00
Saturday, October 27
07:30-09:30
15:30-18:30
Sunday, October 28
07:30-09:30
15:30-18:30
Monday, October 29
07:30-18:30
Tuesday, October 30
07:30-18:30
Wednesday, October 31
07:30-18:30
Thursday, November 1
07:30-17:00
Friday, November 2
07:30-12:00
Saturday, November 3
07:30-09:00
On-site Registration
To alleviate long lines and minimize hand-written registration forms,
all on-site registration will be done via the online registration page. If
you choose to register on-site, you must first register yourself online.
You may do this via any computer with internet access. There will be
computers in the registration area or the computer room that you may
use to register.
6 Registration & Fees Registration & Fees 7
Conference Registration Fees
IEEE Member1
By
Oct. 12
After
Oct. 12
$500
$600
Non-IEEE Member
$650
$750
IEEE Student1,2
$200
$300
Non-IEEE Student2
$300
$400
One Day Only3
$200
$200
IEEE Retired/Unemployed1
$150
$200
IEEE Life Member1,4
No Charge
No Charge
Continuing Education Program Only
No Charge
No Charge
1 IEEE member number required at registration.
2 Proof of student status required at registration.
3 Valid for one occurrence only – if more than one day, full registration will be charged.
4 IEEE Life Members must contact the Registration Chair ([email protected])
prior to registering to receive their fee waiver.
Luncheon/Dinner Fees
By
Oct. 12
After
Oct. 12
NSS Luncheon (Mon., Oct. 29)
$30
$40
RTSD Luncheon (Tue., Oct. 30)
$30
$40
MIC Dinner (Fri., Nov. 2)
$70
$80
received in writing by October 19, 2012. No refunds will be issued
after that date.
IEEE Membership
An IEEE Membership Desk will be located in the Center Lounge
near the Registration Desk. Staff will be available to answer questions
about membership benefits.
Conference attendees who paid non-member registration fees are
eligible for a $100 discount towards a regular (non-student) IEEE 2013
membership that also includes free membership in NPSS -- all courtesy
of NPSS. Students joining at the conference can receive a year’s free
membership by providing a statement from their mentor that they are
full-time students.
Access to the Transactions on Nuclear Science and Transactions on
Plasma Science journals, as well as the NPSS newsletter is included
with NPSS membership. Please visit the IEEE Membership Desk to
take advantage of these offers.
Note that new membership obtained at the Conference is not eligible
for the reduced IEEE member registration fees.
Short Course Fees
Short Course
By
Oct. 12
After
Oct. 12
SC1 - Radiation Detection and
Measurement
$500
$560
SC2 - Nuclear Science for Nuclear
Security
$320
$380
SC3 - Integrated Circuit Front Ends for
Nuclear Pulse Processing
$320
$380
SC4 - Advanced Photodetectors
$320
$380
SC5 - Molecular Biology for Imaging
Scientists
$320
$380
SC6 - Medical Image Reconstruction
$320
$380
SC7 - Physics & Design of Detectors for
PET and SPECT
$320
$380
Note: IEEE Members receive a $60 discount on Short Course fees.
Cancellation and Refund Policy
You are not officially registered until we receive your completed
registration form and payment. If your payment is not received by
the October 12 deadline, your registration will be cancelled. In order
to process refunds (less a $50 cancellation fee), cancellations must be
8 Registration & Fees Registration & Fees 9
General Information
Robert Miyaoka
Tony Lavietes
Driving directions by car from airports
From John Wayne/Orange County Airport take I-405 North toward
Long Beach. Take exit 9A to merge onto CA-55 North. Take exit
10B to merge onto I-5 North toward Santa Ana. Take exit 110
for Harbor Blvd toward Ball Rd. Turn left onto S Harbor Blvd.
Disneyland resort is at 1313 S Harbor Blvd, Anaheim, CA 92802.
From Los Angeles International Airport take I-105 East. Take exit
18 for I-605. Merge onto I-605 South. Take exit 7A to merge onto
CA-91 East. Take exit 24 to merge onto I-5 South toward Santa
Ana. Take exit 110A for Harbor Blvd toward the Convention Center.
Follow signs for Harbor Boulevard S and merge onto S Harbor Blvd.
Disneyland resort is at 1313 S Harbor Blvd, Anaheim, CA 92802.
Hotel and Conference Center
Other Transportation Options
The meeting will be held at the Disneyland® Hotel Convention
Center (Anaheim, California), with rooms reserved for attendees at
the Disneyland® Hotel and Disney Paradise Pier Hotel.
Details
on
other
transportation
options
(including
other airports and train stations) can be found at:
http://disneyland.disney.go.com/plan/guest-services/transportation/
The hotel rooms have been recently renovated and will include free
overnight parking, unlimited local telephone and 800 access, free
internet access, and unlimited use of the fitness center. The hotels
are a short walk (less than 5 minutes) from many restaurants, shops,
movie theaters, and other options in the Downtown Disney area.
Parking
The standard conference rate at these two hotels is $169/night. A
limited number of student rooms at $128/night, as well as a limited
number of rooms at the prevailing government rate are available.
The rooms include one round trip voucher for the Disneyland
Resort Express bus service (to/from the airport) for one of the room
occupants.
When you register on-line at one of the Disneyland® hotels, you will
also have the ability to purchase discounted Theme Park tickets. Oneday, multi-day, and special twilight tickets are available. Twilight
tickets allow theme park admission from 16:00 or four hours before
park closing, whichever is earlier. These tickets are only available online and prior to arrival. Theme park tickets are also available at the
hotel front desk but not at the discounted rate.
Hotel rooms can be reserved through the conference web site
(www.nss-mic.org/2012) under Hotel Reservations. Conference rates
are valid until Tuesday, September 25, 2012, after which prevailing
rates may apply. Availability is limited, so we encourage you to make
your reservation as soon as possible.
Please note that the Disneyland Hotel Convention Center and the
Disneyland Hotel are smoke-free facilities. Smoking is permitted only
in designated outdoor smoking locations.
Transportation
Airports
The closest airport is the Orange County airport (also known as
the John Wayne airport). For direct international flights, the best
airport is Los Angeles International airport. Both of these airports
are serviced by the Disneyland Resort Express bus service. There are
additional options for taxis, share ride vans, and public transport.
10 General Information Free overnight parking is available at the Disneyland Hotel for
guests. Complimentary self parking is also provided for all registered
conference attendees.
Weather
The weather in Anaheim in the late October - early November period
is generally very nice with daytime temperatures in the mid to low
70s (20°C to 24°C) and nighttime temperatures in the low 50s (10°C
to 12°C).
Message Board
A message board will be set up near the Conference Registration
desk. Any last minutes changes in the scientific program and other
important information will be posted on the message board.
Computer Access
Computers, printers, and technical support will be located in the
South Lounge. The facility is intended for use by all attendees to
carry out final editing of their presentations and papers and to retrieve
e-mail. Microsoft Office 2010 will be loaded on all computers. In
addition, wireless hotspots will be available in certain areas.
Special Social Activities
The conference program includes a number of social activities open to
all attendees, some of which are complimentary. The table below is
the list of lunches, dinners, and receptions (including any applicable
fees) that are scheduled during the conference.
Please note that the Conference Reception is a buffet dinner event
and the Exhibitor Reception is a drink and finger-food event.
General Information 11
Event
Date/Time
Location
Fees
NSS Luncheon
Mon.Oct.29
12:30
Pacific Ballroom
Paradise Pier Hotel
$30/$40
Exhibitor Reception
Tue.Oct 30
19:00
Exhibit Hall
Disneyland Hotel
Free
Conference Reception
Wed.Oct.31
19:00
Mark Twain & Lawn
Frontier Tower
Free
RTSD Luncheon
Tue.Oct.30
12:30-14:30
Rainforest Café,
Downtown Disney
$30/$40
MIC Dinner
Fri.Nov. 2
19:00
Studio 51, California
Adventure
$70/$80
The Disneyland Hotel Convention Center is within easy walking
distance to the Downtown Disney District which includes many
entertainment options, a wide collection of dining experiences and
plenty of shopping opportunities.
12 General Information Companion Program
Barb Lewellen
Carolyn Hoffman
Anaheim, home of Disneyland, was founded by fifty German families
in 1857 and incorporated as the second city in Los Angeles County
on February 10, 1870. Anaheim developed into an industrial center,
producing electronics, aircraft parts and canned fruit. Its name
is a blend of “Ana”, after the nearby Santa Ana River, and “heim”,
a common German place name compound originally meaning
“home”. Anaheim is now part of Orange County, California, which is
world-famous for tourism. A small county, there are charming seaside
communities along the Pacific Ocean, the Orange Coast, a string of
seaside jewels that have been compared with the French Riviera or
the Costa del Sol. Forty-two miles of beaches offer pristine stretches
of sand, tide pools teeming with marine life, ecological preserves,
secluded coves, picturesque pleasure-boat harbors, and legendary surf
breaks. The county also includes the Rancho Mission Viejo, an 1845
Mexican Land Grant in the Saddleback Mountains, part of which is
still a working cattle and sheep ranch. The architecture of the area
ranges from Mission Spanish of San Juan Capistrano to the ultramodern Crystal Cathedral.
The Companion Program provides a daily selection of guided
excursions to places of interest both within and outside of the
conference site. All tours will depart from and return to the Companion
Program Meeting Area, the Adventure Room in the Adventure
Tower. This meeting area will be available as a lounge for all registered
companions to gather during the conference. Information about the
Anaheim area will also be available for individuals and families to
plan trips and excursions other than those offered in the Companion
Program. This is an exciting program, and we look forward to seeing
you in Anaheim. Please contact either of us for more information.
Barb Lewellen
Companion Program Co-Chair
Carolyn Hoffman
Companion Program 13
Tour Number and Name
Date
Time
Price
T1 - Bowers Museum of
Cultural Art
Sun. Oct. 28
13:30-16:30
$65
T2 - Mission San Juan
Capistrano
Mon. Oct. 29
08:30-13:30
$45
T3 - San Diego Zoo Safari Park
Tue. Oct. 30
08:30-18:00
$95
T4 - Tour of Queen Mary
Wed. Oct. 31
09:00-14:00
$55
T5 - Pyrotech Launch Area
Wed. Oct. 31
13:30-14:30
$65
$95
T6 - Wine 101
Thu. Nov. 1
13:00-16:00
T7 - Crystal Cove Nature Hike
Fri. Nov. 2
08:30-13:30
$75
T8 - Animation Shop
Fri. Nov. 2
11:00-12:00
$65
T9 - Nixon Library & Old Town
Orange
Sat. Nov 3
09:30-14:15
$45
Pacific Island, Pre-Columbian, Native American, and Asian. The natural
history collections encompass over 40 million years of history with fossils,
seashells, plant life and mounted animal specimens.
T2 - Mission San Juan Capistrano
Monday, October 29, 8:30-13:30
Location: San Juan Capistrano
Cost: $45
Snuggled in a country setting is the historic Mission San Juan
Capistrano, well known for its “return of the swallows” each year and
as “the jewel” of the California missions. The wide spreading adobe
of Mission San Juan Capistrano reveals a glorious chapter in early
California history. Founded in 1776, it is considered to be the oldest
NOTE: These prices are for pre-registration only. Add $10 per tour
for registration on-site.
There will be a breakfast available for participants in the morning
programs starting one hour before the tour starts. This will be served in the
Companion Program’s room (Adventure Room in the Adventure Tower).
T1 - Bowers Museum of Cultural Art
Sunday, October 28, 13:30-16:30
Location: Santa Ana
Cost: $65
One of Southern California’s finest museums and Orange County’s
largest, the Bowers Museum is one of the only museums in the United
States devoted to promoting human understanding through art. Its
state of the art special exhibition and collection storage facilities
enable the Bowers to present world class exhibitions and preserve
collections of cultural art for future generations.
The museum was originally founded to house Early (Rancho) California
and Orange County history exhibits. Today, in addition to these extensive
collections, additional permanent exhibits include: Africa, Oceanic/
mission and once the most prosperous of the chain. The swallows
still arrive every March 19th on St. Joseph’s Day and leave October
23rd on St. John’s Day to begin their 6,000-mile journey back to
Argentina where spring has just begun again. An expert tour guide
will greet guests upon arrival at the gates of the mission. Within
minutes, guests will discover the enchantment of this living historical
landmark, as the docent-led tour leads them through pristine gardens,
soldier barracks, and beautiful archeological monuments. Take a step
back into the rich history of California and experience life as it was
during the era when the Franciscan Missions flourished and shaped
California’s future.
Note: Free time will be given for lunch on one’s own in Downtown
San Juan Capistrano. We recommend “California casual” attire and
a light jacket.
T3 - San Diego Zoo Safari Park
Tuesday, October 30, 8:30- 18:00
Location: San Diego
Cost: $95
When a typical afternoon activity just won’t do, consider a place
that knows no boundaries. Get a unique view of the San Diego
Zoo Safari Park! The San Diego Zoo Safari Park is a unique preserve
where many species of exotic animals can be seen roaming free in
surroundings similar to that of their native homelands. The Park is a
zoological facility like no other, with expansive 100-acre field exhibits
and endangered species from around the world. Enjoy activities that
allow a more in-depth understanding of the animals and the Park’s
14 Companion Program Companion Program 15
conservation activities, with up-close animal encounters, and more.
Providing the best possible care for the animals is the Park’s top
priority. There are more than 3,000 animals at the Park, many of
which are threatened or in danger of becoming extinct. The Park
has made its mark on worldwide conservation of many endangered
species, including the “awe-inspiring” cheetahs and lions. Guests will
have a chance to hear stories of how the successes at the Park are
making a difference for wildlife around the world.
Note: Free time to visit attractions, stores and have lunch on one’s own. We
recommend “California casual” attire, comfortable shoes and a light jacket.
T4 - Tour of Queen Mary
Wednesday, October 31, 9:00-14:00
Location: Long Beach
Cost: $55
In May of 1936, with her three massive, one-ton whistles blasting the
air, the Queen Mary embarked on her maiden voyage and ushered in
a new era of travel, redefining the meaning of luxury, and showing
the world the marvelous results of beauty and technology combined.
Today guests can “book passage” and be a part of the history of a
ship that is included on The National Register of Historic Places. A
“Behind the Scenes” tour takes guests on a private inspection, from
the First Class Suites to the Boiler Room.
Following this exclusive tour, explore the public areas of this giant liner
at leisure. Docked on the shores of Long Beach harbor, the Queen
boasts a unique perspective of the bustling port. En route from the
Queen Mary, guests will enjoy a guided coastal tour from one of our
knowledgeable tour company staff members. Both informative and
entertaining, everyone will leave feeling like a true California native!
Note: Guests will have free time onboard ship. A souvenir guide map
will be provided for each guest. Lunch will be on one’s own.
of the night time fireworks performance. Across the road is the
patented Air Launch System; a series of pneumatic tubes that fire
compressed air in order to launch pyrotechnic shells. Guests will
stand outside the control booth and be greeted by an Entertainment
Pyro Cast Member who provides a 10 - 15 minute overview of
how the system was developed, what it’s ecological benefits are and
how Disney works with similar entertainment groups to share their
design. When available, the Cast Member will run a “test” of the
system wherein the tubes expel air in a rapid 10 - 15 second pattern to
ensure all systems are functioning properly. Guests will be able to ask
questions at the conclusion of the presentation, but are not permitted
to enter the fenced off area around the Air Launch tubes. Backstage
photos are prohibited at all times.
Note: Guests will have to buy their own day ticket to stay in the park.
T6 - Wine 101
Thursday, November 1, 13:00-16:00
Location: Orange County
Cost: $95
The Wine Artist is Orange County’s first custom winery that is
dedicated to enriching the wine selection process by allowing
customers to interactively participate in making their own wine!
Step 1 -Visit the winetasting bar and enjoy wine tasting…some of
which you will soon bottle!
Step 2 - Once a selection has been made guests, with the assistance of
our staff, participate in bottling, corking, and foiling.
Step 3 – Labeling is next. Choose from a wide selection of stylish labels.
Personalize labels with your message and artwork; a photograph or
company logo can be used to add a special touch to the variety you create.
Step 4 – Bottles are placed in an easy to carry case and simply take
your custom vintage home for proper aging and enjoy!
Traditional varietals have been selected for your group: Chardonnay,
Pinot Grigio, Merlot, Pinot Noir and a Tuscan Blend (very popular).
Note: Wine Tasting includes Four Glasses (3-ounce pour).
Recommended age group: 21 Years and older
T5 - Pyrotech Launch Area
Location: Disneyland Park
Cost: $65
Guests are escorted backstage through the Toon Town Alley Gate
next to Minnie’s House in Toon Town to the pad between the Parade
Float Building and the Disney Performing Arts Lot, along the North
Service Road. This location features the control booth for operation
16 Companion Program Shipping Info: There are no shipping restrictions to individuals
within Alaska, Arizona, California, Colorado, Idaho, Illinois, Iowa,
Minnesota, Missouri,
New Mexico, North
Dakota,
Oregon,
Washington,
and
West Virginia. In
addition,
federal
law
allows
an
individual to carry
wine or ship wine
to him so long as
he is not entering a
“dry” county. Therefore, any wine sold to your guests through the
Wine Facility is sold in California and title passes to that guest, the
buyer. The buyer is now able to ship to himself or carry it home via
checked luggage.
Companion Program 17
T7 - Crystal Cove Nature Hike
Friday, November 2, 8:30-13:30
Location: San Juan Capistrano
Cost: $75
Crystal Cove State Park offers three and half miles of unobstructed
pristine beach, and remains the most natural beach in Orange
County. Trails meander along the bluffs, and then lead down to
the beach. A strong wildlife population includes coyotes, squirrels,
raccoons, rabbits, deer, bobcats, opossum, hawks, and a variety of
inland and coastal birds.
Walking along coastal bluffs through a mosaic of native plants, you’ll
enjoy a panoramic overview of the sparkling Pacific Ocean. Guests
will discover (through smell, feel, and taste) that the plants they’re
passing are the same ones that early Native American Indians used for
medicine, food, tea, utensils, and musical instruments.
As guests descend the trails onto the beach, they’ll be amazed to learn
about the sophistication of the dolphin societies, whose members are
often seen playing in the waves.
All of the wild life and history will come to life with Doug
Thompson - our guests’ personal Naturalist during this tour. Doug
is an accomplished writer, ecologist and internationally recognized
naturalist, whose refreshing viewpoint and inspiring lectures are both
professional and engaging.
Animation Shop and its role in maintaining and repairing audioanimatronic and non-motion characters and animals within Resort
attractions. Guests will be able to ask questions at the conclusion of
the presentation, but are not permitted to enter either bay door into
the building. Backstage photos are prohibited at all times.
Note: Guests will have to buy their own day ticket to stay in the park.
T9 - Nixon Library & Old Town Orange
Saturday, November 3, 9:30-14:15
Location: Orange County
Cost: $45
One of Orange County’s most notable residents, Richard Nixon was
born on January 9, 1913, in a quaint farmhouse in Yorba Linda.
Today, the Birthplace has been restored with attention to historical
detail, on the exact spot where President Nixon’s father built it.
Although security and sprinkler systems have been installed, no part
of the house was rebuilt. Most of the furnishings, including the bed
where the President was born and the piano he learned to play are
original. In addition to the original home of our 37th president, the
nine acre Library & Birthplace is a three-dimensional walk-through
memoir featuring a 52,000 square foot museum, 22 high-tech
galleries, movie and interactive video theaters, the spectacular First
Lady’s Garden, and the flower-ringed memorial sites of President and
Mrs. Nixon. Following the docent-led tour of the museum, guests
will be transferred to Orange County’s namesake – the city of Orange,
one of the oldest and most “famous” cities in the county. The Orange
plaza and outlying areas have set the stage for many silver-screen gems
including That Thing You Do!, Big Momma’s House, The Adventures
of Rocky and Bullwinkle, Accepted and many, many more! Guests
will have the opportunity to browse through a multitude of antique
stores and maybe even catch a glimpse of a film crew in action!
Note: Free time in Old Town Orange following the tour. Lunch on
one’s own. We recommend comfortable walking shoes. This tour is
appropriate for most levels of walking.
Note: Snacks (granola bar) and a bottle of water will be provided for
each guest. Be sure to wear comfortable shoes. This is a nature hike,
not a power hike. OK for all levels of hiking.
T8 - Animation Shop
Friday, November 2, 11:00-12:00
Location: Disneyland Park
Cost: $65
At the back of Small World this location features the working metal
and mechanical parts shop where all Disneyland Resort ride vehicles
are serviced and repaired. Guests will stand outside the bay doors
and be greeted by a Facilities Cast Member who will provide a 5 - 10
minute overview of the locations role in supporting the 4 Keys of
Guest Service at the Resort and the Safety and Show Quality standards
that make each ride so distinct and popular. Followed by this piece,
guests will walk next door to Bay #7 to receive an overview of the
18 Companion Program Companion Program 19
Presentation & Poster Guidelines
Oral Presentation Instructions
Presentation files must be in Windows-compatible PowerPoint or
PDF format. Note that the laptops used for the presentations are
under Windows 7 with PowerPoint 2010 and the latest version of
Acrobat Reader. The file for your talk must be loaded onto the central
file server no later than 2 hours prior to the start of your session. For
a talk in the first morning session, the file must be loaded the previous
day. To do this, take the file, preferably on a USB flash drive, to the
Computer Room in the South Lounge, and one of the computer
room staff members will assist you. Note that presenters will not be
permitted to use their own laptops. Please check your presentation
carefully before you leave the Computer Room.
Poster Presentation Instructions
All posters will be in Exhibit Hall, Disneyland Hotel. The poster
panels are made to accommodate posters of a maximum size of 3’x6’
(91 cm x 182 cm). DIN-A0 posters (84 cm x 119 cm) can easily
fit in a panel. Adhesive tape to attach your poster to the panel will
be available in the poster room. Your panel will be labeled with the
session and number of your poster, also referred to as your “Paper
ID.”
Presenting authors are expected to be present at their poster during
their session. Papers whose authors are not present at their poster
during their assigned session are not eligible for publication in the
Conference Record. Session chairs will verify your attendance during
the assigned session.
The NSS, RTSD, and MIC posters will share the same space with their
respective display times shown in the table below. It is recommended
that poster authors display their posters for the entire allotted period.
At a minimum, the poster must be in place no later than 2 hours
prior to the start of the assigned poster session. After that time the
poster board will be labeled as no-show and no late installation will
be allowed.
NSS
Install
Remove
Sun. 17:00 to Mon. 08:00
Wed. 16:00-17:00
MIC
Wed. 18:00 to Thu. 08:00
Sat. 13:00-14:00
RTSD
Sun. 17:00 to Mon. 08:00
Wed. 16:00-17:00
Note: Posters that are not removed on time will be subject to disposal.
20 Presentation & Poster Guidelines Publications
Conference Record
The Conference Record (CR) is the official
repository for manuscripts presented at the
2012 Nuclear Science Symposium and Medical
Imaging Conference and will be on DVD-ROM,
complimentary to all registered conference
attendees, and submitted to the IEEE Xplore for
Bo Yu
publication. All CR manuscripts will be made
available online at http://www.nss-mic.org/2012/ConferenceRecord
before the DVD-ROMs are mailed out.
The approved word processor templates, available in PDF,
MS Word and LaTeX format can be downloaded from
http://www.nss-mic.org/2012/Public/Publications/templates.htm.
All manuscripts submitted to the IEEE must be in IEEE
Xplore-compatible PDF format. To assist authors in meeting
this requirement, IEEE has established a web based service called
“PDF eXpress.” We strongly suggest that you use this service to create
your PDF files. Manuscripts that are not IEEE Xplore-compatible
will not be accepted in the Conference Record.
In order to ensure a timely release of the DVD-ROM, please follow
this procedure for the Conference Record manuscript submission:
1. Produce IEEE Xplore-compatible PDF file using PDF eXpress
The IEEE PDF eXpress service will be available for the NSSMIC authors between Oct. 1 and Nov. 16, 2012. You need to
enter nssmic12x as the conference ID, and set up an account on
that system. You can upload your word processor file to the web
site and have it converted to PDF. Shortly after your upload, an
electronic proof in PDF format will be generated and emailed
to you. You need to retrieve this IEEE Xplore-compatible
file either from the PDF eXpress web site or from your email.
You can also use this service to verify your own PDF file for
Xplore-compatibility. Detailed instructions on the PDF eXpress
service are available at http://www.nss-mic.org/2012/Public/
Publications/PDFeXpress.html.
PDF eXpress is NOT the final destination for your manuscript.
You must submit your manuscript to the Guest Editor following
the step below.
2. Submit the Xplore-compatible PDF file and the IEEE
Copyright Form
Log on to the conference web site and follow the menu “My
Submissions” to the abstract submission page. You will see
both links for uploading your manuscript and submitting the
copyright form electronically. Follow the instructions on the web
site to complete both tasks. Your PDF file will be checked for
Xplore-compatibility. Non-Xplore-compatible files will not be
included in the DVD-ROM.
If you are not authorized to submit the IEEE Copyright Form,
please start the approval process well before the submission deadline.
Publications 21
The deadline for the Conference Record manuscript submission
is Nov. 16, 2012.
All manuscripts submitted through the conference web site will be
made available immediately at the “Conference Record” web link.
However, only those that meet the following requirements will be
included in the DVD-ROM:
• Paper (oral or poster) has been presented at the conference;
• Manuscript conforms to the page layout requirements specified
in the online templates;
• PDF file is IEEE Xplore-compatible;
• PDF file and the electronic copyright form are received no later
than the Nov. 16 deadline.
For further information regarding the Conference Record, contact:
Guest Editor for the Conference Record
Bo Yu
Brookhaven National Laboratory
Phone: +1-631-344-5184
E-mail: [email protected]
Transactions on Nuclear Science (TNS)
Additionally, papers presented at the conference that contain
important information of lasting value may be submitted for review
and publication in the Transactions on Nuclear Science (TNS). The
TNS is a premier peer-reviewed journal with a significant distribution
within the nuclear science and medical imaging communities. TNS is
not the conference record, and only those papers that pass the review
process and are in the fields of interest to TNS will be published.
Prospective authors should consult the TNS page at www.ieee.org
for a description of the publication. TNS discourages the submission
of progress reports and manuscripts that are more suitable for
distribution as an institution’s internal document. We expect each
manuscript to be cast in the context of the state of the art of its field
(including appropriate motivation for the work), present a complete
description of the work performed, and to present a set of conclusions
supported by the measured and/or calculated data. The paper should
be sufficiently complete that others with comparable equipment
could repeat the work.
Authors submitting to TNS should expect to be solicited to serve
as reviewers of other papers. Please accept as many solicitations as
you are able to handle and remember to return your reviews in a
timely fashion. TNS tries to find at least two reviewers for each paper
and the speed of the review process ultimately depends on your
cooperation. TNS relies on this most important professional service
you, the authors, provide to the community.
TNS is published throughout the year, and you can submit your
manuscript to TNS at any time. For instructions on TNS manuscript
submissions, please visit the IEEE’s on-line peer review system
ScholarOne Manuscripts™ (http://mc.manuscriptcentral.com/tnsieee). TNS suggests that authors limit their papers to 8 pages, but
that limit is quite flexible and exceptions can be made.
22 Publications Special instructions for RTSD authors: So that the RTSD papers
may be collected in the August issue of TNS, RTSD papers should be
submitted by Dec. 1. RTSD papers submitted after that date may not
complete the review process by June 1, the deadline for the August
issue. Those RTSD papers that complete the review process after June
1 will appear in later issues of TNS and be identified as originating in
the RTSD Workshop.
For further information regarding the Transactions on Nuclear
Science, contact:
TNS Editor in Chief
Paul Dressendorfer
Sandia National Laboratories (retired)
Tel: +1 505 292 5965
TNS Senior Editors
Radiation Instrumentation (NSS & RTSD)
Zane Bell
Oak Ridge National Laboratory
Tel: +1 865 574 6120
Nuclear Medical and Imaging Sciences (MIC)
Joel Karp
University of Pennsylvania Health System
Tel: +1 215 662 3073
Transactions on Medical Imaging (TMI)
Authors of medical imaging papers may alternatively choose to submit
their manuscripts to the IEEE Transactions on Medical Imaging
through ScholarOne Manuscripts™ (http://mc.manuscriptcentral.
com/tmi-ieee). For further information regarding the IEEE
Transactions on Medical Imaging, contact:
TMI Editor in Chief
Milan Sonka
The University of Iowa
Tel: +1 319 335 6052
Comparison of Requirements
The value of the Conference Record (CR) is chiefly accrued by the
immediate and timely release of the information, which excludes
the possibility of peer-review for manuscript content. It is possible
that a similar (or even the same) article can be submitted to both the
Conference Record and the TNS. However, the authors must keep in
mind that the content of the articles designated for TNS publication
must meet the level of scrutiny by scientific review, and publication
is not guaranteed for the TNS submission. The CR and TNS are two
separate publications. Submission to one does not imply submission
to the other.
Publications 23
Conference Record
(CR)
Transactions on Nuclear
Science (TNS)
Page layout
Same as TNS, but
without running headers
and footers
Standard IEEE Transactions
and Journal format
Copyright
form
Required, electronic
submission
Required, electronic
submission
Deadline
Nov. 16, 2012
Radiation Instrumentation
Papers: None
RTSD Papers: Dec. 1
(strongly suggested)
Peer reviewed
No
Yes
Color figures
Free and encouraged
At author’s expense for
printed version, free for
online version
Page Limit
8 (suggested)
8 (suggested)
Availability
Online immediately,
DVD-ROM out before
end of 2012 to all
attendees
Published throughout the
year
Submission
Site
http://www.nss-mic.
org/2012/submissions
http://
mc.manuscriptcentral.com/
tns-ieee
24 Publications Short Course Program
Jennifer Huber
Steve Derenzo
A n excellent set of short courses will be given at the start of
the NSS/MIC programs, covering a wide range of nuclear
and medical imaging technology. All courses are one or two
days in length. Coffee and pastries will be available for participants
of the short courses at 08:00, before the first lecture which will begin
at 08:30. Lunch, refreshments, lecture notes, and a certification of
completion are also provided as part of the short course registration
fee.
Steve Derenzo
NSS Short Course Chair
Jennifer Huber
MIC Short Course Chair
Short Course
Date
Location
SC1 - Radiation Detection and
Measurement
Sat. Oct. 27
Sun. Oct. 28
Magic Kingdom
Ballroom 2
SC2 - Nuclear Science for Nuclear
Security
Sat. Oct. 27
Magic Kingdom
Ballroom 3
SC3 - Integrated Circuit Front Ends
for Nuclear Pulse Processing
Sat. Oct. 27
Magic Kingdom
Ballroom 4
Sun. Oct. 28
Magic Kingdom
Ballroom 3
SC5 - Molecular Biology for
Imaging Scientists
Sun. Oct. 28
Magic Kingdom
Ballroom 4
Mon. Oct. 29
Magic Kingdom
Ballroom 3
SC7 - Physics & Design of Detectors
for PET and SPECT
Mon. Oct. 29
Magic Kingdom
Ballroom 4
Short Course Daily Schedule
08:00-08:30 08:30-10:00 10:00-10:30 10:30-12:00 12:00-13:30 13:30-15:00 15:00-15:30 15:30-17:00 Student breakfast
Session 1
Morning break
Session 2
Lunch
Session 3
Afternoon break
Session 4
Short Course Program 25
SC1 - Radiation Detection and Measurement
Saturday, October 27, 08:30-17:00
Location: Magic Kingdom Ballroom 2
Organiser: Glenn F. Knoll, University of Michigan, USA
Instructors:
Giuseppe Bertuccio, Politecnico di Milano, Italy
Stephen Derenzo, Lawrence Berkeley National Laboratory, USA
Glenn Knoll, University of Michigan, USA
Graham Smith, Brookhaven National Laboratory, USA
Lothar Strueder, Max Planck Institute, Munich, Germany
Course Description
This 2-day course provides an overall review of the basic principles
that underlie the operation of the major types of instruments used
in the detection and spectroscopy of charged particles, gamma rays,
and other forms of ionizing radiation. Examples of both established
applications and recent developments are drawn from areas including
particle physics, nuclear medicine, homeland security, and general
radiation spectroscopy. Emphasis is on understanding the fundamental
processes that govern the operation of radiation detectors, rather
than on operational details that are unique to specific commercial
instruments. This course does not cover radiation dosimetry or health
physics instrumentation. The level of presentation is best suited to
those with some prior background in radiation measurements, but
can also serve to introduce topics that may be outside their experience
base. A copy of the 4th edition (2010) of the textbook “Radiation
Detection and Measurement”, by G. Knoll, and a set of course notes
are provided to registrants.
Course Outline
• Gas-Filled Detectors
• Scintillation Detectors
• Semiconductor Detectors
• Front-end Electronics for Radiation Detectors
• Recent Detector Developments and Summary
Instructors’ Biography
Giuseppe Bertuccio is Professor of Electronics at Politecnico di
Milano and member of the National Institute of Nuclear Physics.
He received the Laurea in Nuclear Engineering from Politecnico
and in 1987 he joined the research group of Professor Emilio Gatti,
contributing to the pioneering development of integrated electronics
for Silicon Drift Detectors. In 1991 he was invited to Brookhaven
National Laboratory and in 1993 to Canberra Industries to
collaborate on R&D’s of low noise preamplifiers. His current research
activities are in the design of CMOS and BiCMOS integrated circuits
for radiation detectors signal processing and in GaAs and SiC X-ray
detectors, collaborating with Alcatel Alenia Space, ESA, LPE and
Selex. He is author or co-author of over 100 scientific and technical
publications and 11 invited talks at international conferences.
Stephen E. Derenzo is a Senior Scientist at the Lawrence Berkeley
National Laboratory, Head of the Radiotracer Development and
Imaging Technology Department in the Life Sciences Division, and
Professor-in-Residence in the Electrical Engineering and Computer
Science Department at UC Berkeley. He and his colleagues
26 Short Course Program constructed two pioneering positron emission tomographs (PET)
and developed advanced scintillation detectors for PET that provide
high spatial resolution, depth-of-interaction information, and
compact integrated circuit readout. For the past 24 years he has lead a
search for new heavy scintillators and currently heads a project for the
discovery of scintillation detector materials that uses automation to
increase the rate of synthesis and characterization. He has authored or
co-authored over 200 technical publications, seven patents, and one
textbook. He has received two awards from the IEEE Nuclear and
Plasma Sciences Society: the Merit Award in 1992 and the Radiation
Instrumentation Outstanding Achievement Award in 2001. He
became an IEEE Fellow in 2000.
Glenn F. Knoll is Professor Emeritus of Nuclear Engineering and
Radiological Sciences at the University of Michigan. He joined the
Michigan faculty in 1962, and served as Chairman of the Department
of Nuclear Engineering from 1979 to 1990, and as Interim Dean of
the College of Engineering in 1995-96. He is author or co-author
of over 200 technical publications, 7 patents, and 2 textbooks. In
1999 he was inducted to membership in the National Academy of
Engineering. In 2000 he received the highest faculty award from the
College of Engineering of the University of Michigan, the Stephen
E. Attwood Award. He has served as consultant to over 35 industrial
and governmental organizations in technical areas related to radiation
measurements. He is a Life Fellow of IEEE, was selected for the
1996 IEEE/NPSS Merit Award and the 2007 IEEE/NPSS Radiation
Instrumentation Outstanding Achievement Award, and in 2000 was
a recipient of the Third Millennium Medal of the Society.
Graham C. Smith is a senior physicist in the Instrumentation
Division at Brookhaven National Laboratory. He received a
Ph.D in Physics from Durham University, England in 1974,
followed by postdoctoral work in nuclear electronics and detector
instrumentation for X-ray Astronomy at Leicester University. In
1982 he joined Brookhaven’s Instrumentation Division to participate
in development of high accuracy position-sensitive detectors and
electronics, becoming a tenured staff member in 1994. He received
Brookhaven’s Research and Development Award in 1996, and the
IEEE Long Island Regional Award for Contributions to High Energy
Physics in 1998. He became an IEEE Fellow in 2012. He has an
active research program in development of detectors, particularly gasbased detectors, for ionizing radiation measurement in synchrotron,
neutron and particle physics experiments.
Lothar Strueder is with the Max-Planck-Institut für
Extraterrestrische Physik in Munich where he leads the MPI
Semiconductor Laboratory. He earned his Ph.D. in Experimental
Physics at the TU Munich in 1988, and serves as Honorary Professor
in Experimental Physics at the University of Siegen, Germany. His
interests generally include position-, energy-, and time-resolving
detectors for photons and particles. His awards include the
Macres Award of the American Society for Microanalysis for the
most innovative instrument in 1997/1998, an ESA award for the
development of outstanding scientific X-ray imaging spectrometers
in 1999, and an award in 2000 from the EPIC consortium for
outstanding contributions to the XMM focal plane instruments. He
has been issued 11 worldwide patents in scientific instrumentation.
SC2 - Nuclear Science for Nuclear Security
Organiser: Robert (Bob) Runkle, Pacific Northwest National
Laboratory, USA
Instructors:
Robert (Bob) Runkle, Pacific Northwest National Laboratory, USA
Daniel Stephens, Pacific Northwest National Laboratory, USA
Glen Warren, Pacific Northwest National Laboratory, USA
Course Description
This one-day course will cover the application of nuclear science, most
prominently radiation measurement and analysis methods, in the area
of nuclear security that ranges from nuclear material accounting to
illicit material trafficking to treaty verification. The intended audience
consists of those who seek to understand the science and technology
challenges unique to nuclear security missions. Existing commercial
instruments will be briefly discussed but the course focuses on the
role of nuclear technology in meeting mission needs and challenges
faced by emerging technology to meet those needs. Prospective
students with a general physics or engineering background but
little preparation in the area of nuclear science are welcome but are
encouraged to study the book Radiation Detection and Measurement
by Glenn Knoll.
To begin, we will define the scope of “nuclear security” as it pertains
to this course, and the various missions that motivate the use of
nuclear science. We will discuss the operational environments
typically encountered and provide specific examples of technology
implementation. To provide high-level context for technology
developers, this includes the value of systems-level evaluations as a
means to assess technology’s role. A generic discussion of nuclear
signatures will be coupled to an overview of “backgrounds” in
nuclear security environs (e.g. ambient background sources, naturally
occurring radioactive materials (NORM)). The course will then
cover the basic classes of passive gamma-ray and neutron detection
instrumentation (including imaging techniques) and discuss how
one makes field deployment decisions using this technology. We will
elucidate the potential role of “active” interrogation techniques in
addressing some of the most challenging nuclear security problems.
Finally, the course will provide an overview of enabling and
exploratory technologies that could result in key advancements for
nuclear security applications in the future and address the changing
focus of the nuclear security enterprise.
Course Outline
Morning Session
1. Nuclear Security Overview
• Missions • Signatures
2. Sensors & Observables
• Gamma-ray
• Neutron
• Alpha/beta
3. Methods
• Gamma-ray spectroscopy
28 Short Course Program • Active interrogation
• Coincidence
Afternoon Session
4. Systems Level View
• Mission Snapshots
• Spent Fuel Assay
• Illicit Nuclear Trafficking
• Safeguards Sample Analysis
• Dismantlement Verification
• International Monitoring System
5. Trends & Opportunities
6. Questions & Discussion
Robert (Bob) Runkle is a physicist at Pacific Northwest National
Laboratory and performs research into radiation detection for
national security applications. Bob recently authored three review
articles on the role of gamma-ray spectroscopy, neutron detection,
and active interrogation in support of nuclear security missions.
In 2009 and 2010, he spent two years at the Department of
Energy’s Office of Nonproliferation and Verification Research and
Development where he served as a technical advisor to the Special
Nuclear Materials Movement Detection program. Bob served as the
National Test Director for NNSA’s Second Line of Defense program
and is the deputy principal investigator of PNNL’s Ultra-Sensitive
Nuclear Measurements initiative. He is the lead instructor of the
Radiation Detection for Nuclear Security summer school hosted at
Pacific Northwest National Laboratory. Bob joined Pacific Northwest
National Laboratory in 2003 after receiving his Ph.D. in nuclear
astrophysics from the University of North Carolina at Chapel Hill in
2003 where he measured the rates of nuclear fusion reactions relevant
to hydrogen burning in stars.
Daniel Stephens is Technical Manager of the Radiation Detection
and Nuclear Sciences group (RDNS) at Pacific Northwest National
Laboratory. RDNS conducts a variety of fundamental and applied
research projects leading to new capabilities in trace chemical
and radionuclide detection, nuclear and high-energy physics,
environmental assessment and remediation, treaty verification, and
proliferation detection and prevention. Daniel joined PNNL as a
research scientist in February 2003. His most recent assignment
was the Project Manager and Principal Investigator for the Radiation
Portal Monitor Project at the Pacific Northwest National Laboratory.
This project is tasked by the U.S. Department of Homeland Security’s
Domestic Nuclear Detection Office and U.S. Customs and Border
Protection to deploy radiation sensors at the nation’s borders and
ports of entry and to provide the scientific and technical expertise
needed to design, deploy, maintain, and operate these systems. In
this role Daniel was responsible for the successful execution of this
large, complex, and diverse project which draws upon the talents of
250 staff from across all directorates of the laboratory. From 2006 to
2008 Daniel served as a Technical Advisor to the Advanced Materials
and Special Nuclear Material Movement Detection programs in the
U.S. Department of Energy-Headquarters, National Nuclear Security
Agency, Office of Nonproliferation Research and Development
(NA-22). His career at PNNL has focused on the development
and deployment of novel radiation detection instruments with an
emphasis on national and homeland security applications. Research
topics of interest include advanced spectroscopic identification
algorithms, sensor networking, novel radiation detector development,
field operations, and operational testing and evaluation. Daniel
received his B.S. in Physics from Georgia Southern University, M.S.
in Physics, M.S. in Nuclear Engineering and Ph.D. in Nuclear
Engineering from the University of Tennessee.
Glen Warren is a staff scientist at Pacific Northwest National
Laboratory, working in the areas of active interrogation and applied
radiation detection. His primary research interest is the application
of nuclear resonance fluorescence and other active interrogation
techniques to a variety of national and homeland security applications.
In addition, Glen specializes in the modeling of complex radiation
detectors and the analyses of the data resulting from these systems.
Before joining PNNL in 2003, Glen’s research was focused on the
electromagnetic structure of the neutron by conducting experiments
at electron scattering facilities such as the Thomas Jefferson National
Accelerator Facility. Glen received a B.S. in Physics and Mathematics
from the College of William and Mary, and his Ph.D. in Nuclear
Physics from the Massachusetts Institute of Technology.
SC3 - Integrated Circuit Front Ends for Nuclear Pulse
Processing
Organiser: Paul O'Connor, Brookhaven National Laboratory, USA
Instructors:
Christophe de La Taille, IN2P3, France
Paul O'Connor, Brookhaven National Laboratory, USA
Veljko Radeka, Brookhaven National Laboratory, USA
Course Description
This one-day course is intended to introduce physicists and detector
specialists to the fundamentals of integrated circuit front end design.
The class begins with a discussion of low-noise signal processing
and semiconductor devices and then delves into the details of
implementing practical circuits in modern CMOS technology. A
basic knowledge of detectors and electronics is assumed.
Course Outline
1. Pulse Processing Fundamentals
• Signal formation in detectors
• Noise and gain mechanisms
• Pulse processing for amplitude and timing extraction
2. Semiconductor Technology for Integrated Circuit Front Ends
• Operation and characteristics of MOS and bipolar transistors
• Sub-micron CMOS and BICMOS technology
• Feature size scaling
• Radiation effects and reliability
• Mixed-signal circuits
3. Analog circuit design
• The IC design process and CAD tools
• Foundry access, multiproject services
30 Short Course Program • Building blocks for the analog channel: charge-sensitive and
pulse-shaping amplifiers, baseline stabilizers, peak detectors,
track/hold, multiplexers, output stages
• Analog-to-digital and time-to-digital converters (ADC and
TDC)
4. Packaging and Interconnect
5. Application examples
Christophe de La Taille is Technical Director of the French
Institute for Particle Physics (IN2P3). After receiving engineering
and Ph.D. degrees from Ecole Polytechnique, he joined CNRS/
IN2P3 and worked on the readout of the ATLAS calorimeter at
CERN/LHC and other high energy physics experiments. Prior to
his present position, he was the leader of the electronics group at
LAL, Orsay. His research interests are in the field of detectors and
mixed signal ASIC design. He is author and co-author of over 168
publications and has been an IEEE member since 2003.
Paul O'Connor is associate Head of the Instrumentation Division
at Brookhaven National Laboratory. After receiving the Ph.D.
degree in solid-state physics from Brown University he worked from
1980-1990 at AT&T Bell Laboratories prior to joining BNL. His
research interests are in the field of instrumentation systems for
radiation detection, particularly low noise analog CMOS front-end
circuits. He is author and co-author of over 80 publications and has
been an IEEE member since 1980.
Veljko Radeka, Senior Scientist and Head of Instrumentation
Division at Brookhaven National laboratory. His interests have
been in scientific instruments, radiation detectors, noise and signal
processing, and low noise electronics. He authored or coauthored
about 190 publications. He is a Life Fellow of IEEE, a Fellow of APS,
recipient of the 2009 Howard Wheeler Award from the IEEE and
of the 2010 Radiation Instrumentation Outstanding Achievement
Award, IEEE NPSS.
Organiser: Woon-Seng Choong, Lawrence Berkeley National
Laboratory, USA
Instructors:
Katsushi Arisaka,University of California, Los Angeles, USA
Woon-Seng Choong, Lawrence Berkeley National Laboratory, USA
Helmuth Spieler, Lawrence Berkeley National Laboratory, USA
Craig Woody, Brookhaven National Laboratory, USA
Course Description
This 1-day course will discuss the photodetector technology that
is used in the readout of scintillation crystals for nuclear radiation
detection. The main photodetector used in scintillation spectroscopy
at present is the photomultiplier tube (PMT) and its current status and
on-going advances will be covered. The course will also present recent
advances in silicon-based photodetectors - such as unity gain silicon
PIN diodes, drift detectors, high gain avalanche photodiodes (APDs),
and the new silicon photomultipliers. The potentials of wider-gap
semiconductor-based photodetectors will be included. Front-end
electronic readout designs for these different types of photodetectors
will also be covered. Examples of detector configurations that employ
various types of photodetectors in applications such as medical
imaging and physics research will be given. Some prior background
in scintillation spectroscopy would be desirable but not essential.
panels for major detectors in the US, Europe and Japan for both
ground and space-based experiments. He is internationally known for
his tutorial courses on detectors and signal processing and has been
active in outreach projects with local high school science teachers. He
is the author of the book Semiconductor Detector Systems published
by Oxford University Press.
Course Outline
1. Vacuum-Based Photodetectors (PMT, MCP PMT, Hybrid
Photodetectors)
Craig Woody is a Senior Physicist at the Brookhaven National
Laboratory. He received his Ph.D. from the Johns Hopkins
University in 1978. His research interests are primarily in the area
of particle detectors and instrumentation for high energy and
nuclear physics and medical imaging. These include various types of
scintillating crystals and other types of scintillation detectors, optical
readout devices and their associated electronics, laser systems, and
gas detectors for particle tracking and imaging applications. Other
primary research interests are in relativistic heavy ion physics with
the PHENIX Experiment at the Relativistic Heavy Ion Collider at
Brookhaven.
2. Solid State Photodetectors (Photodiode, APD, Geiger-Mode
APD, SiPM)
3. Signal Processing and Elecrotronics
4. Applications of Photodetectors in Physics Research and Nuclear
Medicine
Instructors' Biography
Katsushi Arisaka is a Professor of Physics and Astronomy at UCLA.
He also holds a position of Professor of Electrical Engineering and a
member of CNSI (California Nano System Institute). He received
a Ph.D in Physics from University of Tokyo in 1985 by the ground
breaking neutrino experiment, Kamiokande, where he developed a
20 inch PMT at Hamamatsu Photonics. After postdoctoral work at
University of Pennsylvania, he moved to UCLA in 1988 as a faculty
member in the Department of Physics. Through 25 years of his
career, he has invented and/or developed larger area PMT, position
sensitive PMT, Hybrid PD/APD, together with various types of
photocathodes such as GaAsP and special bialkali photocathodes for
low temperature operation in close collaboration with Hamamatsu
Photonics. His research activities include dark matter search, LHC
(CMS), ultra high-energy cosmic rays, as well as high-speed optical
bio-imaging and neuroscience.
Woon-Seng Choong is a Research Scientist at the Lawrence
Berkeley National Laboratory. He received a Ph.D in Physics
from the University of California at Berkeley in 2000. His major
research interests are in the development of novel and advanced
instrumentation for biomedical imaging, specifically in nuclear
medicine and image reconstruction. These include development of
new scintillators for gamma ray detection, novel photodetectors,
electronics for radionuclide imaging, and new detector designs
and camera systems. Recently, he has been investigating advanced
photodetector technologies such as multi-anode microchannel plate
photomultiplier tubes and silicon photomultipliers.
Helmuth Spieler has retired as a Senior Physicist in the Physics
Division of Lawrence Berkeley National Laboratory after working
three decades there. He received his Ph.D. in nuclear physics from
the Technical University in Munich in 1974 and worked in many
areas of instrumentation, both as a user and designer. Much of his
instrumentation work has been on large-scale semiconductor detector
systems and full custom ICs for high energy physics experiments at
high-luminosity colliders. More recent developments have been on
a large-scale array of superconducting detectors at the South Pole
Telescope to probe very early cosmology and also on high-pressure
Xe gas TPCs to optimize energy resolution and potentially search for
neutrinoless double-beta decay. He has served on numerous review
32 Short Course Program SC5 - Molecular Biology for Imaging Scientists
Organiser: Caius Radu, University of California, Los Angeles, USA
Instructors:
Dean Campbell, University of California, Los Angeles, USA
David Nathanson, University of California, Los Angeles, USA
Caius Radu, University of California, Los Angeles, USA
Course Description
This course is intended as an introduction to fundamental concepts
of Molecular Biology presented from the perspective of integrating
imaging techniques with the emerging concepts of personalized
medicine and systems biology. In this context, the revolution that
has taken place during the last decade in genetics and molecular
biology can be traced back to the development of techniques that
enabled scientists to manipulate and analyze genetic material. These
approaches, together with new data-gathering technologies such
as genomics, proteomics and imaging, have a significant potential
for translation into medically relevant knowledge. The success
of this endeavor depends largely on the creation of an interactive,
inter-disciplinary scientific culture in which experts in engineering,
physics, chemistry, mathematics and computer science join biologists
to ensure the efficient integration of new technologies. Opportunities
for such inter-disciplinary interactions and relevant examples will
be emphasized during this Molecular Biology course. Moreover, the
course will attempt to illustrate fundamental concepts in Molecular
Biology using specific examples of molecular mechanisms involved
in the pathogenesis of human diseases in general and cancer in
particular. Potential imaging applications to study such diseasecausing mechanisms will also be discussed.
Course Outline
1. Nucleic Acids and the Synthesis of Macromolecules
• DNA Replication and Repair
• From DNA to RNA to Proteins; Gene regulation
2. The Cell
• Subcellular Organization of Eukaryotic Cells
• Cell Signaling, Metabolism, Division and Death
3. Molecular Biology Techniques
• DNA Engineering, Gene Replacement, Transgenic Animals,
RNA Interference
• The “OMICS” revolution – a glimpse into the future of
Medicine?
Dean Campbell obtained his BSc. in Chemistry and Biochemistry
from the University of the West Indies, Jamaica. He then received his
Ph.D. in Biochemistry and Molecular Biology at the University of
Georgia. His Ph.D. work focused on elucidating the high-resolution
structure of catalytic RNA molecules using NMR Spectroscopy.
He received his post-doctoral training at UCLA. He is presently
an Assistant Researcher in the Ahmanson Translational Imaging
Division, UCLA. He is currently working on developing humanized
PET reporter genes for use in cellular and gene therapies, as well as,
developing novel strategies for cancer therapeutics by exploiting
metabolic stress responses in tumors.
David Nathanson is a post-doctoral scholar in the Radu/Czernin
lab in the Department of Molecular and Medical Pharmacology at
UCLA. He received his graduate training under Dr. Paul Mischel
at UCLA, where he studied cellular heterogeneity as a mechanism
of resistance to EGFR therapy in glioblastoma. He is currently
examining the role of the nucleoside salvage pathway in cancer cell
metabolism.
Caius Radu is an Associate Professor and also the Chair of the
Graduate Training Committee of the Department of Molecular and
Medical Pharmacology at UCLA. He also serves as a Vice Chairman
of the Department for Graduate Education. Dr. Radu received his
M.D. from the University of Medicine, Craiova, Romania and did
his postdoctoral training at UTSW Medical Center in Dallas and at
UCLA. His group uses a multidisciplinary approach that integrates
biology, chemistry, pharmacology and molecular imaging to translate
basic insights into metabolic regulation of immune cells and cancer
cells into new therapeutics and diagnostics.
Organiser: Jinyi Qi,University of California-Davis,USA
Instructors:
Michel Defrise, Vrije Universiteit Brussel, Belgium
Frederic Noo, University of Utah, USA
Jinyi Qi,University of California-Davis,USA
Course Description
Modern medical imaging systems can probe noninvasively anatomical
and functional information in vivo. However, the measured raw
data are related to the underlying image through a convolution
transform. Image reconstruction is essential to translate the raw data
to meaningful images. Over the past decades, many advances have
been made in both analytical and iterative reconstruction techniques.
Together with new instrumentation and computer hardware, these
34 Short Course Program developments have stimulated growing imaging applications in
clinical and biomedical research.
This course will provide an overview of tomographic image
reconstruction methods. It will start with fundamental issues of
image reconstruction and classical theories in computed tomography.
It will then describe analytical image reconstruction algorithms in 2D
parallel-beam and 3D cone-beam geometries. The third part of the
course will cover iterative reconstruction techniques. It will review
the maximum-likelihood and maximum a posteriori formulations
and describe some of the most successful optimization algorithms.
Prerequisite knowledge includes basic knowledge of the physics of
emission and transmission imaging systems, statistics, calculus, and
elementary linear algebra.
Course Outline
• Fundamentals and Classical Theories in Computed Tomography
• Analytical Image Reconstruction Algorithms
• Iterative Reconstruction Techniques
Michel Defrise received the Ph.D. degree in theoretical physics
from the University of Brussels in 1981, with a thesis devoted to
photon-photon interactions in electron-positron storage rings.
He was a visiting professor in the Department of Radiology of
the University of Geneva in 1992-1993, working with David
Townsend, Paul Kinahan and Christian Michel on the development
of the 3D-PET methodology. He developed in particular the Fourier
Rebinning Algorithm (FORE), as well as algorithms for cone-beam
reconstruction in collaboration with Rolf Clackdoyle (CNRS),
Frédéric Noo (U. of Utah) and Hiroyuki Kudo (U. of Tsukuba). With
the same colleagues, he developed in 2002 algorithms allowing exact
region of interest reconstruction from limited data. He is professor in
the Department of Nuclear Medicine at the Vrije Universiteit Brussel
(Free University Brussels) and his research interests still include 3-D
image reconstruction in nuclear medicine (PET and SPECT) and in
CT. He is Fellow of the Institute of Physics (UK), Fellow of the IEEE,
and Associate Editor of IEEE Transactions on Nuclear Sciences.
Frederic Noo is an Associate Professor of Radiology at the
University of Utah. He holds adjunct appointments at the same level
in Bioengineering, and also in Electrical and Computer Engineering.
He is an IEEE member and an Associate Editor for IEEE Transactions
on Medical Imaging. He has co-authored 59 peer-reviewed papers,
and 91 conference records. His research interest encompasses all
aspects of X-ray computed tomography (CT), including image
reconstruction techniques. His research projects involve the
development of advanced reconstruction techniques for multi-slice
CT, for cardiac CT imaging of the whole heart using cone-beam
data collection within a single heartbeat, and for cone-beam imaging
in interventional radiology. One fundamental problem with conebeam tomography is the handling of truncation in the projections.
Significant progress has been made on this problem over the last few
years, but many problems remain. This issue is integral to his research
projects, as well as that of task-based image quality assessment for
optimization of reconstruction algorithms.
Jinyi Qi is a Professor of Biomedical Engineering at University of
California-Davis, and a Faculty Scientist in the Department of
Radiotracer Development and Imaging Technology at Lawrence
Berkeley National Laboratory. He received his Ph.D. degree in
Electrical Engineering from the University of Southern California in
1998. He has been with the Lawrence Berkeley National Laboratory
since 1999 and joined the faculty at UC Davis in 2004. He is an
Associate Editor of the IEEE Transactions of Medical Imaging and
Fellow of AIMBE. His research interests include statistical image
reconstruction, image quality evaluation, system modeling and
optimization.
SC7 - Physics & Design of Detectors for PET and SPECT
ray Imaging, with appointments in the Department of Radiology and
the College of Optical Sciences. He was a staff scientist at the National
Synchrotron Light Source at Brookhaven National Laboratory. His
major research area is the development and application of detectors,
electronics, and systems for biomedical imaging.
Tom Lewellen was educated at Occidental College and the
University of Washington. He is currently an Emeritus Professor at
the University of Washington, with appointments in the Department
of Radiology (School of Medicine) and Electrical Engineering. He is
director of the Nuclear Medicine Detector and Electronics Laboratory
and a Fellow of the IEEE. His major research is in the development of
electronics and detector systems for SPECT and PET.
Organiser: Lars Furenlind, University of Arizona, USA
Instructors:
Harry Barrett, University of Arizona, USA
Lars Furenlind, University of Arizona, USA
Tom Lewellen, University of Washington, USA
Course Description
This course will survey the state of the art in gamma-ray detectors for
PET and SPECT, with a discussion of emerging technologies as well
as traditional semiconductor and scintillator devices. The course will
begin with a discussion of detector physics, cover signal generation,
analog and digital pulse-processing techniques, triggering, and
acquisition strategies. Considerable emphasis will be placed on
statistical characterization of the detectors and on optimal estimation
methods that take the statistical properties into account.
Course Outline
• Survey of technologies for gamma-ray detection
• Detector requirements for SPECT and PET
• State of the art in scintillation detectors
• State of the art in semiconductor detectors
• Statistical modeling and estimation methods
• Event triggering and coincidence techniques
• Data acquisition systems
• Real-time maximum-likelihood estimation methods
• Examples of applications
Harry Barrett was educated at Virginia Polytechnic Institute, MIT
and Harvard. He is currently a Regents Professor at the University of
Arizona, with appointments in the College of Optical Sciences, the
Dept. of Radiology and the programs in Applied Mathematics and
Biomedical Engineering. He is director of the Center for Gammaray Imaging and a fellow of the IEEE. In collaboration with Kyle J.
Myers, he has written a book entitled Foundations of Image Science,
which in 2006 was awarded the First Biennial J. W. Goodman Book
Writing Award from OSA and SPIE. In 2011 he received the SPIE
Gold Medal of the Society and the IEEE Medal for Innovation in
Healthcare Technology.
Lars Furenlid was educated at the University of Arizona and the
Georgia Institute of Technology. He is currently a Professor at the
University of Arizona and associate director of the Center for Gamma36 Short Course Program Short Course Program 37
Industrial Program
List of Exhibitors (as of July 10, 2012)
T he IEEE NSS/MIC
Industrial
Program
provides
our
conference attendees with ample
opportunities to meet the different
exhibitors on Tuesday, Wednesday,
and Thursday, 30 October to 1
November. The opening hours
Ron Keyser
will follow the hours of the
conference. More than 50 companies from around the world will
be present to meet conference attendees and to demonstrate their
latest products. These represent state-of-the-art in detectors, pulse
processing instrumentation, imaging, software, and other associated
areas. The exhibition area is located in South Exhibit Hall near
the poster sessions. The coffee breaks will be in the exhibit area on
Tuesday, Wednesday, and Thursday. The exhibits will remain open
until 18:00 on Thursday to provide extra time for the MIC attendees
to visit.
The three-day exhibition is complemented by a series of seminars
and technical presentations on Tuesday, Wednesday, and Thursday
in Monorail Room B&C, which will allow an in-depth exchange of
information between attendees and exhibitors on existing products,
future developments and needs. Directions to the Monorail Rooms
and the detailed schedule will be posted at the entrance to the exhibit
area.
The morning and afternoon coffee breaks will be held in the exhibit
area. On Tuesday evening from 19:00 to 21:00, the exhibiting
companies will host the Exhibitor Reception.
The Exhibition opening hours are as follows.
Exhibition Opening Hours
Tuesday, 30 October
12:00-21:00
Reception Starting at 19:00
Wednesday, 31 October
09:00-18:00
Thursday, 1 November
09:00-18:00
Ron Keyser
Industrial Program Chair
38 Industrial Program AdvanSiD S.R.L.
Agilent Technologies
Alibava Systems, S.L.
Alpha Spectra, Inc.
AMPTEK Inc.
AMT Solution Co., Ltd.
Baltic Scientific Instruments
Berkeley Nucleonics
Berthold Technologies
CAEN Technologies Inc.
Canberra
Chemetall GmbH
CMCAMAC
Creative Electron, Inc.
Eljen Technology
FLIR Systems
Furukawa Co., Ltd.
Hamamatsu Corporation
Hilger Crystals/RMD
Itech Instruments
KETEK GmbH
Kromek
labZY, LLC
Mediso Ltd
Micron Semiconductor
Naval Research Laboratory
ORTEC
Philips Digital Photon Counting
Quik-Pak
Saint-Gobain Crystals
ScintiTech/Amcrys
Scionix Holland BV
Sensl Technologies Ltd.
Shanghai SICCAS Crystal
Siemens Medical
SINTEF ICT
Sparrow (Corp)
Struck Innovative Systeme GmbH
Teledyne Microelectronics
Tungsten Heavy Powder
Vertilon Corporation
W-IE-NE-R, Plein & Baus, Ltd.
XIA LLC
X-Ray Imaging Europe
Industrial Program 39
Exhibitor Technical Sessions
Location: Monorail Room B+C
Exhibitor Technical Sessions will take place at the following times:
• Tuesday, 30 October from 14:00 to 16:00.
• Wednesday, 31 October from 10:30 to 16:00.
• Thursday, 1 November from 10:30 to 16:00.
Here is a preliminary list of presentations. The final list and schedule
will be posted on the web and printed in the Exhibition Guide &
Exhibitor Presentations.
Company
Title of Presentation
ORTEC
CAEN
HAMAMATSU
TOKUYAMA
KROMEK
SAINT GOBAIN
Technical Advances in Radiation Detection
Systems
Digital Pulse Processing in Homeland Security
and Medical Imaging Applications
Latest Development for Vacuum
Photodetector
Scintillation Properties of LiCAF for Neutron
Detection
Developments within Multi-Spectral X-Ray
Imaging
Developments in Neutron Detection
Solutions
Planar HPGE- and Si(Li)-Detectors –
SEMIKON Custom-Made and Tailored for a Great Variety
of Physics-Applications
Alibava Systems, S.L.
Flexible Readout System for Microstrip
Particle Detectors
GE ENERGY TBD
Fully Integrated Arrays of Digital Silicon
PHILIPS Photomultipliers (dSiPM’s) - The Way
Towards I ndustrial Application
Check our website: http://www.nss-mic.org/2012 for up-to-date
information. An Exhibitor Program brochure will be available at the
meeting with full details of the exhibitors and the seminar program.
Companies interested in participating should contact the Chair:
Ronald Keyser ([email protected], +1 865 607 2608).
40 Industrial Program Special Focus Workshops
S pecial Focus Workshops are intended
to have a focused discussion among
experts on interdisciplinary topics.
The following special focus workshops will
be organized to address topics of current
instrumentation research. The subjects are
“New Technologies in Hadron Therapy:
Particle Imaging and Optimization of
Ralf Engels
Treatment Delivery” and “Perspectives on
3He Replacements for Neutron Detection.” The Hadron Therapy
workshop will be on Sunday, 28 October, and 3He will be after the
NSS Symposium on Friday afternoon, 2 November.
This year, a “Special Linear Collider Event” is included during the
NSS Symposium and will be held on Monday afternoon and all day
Tuesday.
The workshop program consists of invited talks with ample time for
discussion. The conference website provides detailed information on
the program schedule and detailed content of these workshops.
Ralf Engels
Workshop Chair
New Technologies in Hadron Therapy: Particle Imaging and
Optimization of Treatment Delivery
Organizing committee:
Patrick Le Dû, IPN Lyon, France ([email protected])
Steve Peggs, Brookhaven National Laboratory , USA ([email protected])
Anatoly Rozenfeld, Univ. of Wollongong, Australia ([email protected])
Patrick Le DÛ
Steve Peggs
Anatoly
Rozenfeld
The scope of this workshop is to summarize the state-of-the-art of
technological developments required to meet the Quality Assurance
(QA) needs of the patient dose optimization, distribution and
monitoring during hadron therapy treatment plan.
It will be illustrated by some R&D projects.
Details will cover various topics like:
• Status and overview of new accelerators
instrumentation.
and associated
Special Focus Workshops 41
• Dosimetry, Microdosimetry and Nanodosimetry
• Physics of nanoparticles
• Moving targets: modelling of motion and organ deformation,
detection and tracking organ motion
• Advanced technologies for real time dose quantification using inbeam PET and prompt gammas
• Proton Computed Tomography
• Any other related topics
It is planned to have invited overview talks and introductory
discussions by internationally recognized experts including invited
clinicians in the morning sessions and status reports on ongoing
R&D projects made by young researchers in the afternoon sessions.
Round table discussion and informal exchanges of information will
be organized during the program.
• Neutron detection for national security and safeguards
• Neutron detection for neutron scattering science
• He-3 applications for medicine
• Neutron detection for petroleum and gas exploration
There is no formal registration procedure. We’re looking forward to
seeing you in Anaheim and enjoying a stimulating afternoon session.
Summary talks will be presented at the NSS-MIC joint session or
during the NSS/MIC Hadron Therapy sessions.
To participate in the workshop there is no formal registration
procedure. A preliminary program is available in the “Program”
section of this booklet and an updated version will be available on
the web site.
Perspectives on He-3 Replacements for Neutron Detection
Friday, November 2, 14.00-18:30
Organizing Committee:
Ralf Engels, Forschungszentrum Juelich
GmbH, Germany
Richard Kouzes, Pacific Northwest National
Laboratory, USA
This Workshop will focus on neutron
detection methods and technologies for
Dick Kouzes
science and applications, in the age of a
diminishing supply of He-3. One of the
main uses for He-3 is in gas proportional
counters for neutron detection, which
are used for homeland security, nonproliferation, neutron scattering science,
commercial instruments, and welllogging detectors. It is also used in
Ralf Engels
dilution refrigerators, targets or target
cooling in research, and for basic research
in condensed matter physics. Due to the large increase in these
applications and no new sources, the supply can no longer meet
the demand, and the He-3 stockpile is dwindling. The objective of
this workshop is to provide a forum for discussion of the state of
the art of neutron detection and the issues surrounding the current
shortage of He-3. This workshop will present and discuss the latest
developments for replacements. The emphasis will be on scientific/
technical developments in the following:
• The He-3 supply limitations and possible supplies
• Alternative neutron detector technology
42 Special Focus Workshops Special Focus Workshops 43
Special Events
Special Women in Engineering (WIE) Session: Contribution of
Women Scientists to Nuclear Science and Medical Imaging
Location: Sleeping Beauty Pavilion
Organizer:
Allan Johnston, NPSS Liaison to the IEEE Women in Engineering
Special Interest Group
I am pleased to welcome you to the 2012 Women in Engineering
(WIE) Session. The special session will address the theme of women’s
contributions to nuclear science and medical imaging by presenting
encouraging examples from the IEEE NSS and MIC. This session
will provide an opportunity for participants to exchange ideas and
experiences in an informal setting.
Details about the WIE Session can be found on the website: http://
www.nss-mic.org/2012
STIR / SimSET / ASIM User’s Meeting: Open Source Software
for PET and SPECT
Thursday, November 1, 12:40-14:00
Location: Sleeping Beauty Pavilion
Organizing committee:
Claude Comtat
Robert Harrison
Paul Kinahan
Kris Thielemans
Charalampos Tsoumpas
This meeting will focus on the synergies between three Open Source
packages used for medical imaging research. STIR is Open Source
software for image reconstruction and associated data processing,
currently mostly used in PET. SimSET and ASIM are simulations
of emission tomography, the former a photon-tracking simulation of
PET and SPECT, the latter an analytic simulation of PET. This User’s
Meeting will commence with an introduction to the current releases
of the three packages. We will then give a brief demonstration of
the use of the packages together, followed by presentation of a few
projects that use these software packages.
Topics discussed in this meeting will be:
• SPECT reconstruction with STIR
• improved SPECT modeling and acceleration planned for
SimSET
• integration of simulation packages with STIR
The meeting will close with an open discussion.
Existing users of any of the three packages who are interested in
presenting their work during the meeting should contact the User’s
Meeting organisers by the 15th of September.
44 Special Events Reception for IEEE GOLD Members
Thursday, November 1, 19:00-21:00,
Location: Mark Twain Room
IEEE GOLD (Graduates of the Last
Decade) members are welcome to join a
casual reception to be held on Thursday,
November 1 from 19:00 to 21:00 in the
Mark Twain Room.
Attendance is free, but restricted to GOLD
members and to conference attendees
that join IEEE or the Nuclear and Plasma
Sciences Society during the conference
in Anaheim, in order to extend a special
welcome to them and allow for networking
right away.
Christoph
Ilgner
In a comfortable, casual atmosphere, personal contact between the
attendees can easily be established: After a short welcome address the
participants will be invited to take some refreshments. A couple of
speakers that can look back on their bright careers in both academia
and industry will then give very brief summaries on what they have
done to get where they are today. Also IEEE fellows will be among
these speakers. Their statements will focus on aspects of successful
career planning. Since these brief statements are meant to open the
floor for peer-to-peer discussions among the participants, a lot of
time will be available for this.
Over the past years, the GOLD receptions at NSS-MIC and other
IEEE-NPSS conferences have proven to foster direct contact between
young professionals and colleagues at the zenith of their careers. So,
if you are an IEEE GOLD member or have joined our society right
here in Anaheim, you are cordially invited to participate. It is up to
you to profit from the opportunities the GOLD reception offers. I
look forward to welcoming you.
Christoph Ilgner, GOLD Committee Chair
OpenPET Users Group Meeting
Thursday, November 1, 14:00-16:00,
Location: Grand Ballroom South
Organizer:
Jennifer Huber, Lawrence Berkeley National Laboratory, USA
OpenPET is a general purpose, open source readout electronics
system for high performance radionuclide imaging that is under
development by LBNL. It consists of circuit boards, firmware and
software for people that are building prototype PET and SPECT
imagers. At this OpenPET users group meeting, we will give an
update on the status of OpenPET and will have reports from our
early adopter users. All are welcome to attend. You can find more
information about OpenPET at http://openpet.lbl.gov/.
Special Events 45
Linear Collider Event
The recent discovery of a particle at the Large Hadron Collider (LHC)
at CERN, consistent with the long-thought Higgs boson, provides a
very clear target for near-future linear collider experiments. A next
generation Linear Collider (LC) is currently being designed as the
next large-scale experimental facility in elementary particle physics
beyond the LHC. It is intended to offer a perfect environment to
elucidate the nature of a Higgs particle and allows for precision studies
to be conducted that may reveal the next energy scale of physics to be
targeted by future big machines.
With the news of the Higgs, public interest in particle physics in
general, and the LC in particular, is at an all-time high. Therefore, this
year the organizers have chosen to arrange a Special Linear Collider
(LC) Event in addition to their nominal IEEE NSS program. The
aim of the special event is to bring together academic, industry, and
laboratory-based experts on accelerator and detector technologies and
applications. It is an excellent opportunity to discuss linear collider
technologies with the accelerator and instrumentation community at
large.
Particle accelerators are widely perceived as tools for mankind in the
service of science. The International Linear Collider (ILC), which
is distributed among many labs, and the Compact Linear Collider
(CLIC), centered at CERN, are both global projects that would collide
electrons and positrons at TeV energies. However, they have different
technologies, different time scales, and different energy extensibility.
The two-day LC event will: summarize the state-of-the-art of ILC and
the CLIC accelerator and detector concepts; include presentations on
the impact of LC technologies for different applications; provide a
forum for discussion about LC perspectives.
Special attention will be given to the sessions where potential spinoffs of LC accelerator and detector technologies are discussed.
In particular, they will include presentations on how accelerator
technology developed by the nation’s laboratories and universities
could directly translate into a competitive strength for industrial
partners, as well as advance applications of accelerators for use in
service to society. The status of the Advanced Accelerator Association
Promoting Science and Technology (from the perspective of ‘industrygovernment-academia collaboration’ motivated by AAA, Japan) will
be also reported. In the field of detector instrumentation, many spinoffs from ILC detector R&D look valuable for other particle physics
detectors, and for detectors in other fields, in particular medical
imaging (e.g. novel multi-modality designs in positron emission
tomography).
The Linear Collider Forum Discussion will bring together directors
of the world-wide High Energy Physics Laboratories and leading
experts in LC technologies, both from the academic research sector
and industry, to provide an interactive discussion and insight into
the long-term technology roadmap for the Linear Collider Facility
construction.
We are looking forward to seeing you in Anaheim !
46 Linear Collider Event Program Committee of the “Linear Collider Event”:
Jim Brau, University of Oregon, USA
Juan Fuster, IFIC Valencia, Spain
Ingrid-Maria Gregor, DESY Hamburg, Germany
Michael Harrison, BNL, USA
Marc Ross, FNAL, USA
Steinar Stapnes, CERN, Switzerland
Maxim Titov, CEA Saclay, France
Nick Walker, DESY Hamburg, Germany
Akira Yamamoto, KEK, Japan,
Hitoshi Yamamoto, Tohoku University, Japan
Program and Abstracts
LC1: Introduction
Monday, Oct. 29,14:00-15:40, Grand Ballroom Center
LC1-1 (14:00, invited): Welcome to the Special Linear Collider Event
R.-D. Heuer, CERN, Geneva, Switzerland
LC1-2 (14:10, invited): Brief Overview of the ILC History and
Milestones, Summary of ILC TDR, Perspectives
B. Barish, California Institute of Technology, Pasadena, USA
LC1-3 (14:25, invited): Brief Overview of the CLIC History and
Milestones, Summary of CLIC CDR, Perspectives
S. Stapnes, CERN, Switzerland
LC1-4 (14:40, invited): Physics of the Linear Colliders
H. Murayama, LBNL, Berkeley, CA, USA and Kavli Institute for the Physics and
Mathematics of the Universe (IPMU), Tokyo, Japan
Recent discovery of a particle that looks like a Higgs boson provides a very
clear target for the near-future linear collider. I will review the capabilities of a
low-energy linear collider in elucidating the nature of this new particle. I will
emphasize that a precision study may reveal the next energy scale of physics to
be targeted by a later big machine.
LC1-5 (15:10, invited): Overview of Detectors for the Linear Collider
H. Yamamoto, Tohoku University, Japan
At an e+ e- linear collider, the 4-momentum and the spin state of the initial
state can be well controlled and the environment of interactions are clean.
Taking advantage of these experimental conditions, a linear collider provides
unique physics opportunities for the detailed studies of the Higgs particle.
In order to fully exploit the physics potential, the detectors need to have
resolutions that far exceed the past state-of-the-art. Intensive R&D activities
have been conducted to meet the requirements and they promoted great
advances in the field. In this brief talk, I will review such efforts in detector
R&Ds.
LC2: ILC/CLIC Accelerator and Detector
Concepts
Monday, Oct. 29, 16:30-18:40, Grand Ballroom Center
LC2-1 (16:30, invited): The Superconducting RF Acceleration and the
International Linear Collider
N. Walker, DESY, Hamburg, Germany
The benefits of using superconducting radio-frequency (SCRF) acceleration
for an electron-positron linear collider have been well documented over the
years. The ultra-low cavity wall losses allow the use of long RF pulses, greatly
simplifying the RF source, while facilitating high-efficiency acceleration of
high-current beams. In addition the low RF frequency (1.3 GHz) significantly
Linear Collider Event 47
reduces the impedance of the cavities, leading to reduced beam dynamics
effects and relatively relaxed alignment tolerances. Over two decades of R&D
has lead to an increase in the deployed available gradient of over a factor of
six, which, together with a high level of cavity integration into single cryostat
(cryomodule) has resulted in an affordable and mature accelerator technology.
Following a unique decision in 2004 by the world high energy physics
community to develop the International Linear Collider (ILC) based on the
established SCRF technology as a truly global project, the Global Design
Effort (GDE) has successfully coordinated a worldwide R&D programme
which will culminate in the ILC Technical Design Report in 2013. This
presentation will chart the history of the SCRF linear collider, with a focus
on the quest for higher gradients (35 MV/m and beyond), the ‘globalisation’
of the technology, and the preparation for a worldwide industrial base for the
construction of the ILC.
LC2-2 (17:10, invited): X-Band Acceleration, Two-Beam Acceleration,
and the Compact Linear Collider
D. Schulte, CERN, Geneva, Switzerland
The Compact Linear Collider (CLIC) Collaboration is developing a
multi-TeV linear electron-positron collider for future high energy physics
experiments; it has recently published a conceptual design report. The concept
is based on the use of 12GHz normal conducting accelerating structures,
which allow high gradients and hence a cost effective machine. To minimise
cost a novel two-beam scheme is used to power the accelerating structures
rather than conventional klystrons. Key technical choices are specified and
the status of the technology is discussed. The on-going work-programme and
studies towards an implementation plan for the CLIC project will also be
briefly covered.
LC2-3 (17:50, invited): State-of-the-art in Vertex Detectors for LC
M. Winter, CNRS/IN2P3, IPHC Strasbourg, Strasbourg, France
The Linear Collider physics programme assumes high performance flavour
tagging capabilities, particularly in terms of displaced vertex reconstruction
originating from charm-quark and tau-lepton decays. A new generation vertex
detector, featuring unprecedented spatial resolution and material budget, is
therefore developed since several years, based on novel pixel technologies. The
talk will overview the status of the different R&D activities, compare their
achievements with the ILC and CLIC specifications and summarise their
perspectives.
LC2-4 (18:15, invited): State-of-the-art in Silicon Tracking for LC
T. Nelson, SLAC National Accelerator Laboratory, USA
During the past few years, the concepts and technologies for solid state
tracking at the ILC have matured to the point where they are largely ready
for implementation. Meanwhile, the advent of the CLIC detector concepts has
introduced some additional challenges, pushing the evolution of these designs
and technologies even further. The status of silicon tracking for the ILC detector
concepts will be discussed, along with the new challenges that must be met for
CLIC and some thoughts about how to achieve the remaining goals.
LC3: ILC/CLIC Detector Concepts and
Summary of Detector Spin-Offs
Tuesday, Oct. 30, 08:00-10:00, Grand Ballroom South AB
LC3-1 (08:00, invited): State-of-the-art in Gaseous Tracking for LC
T. Matsuda, KEK/IPNS, Japan
R&D for a high-precision TPC is ongoing in the international ILC-TPC
collaboration. The main topics are the construction of a low material-budget
field cage and the development of gas amplification end-plates using GEM
or Micromegas. In this talk we discuss the state-of-art in gaseous tracking
detector for LC, in particular, the concept and the current status of R&D of
MPGD TPC for LC.
48 Linear Collider Event LC3-2 (08:25, invited): State-of-the-art in Electromagnetic Calorimetry
for LC
J.-C. Brient, CNRS/IN2P3, Paris, France
The physics program at a future linear collider requires a novel design of the
electromagnetic calorimeter (ECAL), very different to equivalent detectors
used at the LHC. The Particle Flow Approach (PFA) to jet reconstruction
implies an ECAL whose primary goal is to identify individual particle showers
in the dense environment of high energy hadronic jets. This consideration
leads an ultra granular device with many readout layers and small pixel size.
Possible technological solutions and their respective advantages and drawbacks
will be discussed.
LC3-3 (08:50, invited): State-of-the-art in Hadronic Calorimetry for LC
J. Repond, Argonne National Laboratory, USA
To fully exploit the physics potential of a future Lepton Collider will
require unprecedented jet energy and (di)-mass resolution. Currently two
complementary approaches are being pursued to achieve this goal: Particle
Flow Algorithms (PFAs) and Dual Readout (DR) calorimetry. The former
requires imaging calorimeters with extremely fine spatial segmentation. The
latter requires the measurement and identification of both scintillation and
Cerenkov light in the calorimeter. This talk reviews the main developments
in hadron calorimetry geared towards implementation in a future Lepton
Collider detector. The talk covers recent results from the large prototypes of the
CALICE collaboration, such as the Scintillator Analog Hadron Calorimeter
(AHCAL) and the Digital Hadron Calorimeters (DHCAL and SDHCAL), as
well as results from the various development projets.
LC3-4 (09:15, invited): State-of-the-art in Forward Calorimetry and
other Miscellaneous Detector Applications
S. Kulis, AGH University of Science and Technology, Cqracow, Poland
A report will be given about the design of the very forward calorimeters, their
functionality, and the performance of prototype sensor planes assembled with
dedicated FE ASICs in test beams. These sensor planes constitute the key
components to built compact and finely segmented sampling calorimeters as
prototypes of very forward calorimeters. Also the R&D on special detectors
for muon identification is summarised.
LC3-5 (09:30, invited): Summary of the Spin-off Document “ILC
Detector R&D: its Impact”
M. Demarteau, Argonne National Laboratory, Argonne, USA
Although the actual construction date of the ILC accelerator and its detectors
is uncertain, the impact of the R&D for ILC detectors is very real. The deep
impact of the work initiated by and carried out within the ILC detector
community on the particle physics community and beyond will be discussed.
LC4: ILC/CLIC Detector Spin-offs and ILC/
CLIC Accelerator Instrumentation
LC4-1 (10:30, invited): From ILC Imaging Calorimeter to a PET
Detector
E. Garutti, Faculty of Mathematics, Informatics and Natural Sciences, University
of Hamburg, Hamburg, Germany
From imaging calorimeters for particle physics to imaging cancerous cells
in a human body, the detector technologies established for particle flow
calorimeters at linear collider detectors enable unprecedented spatial resolution
and novel multi-modality designs in positron emission tomography detector.
A brief overview is given of the current medical projects profiting from ILC
research.
LC4-2 (11:00, invited): LC Spin-offs Outside Medical Imaging
C. De La Taille, IN2P3/CNRS, Paris, France
Detectors designed for particle-flow calorimetry at the Linear Collider will
feature unprecedented granularity (tens of millions of channels) to reconstruct
the “image” of showers and accurately reconstruct them. With embedded ultra
low power readout electronics, they allow to design large area smart detectors.
Various technologies have been studied over the last ten years, from highly
granular Resistive Plate Chambers or MicroMegas and Gems, to Silicon PM
scintillating tiles or large area PIN diodes. These “square meter” detectors or
their readout electronics with accurate charge and time measurement not
only find applications in medical imaging but also in muon tomography for
volcano studies (MuRay or TOMUVOL projects), astrophysics experiments
(PEBS) and Nuclear physics (HN diffusion). Future perspectives will be also
discussed.
LC4-3 (11:30, invited): Linear Collider Instrumentation
T. Lefevre, CERN, Geneva, Switzerland
Linear collider relies on tight beam parameters while colliding short bunches
focused down to nanometer beam sizes. The conservation of ultra-low
emittances requires a precise control of the beam alignment over very long
distances. The talk will present the state of the art in Linear collider beam
instruments, with an emphasis on non-invasive techniques.
LC4-4 (11:50, invited): Linear Collider Module Control and
Stabilization
A. Jeremie, CNRS/IN2P3, LAPP, Paris, France
A future linear collider will rely of having the possibility to monitor and
control reliably a significant number of key module and environmental
parameters along its full length. Novel module data acquisition systems based
on integrated radiation hard and low power readout electronics are being
studied, including systems and methods for stabilisation of key elements of
the machine to a very high precision.
LC4-5 (12:10, invited): Alignment Challenges for a Future Linear
Collider
H. Schmickler, CERN, Geneva, Switzerland
The alignment and stability requirements for a future linear collider are very
demanding. The talk will cover the specifications and solutions being studied
for pre- aligning and aligning linear collider elements within the CLIC and
ILC projects.
LC5: ILC/CLIC Accelerator Technologies for
Industrial Applications I
LC5-1 (14:00, invited): Opportunities for Applications of LC
Technology (Institutional Perspective)
M. C. Ross, SLAC National Accelerator Laboratory, Palo Alto, CA, USA
Particle accelerators are widely perceived as tools for mankind in the service
of science. The next generation will see applications of accelerators broadly
expanded and adapted for use in service to society. This transition has been
enabled by an era of work to extend the frontiers of technology in terms of
performance, reliability and cost. The surprising richness of the micro-universe
has motivated accelerator builders over the last few decades to push their art to
the limits and we now begin to doubt if these limits have been reached and if
machines much larger than LHC, ILC or CLIC are realistic. The term ‘hightechnology’ characterizes work on linear colliders and related accelerators, and
generally indicates a high level of investment and return on investment (ROI),
in other words: high risk. Following the unique decision in 2004 by the world
high energy physics community to develop the International Linear Collider
an unprecedented degree of global focus and participation allowed this
investment in, for example, superconducting RF technology and precision
beam control. As we now move forward to realize the linear collider, it is time
to consider the ROI, especially toward industrial applications. In this talk we
will review this remarkable era and consider the next steps to be taken toward
applying what has been learned.
LC5-2 (14:25, invited): Overview of Industrial, Medical, Energy and
Security Related Accelerator Use (Industry Perspective)
N. Holtkamp, SLAC National Accelerator Laboratory, USA
50 Linear Collider Event Based on the 2009 workshop “Accelerators for America’s Future,” (AfAF)
an assessment was made on how accelerator technology developed by
the nation’s laboratories and universities could directly translate into a
competitive strength for industrial partners and a variety of government
agencies in the research, defense and national security sectors. The workshop
report provides comprehensive and up to date information with respect to
the broad applications of accelerators. In addition in September 2011 the US
Senate Appropriations Committee requested a ten-year strategic plan from
the Department of Energy (DOE) that would describe how accelerator R&D
today could advance applications directly relevant to society in those fields. An
overview of the applications and an assessment where DOE funded national
laboratories and their programs can have a major impact will be described.
LC5-3 (14:50, invited): Applications of Superconducting RF Linear
Accelerators (Industry Perspective)
J. Rathke, Advanced Energy Systems, Princeton, NJ, USA
This paper will discuss the criteria for use of SRF technology for industrial
applications i.e. when does it make sense to use SRF. Criteria such as capital
costs, operating costs and space considerations will be covered. Based on
these criteria applications such as flue gas and water treatment as well as most
medical applications do not meet the criteria. Applications such as isotope
production, defense and ADS do.
LC5-4 (15:15, invited): Applications of Normal-Conducting RF Linear
W. Wuensch, CERN, Geneva, Switzerland
Normal conducting linacs are used in a wide variety of industrial applications.
Basic RF parameter choices, such as peak input power and accelerating
gradient, are influenced by a number of factors but are often conservatively
matched to performances achieved in other machines. Now the normal
conducting linear collider R&D programs have led to practical accelerating
gradients above 100 MV/m. How might this result influence future industrial
accelerators? The field of normal conducting industrial accelerators is reviewed
and the possibilities of benefiting from linear collider R&D are considered.
LC5-5 (15:50, invited): Applications of Linear Collider Supporting RF
Technology (Industry Perspective)
S. Lenci, Communications & Power Industries LLC, Palo Alto,
CA, USA
The presentation will provide an overview of RF Technology that supports
Linear Colliders, as various RF sources (klystrons and IOT’s), components
(Power Couplers and Barrier Windows), and other related technology. It
will include a future outlook towards future devices and the use of similar
technologies in a wider research and industry perspective.
Industrial Applications II
LC6-1 (16:30, invited): Applications of Linear Collider Supporting
Instrumentation Technology (Industry Perspective)
M. Ross, SLAC National Accelerator Laboratory, USA
The recently - published Department of Energy Report ‘ Accelerators for
America’s Future’ (http://www.acceleratorsamerica.org/report/index.html),
lists Reliability, Beam Power/RF and Beam Transport and Control as the top
R & D needs for various accelerator applications. While it is unlikely the
Grand Challenges formulated in response to the report will target these needs
specifically, we can expect follow-on work to focus on these top R & D needs
as high-priority by-products. Instrumentation of different kinds is used to
support the operation of modern accelerators through beam measurements,
component monitoring and control and RF feedback and will therefore have
a strong role in this work. The example of RF feedback, to be presented in
this talk, uses leading-edge technology digital signal processing to achieve the
required stabilization. Other examples to be discussed include radiation effects
on electronics (LHC and ILC), low latency feedback (ILC / CLIC), ultra-low
noise receivers (ILC) and mechanical stabilization systems (CLIC).
LC6-2 (16:55, invited): The status of Advanced Accelerator Association
Promoting Science and Technology
M. Matsuoka, Secretary General, Advanced Accelerator Association Promoting
Science & Technology, Tokio, Japan
Advanced Accelerator Association Promoting Science and Technology (AAA)
was established in June 2008 in Japan. The functions of AAA are to facilitate
Industry- Government-Academia collaboration and to promote and seek
various industrial applications of advanced accelerator and technologies
derived from R&D on such accelerator. International Linear Collider (ILC)
is one of the main themes of our study. Members of AAA have increased to
90 companies and 38 academic institutions since starting our activity. We
held 11 times symposiums to gain broad public understanding of ILC and
other accelerators. And our members of industry side have been studying
the accelerator technologies and their applications in collaboration with the
academia members. Some R&D project started by virtue of this activity. The
detail of these activities will be presented.
LC7: Forum Discussion about LC perspectives
Rolf-Dieter Heuer, CERN, Switzerland, Joachim Mnich, DESY, Germany,
Atsuto Suzuki, KEK, Japan, Pier Oddone, FNAL, USA
52 Linear Collider Event Nuclear Science Symposium - NSS
Maxim Titov
Ingrid-Maria Gregor
T The Nuclear Science Symposium (NSS) offers an outstanding
opportunity for scientists and engineers interested in the
fields of nuclear science, radiation detection, accelerators,
high energy physics and astrophysics, and related software to present
their latest developments and ideas. The scientific program provides
a comprehensive review of the latest developments in technology and
covers a wide range of applications from radiation and accelerator
instrumentation, new detector materials, to complex detector systems
for physical sciences, and advanced imaging systems for biological
and medical research.
Having received over 850 abstracts from colleagues working on
numerous NSS topics, we have organized the NSS program from
Monday to Friday, with four parallel sessions running at the same
time. This year’s program consists of 353 oral and 480 poster papers,
which are presented in three plenary sessions, 44 NSS oral parallel
sessions, and two poster sessions. The daily program includes two
2-hour sessions in the morning (08:00-12:30) and two 2-hour
sessions (14:00-18:30) in the afternoon.
Among the highlights of the symposium will be two NSS Plenary
Sessions on Monday, October 29, 2012 (08:30-12:00) and one on
Friday, November 2, 2012 (10:30-12:30), where leading experts in
our fields will shed a light on the most outstanding current and future
research frontiers.
The NSS Plenary Sessions will feature:
•
Prof. Dr. Rolf-Dieter Heuer on “The High Energy Frontier:
Past, Present, and Future”
•
Prof. Dr. Martin Pohl on “Recent Highlights from the AMS
Cosmic Ray Observatory on the International Space Station”
•
Dr. Edward Moses on “The National Ignition Facility and
Fusion Ignition: Status and Progress”
•
Dr Steve Holmes on “Project-X: A Powerful Facility for Particle
Physics and Beyond”
The Monday Plenary Sessions will be followed by the traditional NSS
Luncheon (12:00-14:00) during which Industrial Light and Magic
visual effects master John Knoll will provide a fascinating glimpse
into the science and technology of motion picture animations and
computer graphics.
On Tuesday, contributions bridging the fields of nuclear science,
Nuclear Science Symposium - NSS 53
medical imaging, and solid-state radiation detectors will be presented
in one dedicated NSS/MIC/RTSD joint session and one NSS/MIC
joint session (14:00 to 16:00, and 16:30 to 18:30). A joint NSS/
RTSD session is also planned on Friday (08:00-10:00).
To emphasize the importance of poster presentations, NSS posters
will be accessible from Monday morning to Wednesday evening, with
no NSS oral presentation sessions during the 2-hour dedicated poster
sessions.
Based on the positive feedback from previous years, we will again
have refresher courses during the lunch breaks.
The recent discovery of a particle at the Large Hadron Collider (LHC)
at CERN, consistent with the long-thought Higgs boson, provides a
very clear target for near-future linear collider experiments. Therefore,
this year we have chosen to arrange a Special two-day Linear Collider
(LC) Event in addition to their nominal IEEE NSS program. The
aim of the special event is to bring together academic, industry, and
laboratory-based experts on accelerator and detector technologies and
applications. It is an excellent opportunity to discuss linear collider
technologies with the accelerator and instrumentation community at
large.
We would like to thank all of the authors of the scientific contributions,
which form the true and crucial basis for this important event, as
well as all conference attendees. We would also like to thank the 330
reviewers who contributed valuable time and effort to read and assess
submitted papers. Our special thanks go to more than 40 NSS Topic
Conveners for their tireless efforts in organizing the symposium
program along the lines of the scientific topics and completing the
program within the scheduled time despite the very large number of
submitted abstracts.
More detailed information on the program, the Plenary Speakers, the
Linear Collider Event, and the Refresher Courses can be found in
this booklet and is available on the conference website (www.nss-mic.
org/2012). Please feel free and encouraged to contact us for feedback,
suggestions, and questions, by sending an email to [email protected].
We sincerely hope you will enjoy the exciting 2012 IEEE NSS/
MIC/RTSD and are looking forward to meeting you in Anaheim,
California in October this year.
Maxim Titov
NSS Program Chair
Ingrid-Maria Gregor
NSS Program Deputy Chair
Dora Merelli, Natalia Potylitsina-Kube
NSS Coordinators
NSS Plenary Talks
NP1-2 : The Large Hadron Collider: Unveiling the Universe
Rolf Heuer
CERN, Switzerland
Monday, October 29, 09:15-10:00, Grand Ballroom Center
Abstract
With the start of the
Large Hadron Collider
(LHC) at CERN, particle
physics entered a new era.
The LHC will provide
a deeper understanding
of the universe and the
insights gained could
change our view of the
world.
By
colliding
unparalleled high energy
and high-intensity beams,
the LHC is opening up
previously
unexplored
territory at the TeV scale
in great detail, allowing
the experiments to probe
deeper inside matter.
Rolf Heuer
The LHC is expected
to yield insights into the origin of mass, the nature of dark matter
and the existence of hidden extra dimensions. The talk will address
the exciting physics prospects offered by the LHC and present latest
results, in particular the recent discovery of a new ‘Higgs-like’ Boson.
The LHC will provide first indications of new physics at energies up
to several TeV. These results will be decisive in indicating the direction
that particle physics will take in the future. The talk will conclude
with this look forward and discuss new projects at the energy frontier
in Particle Physics.
Biography
Professor Rolf-Dieter Heuer has been CERN Director General since
January 2009. He obtained his Ph.D. at the University of Heidelberg
in 1977. Most of his scientific work has focused on the study of
electron-positron reactions, the development of experimental
techniques, as well as the construction and operation of large detector
systems. From 1984 to 1998, Prof. Heuer was a staff member at
CERN, working for the OPAL experiment at the electron-positron
storage ring LEP. During his 15 years at CERN Prof. Heuer occupied
the highest managerial positions in the OPAL experiment and was
the OPAL’s spokesperson in 1994-1998. In 1998, Rolf-Dieter Heuer
was appointed to a chair at the University of Hamburg. There, he set
up a working group to prepare experiments at an electron-positron
Linear Collider that quickly became one of the leading groups in this
field worldwide.
From 2004 to 2008, Prof. Heuer was research director for particle
and astroparticle physics at the DESY laboratory.
54 Nuclear Science Symposium - NSS NSS Plenary Talks 55
Prof. Heuer has been a member of many scientific committees and
advisory bodies where he has acquired a great deal of expertise in
reviewing projects as well as in assessing and promoting people. He
has been conferred honorary degrees of Doctor of Science in several
universities in Europe and Canada.
NP2-1: Recent Highlight from the AMS Cosmic Ray
Observatory on the International Space Station
Martin Pohl
Center for Astroparticle Physics, CAP Genève
University of Geneva, Switzerland
Abstract
The AMS-02 cosmic ray observatory is a-state-of-the-art particle
detector for long-term observation of cosmic rays in the GeV to TeV
region. It consists of a magnetic spectrometer, high performance
particle identification systems and a calorimeter. It was launched
successfully on May 16, 2011 on board of Space Shuttle Endeavor and
installed on the International Space Station (ISS) shortly afterwards.
Since then, it has been taking data continuously. The commissioning
phase of the detector is finished, all subsystems are up and running and
perform according to specifications. Detector operation is performed
from the Payload Operations and Control Center (POCC) at CERN.
Science data are timely transmitted to ground, stored and analyzed
using the Science Operation Center (SOC), also installed at CERN.
The alignment and calibration of the detector and its subsystems are
progressing well. First preliminary results are available. A very rich
physics program is thus starting, which will last at least until 2020,
with 16 billion cosmic rays collected per year. In this talk, I will review
the design, construction and performance of the detector, with special
emphasis on constraints
coming from the hostile
space
environment.
I will present inflight experience with
the detector and its
subsystems, as well as
first results concerning
the physics of cosmic
rays in near-earth orbit.
Biography
Pohl studied physics
at
RWTH
Aachen
(Germany) in the 1970s,
where he obtained his
diploma and Ph.D. with
studies of neutrinos
with bubble chambers
at CERN (Geneva,
Martin Pohl
Switzerland). He then
moved on to the electron-positron experiment MARK-J at the
PETRA collider (DESY, Hamburg) in the 80s. From 1984 to 2001
56 NSS Plenary Talks he was a senor physicist at ETH Zürich (Switzerland) working on the
L3 experiment at the Large Electron-Positron collider LEP (CERN,
Geneva). Since 1999 he has also collaborated on an experiment
striving to measure the muon lifetime to ppm precision at the PaulScherrer-Institute (Villigen, Switzerland). Since 2002 he has been a
full professor of physics at the University of Geneva. He has since
then specialized on astroparticle physics experiments in space, with
the AMS cosmic ray experiment taking data on the International
Space Station, the POLAR X-ray detector under construction for
the Chinese space laboratory Tiangong 2, and the X-ray observatory
LOFT, an ESA M-class mission candidate in the assessment phase.
His hardware experience ranges from silicon microstrip, pixel and
drift detectors to inorganic scintillators. He also teaches general
physics and particle physics at University of Geneva. His functions
include: chairman of the Swiss Institute of Particle Physics CHIPP
(2010-11), head of the physics department (2005-11) and director of
the department for particle and nuclear physics (DPNC) since 2011
at University of Geneva, co-founder of the Center for Astroparticle
Physics, CAP Genève.
NP2-2: The National Ignition Facility and Fusion Ignition:
Status and Progress
Edward Moses
Lawrence Livermore National Laboratory, USA
Abstract
The National Ignition Facility (NIF) at Lawrence Livermore National
Laboratory (LLNL) is the world’s most energetic laser system. NIF
has been operational since late 2009 and is routinely operating at 1.6
MJ of 3ω light with very high reliability and has reached its design
goal of 1.8 MJ and 500 TW in the ultraviolet. The energy level is
approximately 100x the capability of any other laser of its kind. In
addition, its capabilities as a scientific instrument have continually
increased with over 50 X-ray, optical and nuclear diagnostic systems
and the ability to shoot
cryogenic targets with
neutron yield. A variety
of experiments have also
been completed and
many more are planned
in support of NIF’s
mission areas in national
security,
fundamental
science, and fusion energy.
The National Ignition
Campaign (NIC), an
international effort with
the goal of demonstrating
thermonuclear burn in
the laboratory, has been
making steady progress
toward achieving ignition,
and implosions with
Edward Moses
NSS Plenary Talks 57
record indirect-drive neutron yield of 7.5 × 1014 neutrons have been
achieved. Other experiments have been completed in support of highenergy science, materials equation of state, and materials strength.
In all cases, records of extreme temperatures and pressures, highest
neutron yield and highest energy densities have been achieved.
This talk will describe the unprecedented experimental capabilities
of the NIF, the pathway to achieving fusion ignition, the plan to
build on this progress toward a clean energy future, fundamental
science experiments underway and our plans to transition NIF to
an international user facility providing access to researchers around
the world.
Biography
Dr. Edward Moses is the Principal Associate Director for Lawrence
Livermore National Laboratory (LLNL) in Livermore, California
responsible for National Ignition Facility and Photon Science
(NIF&PS) organization. The National Ignition Facility (NIF) is the
world’s largest and most energetic laser with applications to issues of
strategic security, fundamental science and fusion energy. Dr. Moses is
also the Director of the National Ignition Campaign (NIC). The goal
of the NIC, an international collaboration of national laboratories,
industry and academia, is to achieve fusion ignition in the laboratory
— the culmination of a 50-year quest. Dr. Moses has a career in high
technology and big science projects reaching back to 1980 which
included using high power laser systems to process materials, leading
a team that developed the Peregrine Cancer Treatment System and
many other technology areas in lasers, optics, control systems, and
diagnostics.
Dr. Moses has received many honors, including the Jefferson Award
for Public Service, the 2009 Edward Teller Medal for his leadership
in the development and completion of the NIF, the Fusion Power
Associates 2008 Leadership Award, the National Nuclear Security
Administration Defense Programs Award of Excellence for significant
contribution to the Stockpile Stewardship Program, the Memorial
D.S. Rozhdestvensky Medal for Outstanding Contributions to Lasers
and Optical Sciences, and the R&D 100 Award for the Peregrine
radiation therapy program. Recently, he received the Project of
the Year Award, the highest accolade of the Project Management
Institute (PMI), for leading the NIF. He has several other awards for
outstanding achievements in project management and construction
safety.
NP3-1: Project X: Technology, Perspectives and Applications
Steve Holmes
Fermi National Accelerator Laboratory, USA
Friday, November 2, 10:30-11:15, Grand Ballroom Center
Abstract
Project X is a multi-megawatt proton facility being developed to
support a world-leading program in Intensity Frontier physics at
the Fermi National Accelerator
Laboratory (Fermilab). The
facility is designed to support
programs
in
elementary
particle and nuclear physics,
with possible applications to
nuclear energy research. This
presentation will describe the
design concept and ongoing
technologies
development
program, highlighting the
unique aspects of the facility in
supporting forefront scientific
research.
Biography
Steve Holmes received his his
Steve Holmes
Ph.D. in Experimental Particle
Physics from Harvard University in 1976. Following a seven year
stint at Columbia University he joined the staff of the Fermi National
Accelerator Laboratory in 1983. At Fermilab he has worked on all
accelerators within the Tevatron complex, holding both technical
and management responsibilities. In the 1990s he served as Head
of the Fermilab Accelerator Division and as Project Manager for the
Main Injector construction project. He held the position of Fermilab
Associate Laboratory Director for Accelerators from 1999-2010. He
is currently serving as Project Manager of the Project X development
effort. He is a Fellow of the American Physical Society and a former
chair of its Division of Physics of Beams.
Dr. Moses is a member of the National Academy of Engineering, a
Fellow of the Optical Society of America, a Fellow of the American
Association for the Advancement of Science and a Fellow of SPIE. He
is a member of the California Council on Science and Technology.
Dr. Moses received his B.S. and Ph.D. degrees from Cornell
University. He holds patents in laser technology, inertial fusion
energy, and computational physics.
Dr. Moses and his wife live in Livermore, California. They have three
grown children.
58 NSS Plenary Talks NSS Plenary Talks 59
NSS Luncheon Talk
Art and Science in Visual Effects
John Knoll
Industrial Light & Magic, CA, USA
Monday, October 29, 12:00
Paradise Pier Hotel, Pacific Ballroom
twenty feature films and commercials.
He has been honored with five Academy Award nominations for
Visual Effects Supervising on “Star Wars: Episode I The Phantom
Menace”, “Star Wars: Episode II Attack of the Clones”, and the
Pirates of the Caribbean films, including “Pirates of the Caribbean:
Dead Man’s Chest”, for which he received both a BAFTA and an
Academy Award®. Since then, he supervised ILM’s visual effects for
James Cameron’s “Avatar”, “Rango”, and “Mission Impossible: Ghost
Protocol.”
Adding to his vast array of credits is the co-authorship of Photoshop,
which Knoll created with his brother in 1987.
John Knoll
Abstract
When filmmakers wish to tell stories about times, places or events
that are not possible or practical to photograph “for real”, they turn
to visual effects to manufacture the imagery. No matter how fantastic
the story that is being told, the filmmaker desires the imagery to feel
authentic. As the tools have evolved in an attempt to satisfy these
desires, filmmakers have exploited these new capabilities to tell bigger
and more fantastic stories.
The human visual system is sophisticated and our brains are good at
extracting information from pictures. Much of the progress in visual
effects over the last few decades has been in attempting to understand
and realistically simulate natural phenomena, everything from light
transport through a scene, to the way cloth folds or fluid flows. These
simulation techniques provide a great deal of realistic (or at least
plausible) detail that goes a long way towards towards convincing the
brain that what we are seeing is real.
In this talk I will show some of the techniques that are employed to
manufacture authentic looking imagery.
Biography
John Knoll’s interest in filmmaking began at an early age. Having a
keen interest in visual effects, Knoll was mesmerized by the original
“Star Wars.” During a visit to George Lucas’ visual effects studio
Industrial Light & Magic in 1978 he was able to observe first-hand
the world of visual effects. Inspired to learn more, Knoll attended the
USC School of Cinema and earned a Bachelor of Arts in Cinema
Production, while freelancing as a modelmaker at a variety of Los
Angeles-based production facilities.
Knoll joined ILM as a camera assistant in 1986. After three years in
the camera department, Knoll worked on the ground breaking digital
effects for “The Abyss”. Since that time, he has been promoted to
Visual Effects Supervisor, helming the visual effects on more than
60 NSS Luncheon Talk NSS Luncheon Talk 61
NSS Refresher Courses
Silicon Detectors
Helmuth Spieler,
LBL, Berkeley ,USA
Tuesday October 30, 12:45-13:45, Magic Kingdom 2
Silicon detectors are used in a wide range of applications, often with
very different requirements. In classic nuclear physics they provided
energy measurements and identified isotopes and their mass. In
high energy physics they are now widely used as tracking detectors
in systems with millions of channels and also for scintillation
measurements in large-scale calorimeters. In astronomy and
astrophysics they have played a major role in supernova searches
and also increase sensitivity in weak star detection. Astronomy
gamma-ray measurements have gained significantly in the Fermi
space telescope by building on detectors designed for high-energy
physics. In medical imaging, positron emission tomography (PET)
can use secondary silicon detectors to yield high position resolution
and time resolution. X-ray imaging yields intensity and position vs.
time to follow interactions in medical isotope injection. Some key
developments are now proceeding in atomic physics and molecular
interaction measurements at accelerator-based high-intensity X-ray
and photon sources. Silicon detector systems have also yielded novel
results in electron microscopy.
Although the requirements of these different applications vary
greatly, the basic physics is the same and understanding how this
affects the signals often leads to appropriate designs. Micron-level
design and monolithic integration offer many options. Another
key component is the electronic readout and here it is also just as
important to understand the various functions and how they should
be adapted to the overall system requirements. Additional aspects
also come into play, for example, radiation damage, overall power
consumption, and material distribution in the large-scale high-energy
physics detectors. In many applications the key is not to optimize
just one aspect, but to arrive at an appropriate compromise, perhaps
in a novel form. This is often a major problem, as many designs are
driven by generally accepted recipes, which have often led to “expert”
claims that new applications can’t work, although now they are taken
for granted. This summary talk will describe different applications,
key aspects of the sensors and electronics, and how the overall system
design optimizes the results. Additional information is available at
www-physics.LBL.gov~spieler.
makes them indispensable for the search for New Physics. Ongoing
technological developments are changing these devices, from rather
coarse detectors to highly granular precision instruments. Novel
measurement and reconstruction approaches promise dramatically
improved energy resolution for hadronic states, and the addition of
precise timing increases the spatial resolution in medical imaging and
turns particle physics calorimeters into 4D detectors with powerful
background rejection capabilities.
This refresher course will provide a brief introduction to the art of
energy measurements of electromagnetic and hadronic particles,
and discuss state of the art technologies and future developments.
Particular emphasis will be placed on new technologies that enable
compact, high resolution PET systems and on ideas for next
generation calorimeters in high-energy physics that push the limits
on single particle and on jet energy resolution.
GEANT 4
Maria Grazia Pia
CERN, Switzerland
Thursday November 1, 12:45-13:45, Magic Kingdom 2
This Refresher Course overviews Geant4 main features, with
emphasis on Geant4 physics modeling capabilities and their use in
Monte Carlo simulation applications.
The selection of physics processes and models to be used in a
simulation is one of the most critical tasks of Geant4 experimental
applications. Geant4 users are responsible for configuring the physics
of their simulation, since Geant4 does not provide any default physics
settings. The configuration of a user application requires in-depth
knowledge of Geant4 physics functionality to identify appropriate
processes and models, and understanding of their validity to estimate
the reliability and accuracy of the simulation results. This Geant4
simulation domain is by far the most difficult to master, not only for
novice users, but also for more experienced ones, due to its intrinsic
complexity and the large number of available options in the toolkit.
This Refresher Course reviews Geant4 simulation capabilities and
physics modeling options; it summarizes the current status of Geant4
physics validation and provides guidance to deal with Geant4 physics
selection in experimental applications.
Calorimeters
Frank Simon
MPI Munich, Germany
Wednesday October 31, 12:45-13:45, Magic Kingdom 2
The measurement of particle energies with calorimeters is a crucial part
of particle physics experiments, and the basis of modern diagnostics
with positron emission tomography. In experiments at the energy
frontier of particle physics, calorimeters also serve as key detectors for
the reconstruction of hadronic jets and overall event energy, which
62 NSS Refresher Courses NSS Refresher Courses 63
Medical Imaging Conference - MIC
The early morning refresher course tradition will continue, and we
have gathered prominent speakers from a variety of areas, ranging
from advances in light detectors techniques to ultrasound imaging, to
provide an overview of the latest developments in the respective areas.
The MIC dinner banquet will encourage socializing; given the
entertainment atmosphere intrinsic to the location we decided
against an after dinner talk to allow the participants to enjoy the local
attractions.
I
Vesna Sossi
Alex Converse
t is our great pleasure to welcome you to the 2012 Medical
Imaging Conference in Anaheim, California. The conference
center is located in the heart of Disneyland and hosts
comfortable meeting facilities conducive to stimulating discussions
in a pleasant and relaxed atmosphere. This is the foremost conference
dedicated to radionuclide-based imaging, where the latest trends
and ideas are presented and discussed. This year we received a near
record 755 abstracts and are grateful to the many dedicated reviewers
who generously donated their time to ensure high meeting standards
through a rigorous review process.
The conference offers over one hundred oral presentations, an
opening plenary session, four non-parallel and five parallel oral
sessions. We selected the parallel sessions in such a way as to attempt
to minimize overlapping interests. Abstracts from the themes with the
largest number of contributions, reflecting the trends of most interest
in the field, were assigned to the non-parallel sessions. We will have
four parallel poster sessions and posters will be on display for the
entire duration of the MIC meeting to allow ample time for poster
viewing. Recent years have seen increased use of radionuclide imaging
in conjunction with complementary imaging techniques, so we will
have one session dedicated to ‘other’ imaging modalities and one to
the use of radionuclide-based imaging techniques in radiotherapy.
And finally a sincere thanks to all the contributors who keep the
standard of this conference high and continue gathering year after
year while introducing the next generation to this exciting field.
Thanks also to the General Chair and all the other organizers who
work tirelessly to make this conference such a continuing success.
We hope that you will enjoy this meeting as much as those from the
previous years and are very much looking forward to seeing you in
Anaheim.
Vesna Sossi
MIC Program Chair
Alex Converse
MIC Program Deputy Chair
Tuesday will be dedicated to three joint oral sessions: an MIC/RTSD
in the early morning followed by an MIC/NSS and an NSS/MIC/
RTSD in the afternoon. The content of the abstracts selected for
these joint session was considered of interest and relevance to all
three communities. MIC attendees might also be interested in the
late Tuesday morning sessions of the Linear Collider Workshop as
especially relevant to medical applications. The official opening of the
MIC will be on Wednesday morning starting with two plenary talks,
given by outstanding scientists who use imaging in two different
areas, health and astronomical exploration. The first plenary talk,
entitled ‘Multi-modality Imaging and the Future of Alzheimer’s
Disease’ will be given by Dr. William Jagust, Professor of Public
Health and Neuroscience at the University of California, Berkeley.
The second plenary talk, entitled ‘Practising “Astromedicine”:
Lessons in Imaging and Inversion from a Rocket Scientist’, will be
given by Dr. Jaymie Matthews, Professor of Astrophysics from the
University of British Columbia. The second opening plenary session
will be dedicated to the Hoffman and Hasegawa Awards ceremony
followed by four oral presentations that were highly rated by the
reviewers.
64 Medical Imaging Conference - MIC Medical Imaging Conference - MIC 65
MIC Plenary Talks
M01-1: Multi-modality Imaging and the Future of Alzheimer’s
Disease
William Jagust
University of California, Berkeley & Lawrence Berkeley National
Laboratory, USA
Wednesday, Oct. 31, 08:30-09:15, Grand Ballroom Center
Abstract
Alzheimer’s disease (AD) is a major challenge for developed societies
experiencing growth of older populations. Despite extensive
knowledge of biochemical mechanisms underlying the disorder,
several major clinical trials of Alzheimer therapeutics targeting these
mechanisms have recently failed. This situation has forced a rethinking of the sequence of events underlying AD, and suggested
new approaches to drug development. Brain imaging, especially PET,
has played a key role in this process. We now have PET imaging
agents that bind to beta-amyloid, the protein that many believe to be
a key initiating event in AD and which aggregates to form the AD
plaque detected at autopsy. PET imaging has shown deposition of
beta-amyloid in cognitively healthy older people as well as patients
with AD, and revealed both structural and functional changes in the
brains of normal older people that are related to amyloid deposition.
This has supported a view in which amyloid deposition begins many
years – probably decades – before disease symptoms start, during
which time neurodegenerative processes slowly advance. Amyloid
deposition, brain atrophy, and decline in glucose metabolism, can
be detected in living people and linked to symptom progression and
disease stage. Taken together, the findings suggest that intervention
at presymptomatic stages may be necessary to have an effect on the
disease. Such approaches, if successful, might work through the
application of screening tools such as high-resolution, widely available
PET instruments that can detect individuals who might benefit from
treatment prior to the emergence of symptoms.
Biography
William Jagust, MD
is currently Professor
of Public Health
and Neuroscience
at the University of
California, Berkeley
and
a
Faculty
Senior Scientist at
Lawrence Berkeley
National Laboratory.
Following training
in medicine and
neurology, Dr. Jagust
was a postdoctoral
William Jagust
fellow at Lawrence
Berkeley National Laboratory and then joined the faculty at
the University of California Davis, where he was director of the
66 MIC Plenary Talks Alzheimer’s Disease Center and served as Chair from 1998-2004. His
research uses multi-modality imaging techniques to study brain aging
and dementia, demonstrating hippocampal atrophy using MRI and
glucose hypometabolism using PET. Most recently he has employed
imaging with ligands that bind to beta-amyloid to probe biochemical
changes in brain aging and link them to changes in brain structure
and function. Dr. Jagust has served on many NIH review committees
including chairing the National Institute on Aging’s Neuroscience
of Aging Review Committee, and he is a member of the Editorial
Board of the Annals of Neurology, Brain Imaging and Behavior, and
Alzheimer’s Disease and Associated Disorders and is an Associate
Editor of the journal Frontiers in Human Neuroscience. He is a
member of the Alzheimer’s Association Neuroimaging Work Group
and the leader of the PET imaging Core of the NIH Alzheimer’s
Disease Neuroimaging Initiative, a multi-center project that has
pioneered in standardization of PET data acquisition and analysis.
M01-2: Practising “Astromedicine”
Lessons in Imaging and Inversion from a Rocket Scientist
Jaymie Matthews
University of British Columbia, Vancouver, & Canadian Space
Agency, Canada
Wednesday, Oct. 31, 09:15-10:00, Grand Ballroom Center
Abstract
“Interdisciplinary studies” has become a catchphrase in modern pure
and applied sciences. But few would expect this principle could be
stretched enough to connect topics
as diverse as cancer and cosmology,
retinal disorders and resolving
binary stars, or the lymphatic
system and the Solar System.
Those connections – and others
between medical imaging and its
astrophysical counterparts – do
exist. Medical specialists employ
non-invasive ways to probe inside
the body; astronomers have no
choice but to probe distant stars
and galaxies non-invasively. Our
sciences, despite their very different
Jaymie Matthews
objectives, share a common
element of remote sensing. The retina of light-sensitive cells only 25
millimetres behind the living cornea can pose diagnostic challenges as
great as a galaxy of light-emitting galaxies 25 million light years beyond
the Earth. I’ll present a few examples of how astronomical imaging and
inversion techniques, and detector technology, have been applied by
medical researchers: Faint galaxy imaging software and its applications
to digital mammograms. Adaptive optics technology intended to counter
the turbulence of the Earth’ atmosphere, enabling detailed studies of the
living retina through the vitreous humour. Lightweight X-ray sensitive
microchips for an orbiting astronomical observatory, which are capable
of pin-point diagnostics to guide surgeons to cancerous cells. I’ll also
speculate on potential applications in the near future of the fledgling field
of “astromedicine”.
MIC Plenary Talks 67
Biography
Dr. Matthews is the Mission Scientist leading the Canadian Space
Agency’s MOST project, and a Professor of Astrophysics in the
Department of Physics & Astronomy at the University of British
Columbia. He and his team are trying to revise the biography of our
Sun – past and future – by studying its neighbours in our Galactic city,
the Milky Way. Dr. Matthews is a world-leading expert in the fields
of stellar seismology (literally using the surface vibrations of vibrating
stars to probe their hidden interiors and histories), exoplanetary
science, and astronomical time series analysis. He obtained his B.Sc.
degree at the University of Toronto, and his M.Sc. and Ph.D. degrees
at the University of Western Ontario.
In addition to heading the MOST Mission, Dr. Matthews serves on
the Science Teams for NEOSSat (Near Earth Object Surveillance
Satellite) – a Canadian asteroid-hunting mission – and BRITE
Constellation (BRIght Target Explorer) – a Canadian-AustrianPolish space satellite mission to monitor the brightest stars in the
night sky. He is a Co-Investigator for the French CoRoT satellite,
and a member of the Asteroseismic Science Consortium for NASA’s
Kepler space mission hunting for exoplanets.
In 2006, Dr. Matthews was appointed an Officer of the Order of
Canada, and in 2012, he received a Queen Elizabeth II Diamond
Jubilee Medal.
Dr. Matthews sat on Canada’s steering committees for the
international Gemini Twin 8-Metre Telescopes Project and FarUltraviolet Spectroscopic Explorer satellite, and the Joint Committee
on Space Astronomy, advising the Canadian Space Agency and the
Canadian Astronomical Society. He is a member of the International
Astronomical Union’s Commission on Variable Stars. He serves
on the Boards of Directors of Vancouver’s H.R. MacMillan Space
Centre (and was its Vice-President for one term) and Youth Science
Canada. Dr. Matthews was awarded a 1999 Killam Prize for teaching
excellence in the UBC Faculty of Science, as well as the 2002 Teaching
Prize of the Canadian Association of Physicists. Dr. Matthews also
disseminates scientific knowledge through regular appearances on
several TV channels.
68 MIC Plenary Talks MIC Refresher Courses
Light Detectors: Technology and Applications
Joel S. Karp
Dept .of Radiology and Dept. of Physics & Astronomy
University of Pennsylvania, USA
Wednesday, October 31, 07:00–08:00, Grand Ballroom Center
An update will be given on the latest developments of light detectors
with a focus on those that have application for medical imaging
systems, both current and near future. This will include a discussion
of traditional photo-multplier tubes and newer solid-state photosensors, including avalanche photodiodes (APDs) and silicon photomultipliers (SiPMs). A review of the intrinsic performance of the
devices will be given and description of how these devices can be
incorporated into detectors for medical imaging systems. The design
of the detector depends on whether the imaging application is for
humans or small animals, which in turn dictates the requirements of
performance in terms of sensitivity and spatial, energy, and timing
resolution. Our overall goal is to understand how these light sensors
impact the imaging performance and versatility of the scanner, and
the trade-offs involved in terms of cost and complexity of both
detector and electronic design.
Ultrasound Imaging and its Application in Minimally Invasive
Interventional Guidance
Cristian Linte
Dept. Physiology& Biomedical Engineering Biomedical Imaging
Mayo Clinic, Rochester, USA
Thursday, November 1, 07:00–08:00, Grand Ballroom Center
Ultrasound (US) imaging involves the exposure of a region of interest
in the body to sounds waves in the frequency range of 5-10 MHz.
These waves penetrate into soft tissue, but are reflected at tissue
boundaries due to the difference of the speed of sound in different
tissue media, giving rise to images of the internal body anatomy.
In addition to its value as a diagnostic tool, as an alternative to CT
or MRI, US imaging is an attractive modality for intra-procedure
guidance, especially due to its safety, relatively low cost, wide
availability, lack of ionizing radiation and compatibility with standard
operating room equipment. As such, US imaging presents a significant
benefit for its use in real-time visualization during minimally invasive
image-guided interventions. Following a brief overview of the
traditional principles of US imaging, this lecture will focus on several
applications associated with the use of real-time 2D, 3D as well as
4D (3D + time) US for intra-operative image guidance. Techniques
for registration of US images to pre-operative CT or MR images or
anatomical models will be discussed, along with the integration of
various US transducers with surgical tracking technologies for spatial
localization of the acquired images. Clinical applications will include
cardiac, orthopedic and prostate interventions, recent developments
in US elastography, as well as vascular imaging for monitoring and
assessment of vascular disease. To conclude, common challenges and
MIC Refresher Courses 69
limitations of US imaging systems, along with future directions in the
field, will be outlined.
ROC Analysis in Medical Imaging
Matthew Kupinski
The University of Arizona, College of Optical Sciences, USA
Friday November 2, 07:00–08:00, Grand Ballroom Center
This course will cover receiver operating characteristic (ROC) analysis
and the application of ROC analysis in medical imaging. This course
will not assume any prior knowledge on the subject and will start
by discussing how observers, both humans and model observers, can
map image data to decision variables; this mapping forms the basis of
ROC analysis. The benefits and limitations of ROC-based figures of
merit will be discussed as well as tests of significance and multi-reader,
multi-case (MRMC) analysis. We will also touch upon the topics
of ROC curve fitting, existing software, and ROC variants such as
localization ROC (LROC) analysis.
The Development and Validation of Useful
Radiopharmaceuticals
Richard Carson
Yale, New Haven, CT, USA
Saturday, November 3, 07:00–08:00 , Grand Ballroom Center
Abstract: The success of PET and SPECT imaging depends heavily
on the availability of specific radiopharmaceuticals with appropriate
pharmacokinetic properties. The development of a truly useful tracer
requires years of clinical and preclinical work. Successful and useful
radiopharmaceuticals have a number of important properties. These
include appropriate target selection, suitable affinity and selectivity
for the targeted biological process, appropriate lipophilicity for
tissue penetration, feasible radiochemistry to produce sufficient
yields with necessary specific activity, suitable peripheral metabolism
rates, acceptable toxicology and dosimetry, sufficient contrast and
uptake for imaging, feasible kinetic modeling for determination of
gold-standard pharmacokinetic parameters, and tracer kinetics that
support the use of a simple protocol for practical patient imaging.
This refresher course will survey these factors in general and in the
context of successful radiopharmaceuticals.
70 MIC Refresher Courses RTSD
19th International Workshop on RoomTemperature Semiconductor X- and Gamma
Ray Detectors
D
ear attendees,
Welcome to the 19th International Workshop on RoomTemperature Semiconductor X-Ray and Gamma-Ray
Detectors RTSD in 2012!
As Chairs of the workshop, it is our sincere hope that this conference
will facilitate cross-fertilization of research and spawn creative ideas,
and that these ideas will be incorporated into knowledge, leading to
new directions. We urge you to take time at this meeting to build on
the commonality of your work with colleagues within the RTSD, NSS
and MIC conferences, and to share your data, energy, and experience,
and explore ways to enhance cooperation and collaboration with
others.
The NSS/MIC/RTSD meeting represents the principal forum for
scientists and engineers working to develop new solid-state radiation
detectors and imaging arrays. We have chosen to hold this meeting
in conjunction with the IEEE NSS and MIC meetings for the
purpose of encouraging information exchange between a much larger
body of scientists and engineers who have an in-depth knowledge
of detectors, instrumentation, nuclear science and technology, and
medical imaging.
Joint sessions between NSS, MIC and RTSD play a major role for
the meeting in 2012. These joint sessions are clearly identified in the
program booklet, and we request everyone’s participation to help
bring people together with common interests and offer the right
environment for the creation of new and
fruitful associations.
The well-known RTSD luncheon will be
held this year at the Rainforest Café located
in Downtown Disney about 100-200 yards
from the conference site. You are encouraged
to purchase your ticket(s) when you preregister as seating will be limited.
We would like to thank the speakers and
attendees for their contributions, the
workshop sponsors for their kind support,
and express our gratitude to the session
chairs and members of the RTSD Steering
Committee, who have offered their time to
enlist the involvement of most researchers in
the field.
Ralph James
RTSD Program Co-Chair
Ralph James
Michael Fiederle
Michael Fiederle
RTSD 71
Joint Sessions
J
oint sessions between the NSS,
MIC, and RTSD communities are
now organized regularly every year
on the second day of the conference
week. This year, we have organized three
plenary joint sessions on Tuesday, October
30th in the Grand Ballroom Center:
• Joint MIC/RTSD at 8:30-10:00
Patrick Le DÛ
• Joint NSS/MIC at 14:00-16:00
• Joint triple NSS/MIC/RTSD at 16:30-18:30
The triple joint session will include an invited talk about “A Status
Update on Proton Imaging for Applications in Medicine” by Prof.
Reinhard Schulte from Loma Linda University Medical Center, USA.
He will also shortly summarize the New Technologies in Hadron
Therapy Workshop held on October 28th about Particle Imaging and
Optimization of Treatment Delivery.
We have selected and combined 21 papers on advanced tools and
technologies over the total of 887 (NSS), 754 (MIC) and 159
(RTSD) submitted abstracts that are of common interest to the
various communities. The final selection was made jointly by the
NSS, MIC, and RTSD organizers. Topics of particular relevance to
these sessions are:
•
•
•
•
Scintillators
Photodetectors
Semiconductor-Based Imaging Systems
Innovative Techniques for Small and Large Medical Imaging
Devices (PET, SPECT, MRI, etc.)
• Advanced Multimodality Endoscopic Instruments
• Particle Beam Therapy
• Dosimetry
72 Joint Sessions Scientific Program
Scientific Program 73
07:00
07:30
07:30
08:00
08:00
Saturday, 27 October
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
07:00
Sunday, 28 October
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
08:30
09:00
09:30
10:00
10:30
11:00
11:30
11:30
12:00
12:00
SC1 - Radiation
Detection and
Measurement
11:00
SC1 - Radiation
Detection and
Measurement
10:30
SC2 - Nuclear Science
for Nuclear Security
10:00
09:30
SC3 - Integrated Circuit
Front Ends for Nuclear
Pulse Processing
09:00
HT-2 Particle Therapy
Workshop 2
Pulse Processing
08:30
Workshop 1
SC4 - Advanced
Photodetectors
SC1 - Radiation
Detection and
Measurement
SC4 - Advanced
Photodetectors
SC5 - Molecular
Biology for Imaging
Scientists
SC1 - Radiation
Detection and
Measurement
SC5 - Molecular
Biology for Imaging
Scientists
12:30
12:30
13:00
13:00
13:30
14:00
14:30
15:00
15:30
16:00
16:30
17:00
17:00
SC1 - Radiation
Detection and
Measurement
16:30
SC1 - Radiation
Detection and
Measurement
16:00
15:30
15:00
17:30
17:30
18:00
18:00
18:30
18:30
19:00
19:00
19:30
19:30
Workshop 4
Pulse Processing
14:30
SC1 - Radiation
Detection and
Measurement
14:00
SC1 - Radiation
Detection and
Measurement
SC4 - Advanced
Photodetectors
Pulse Processing
13:30
SC4 - Advanced
Photodetectors
SC5 - Molecular
Biology for Imaging
Scientists
Workshop 3
SC5 - Molecular
Biology for Imaging
Scientists
74 74
Sunday - Workshop Oral
Presentations
New Technologies in Hadron Therapy
HT-1 Particle Therapy Workshop 1
Sunday, Oct. 28 08:30-10:00, Magic Kingdom Ballroom 1
Session Chairs: Patrick J. Le Du, IPNL,IN2P3, France
Anatoly Rosenfeld, University of Wollongong, Australia
HT-1-1 (08:30) Overview of Charged Particle CT
R. Schulte
Department of Radiation Medicine, Loma Linda University Medical Center,
USA
HT-1-2 (09:00) Australian Hadron Project and Comparison of Protons
with Modern X-ray Technologies
M. Jackson, Prince of Wales Hospital, Australia
HT-1-3 (09:30) Review on C-12 Achievements and Radiobiology Based
TPS
T. Haberer
Heidelberg Ionenstrahl-Therapie Centrum (HIT), Germany
Session Chairs: Reinhard Schulte, Department of Radiation Medicine,
Loma Linda University Medical Center, USA
Michael A. Jackson, Prince of Wales Hospital, Australia
HT-2-1 (10:30) In‐Vivo Imaging at the Heidelberg Ion Beam Therapy
Center – A Status Update
K. Parodi, Heidelberg Ion Beam Therapy Center, Germany
HT-2-2 (10:45) Techniques for Image Based in-vivo Dosimetry: from
Particle Therapy PET to in-beam Prompt Gamma Imaging
F. Fiedler1, C. Golnik2, S. Helmbrecht2, T. Kormoll2, D. Kunath1,2, K.
Laube2, A. Mller2, M. Priegnitz1, H. Rohling2, S. Schne1, W. Enghardt1,2
1
Helmholtz-Zentrum Dresden-Rossendorf, Germany; 2OncoRay, Germany
HT-2-3 (11:00) ELIMED a New Concept of Hadrontherapy with LaserDriven Beams
P. G. A. Cirrone1, G. Cuttone1, G. Korn2, M. Maggiore3, D. Margarone2, L.
Calabretta1, S. Cavallaro4, L. Celona1, M. Favetta1, S. Gammino1, T. Levato2,
G. La Malfa5, L. Manti6,7, J. Prokupek2, M. Renis5, F. Romani1, F. Schillaci1,
B. Tomasello5, L. Torrisi1,8, A. Tramontana1
1
Laboratori Nazionali Del Sud, Italy; 2Institute of Physics of the ASCR ELIBeamlines project, Czech Republic; 3Laboratori Nazionali di Legnaro, Italy;
4
Physics and Astronomy Department, Italy; 5Science of Drugs Department,
Italy; 6Physics Science Department, Italy; 7Section of Naples, Italy; 8Physics
Department, Italy
HT-2-4 (11:15) Development of a Compton Camera for Online
Monitoring and Dosimetry of Laser-Accelerated Proton Beams via
Prompt-Gamma Detection
P. G. Thirolf1, C. Lang1, K. Parodi1,2
1
Ludwig-Maximilians-University Munich, Germany; 2Heidelberger IonenstrahlTherapie Centrum, Germany
HT-2-5 (11:30) Real-time Online Monitoring of the Ion Range by
means of Prompt Secondary Radiations
C. Ray, E. Testa, D. Dauvergne, IPNL,Université de Lyon, Université Claude
Bernard Lyon 1,CNRS/IN2P3, France
Sunday - Workshop Oral Presentations 75
HT-2-6 (11:45) Meeting the Demands of Highly Precise Ion Beam
Therapy Improvements in QA and Treatment Planning by the Use of a
Flat-Panel Detector
B. Hartmann1,2, J. Telsemeyer1,2, B. Ackermann3, S. Brons3, O. Jaekel1,2,3, M.
Martisikova1,2
1
German Cancer Research Center (DKFZ), Germany; 2Heidelberg University
Hospital, Germany; 3Heidelberg Ion-Beam Therapy Center, Germany
HT-2-7 (12:00) The PRIMA Collaboration: Status of the Development
of a Proton Computed Tomography Scanner
M. Scaringella, University of Fiorence, Italy
On behalf of the PRISMA Collaboration
HT-2-8 (12:15) Neutral and Charged Particles’ Flux Measurement for
Released Dose Imaging in Hadrontherapy
S. Fiore, Sapienza Universita’ di Roma, Italy
Session Chairs: Anatoly Rosenfeld, University of Wollongong, Australia
Thomas Haberer, Heidelberg Ionenstrahl-Therapie
Centrum (HIT), Germany
HT-3-1 (14:00) Influence of Tissue Composition in Proton Therapy
Verification and the Importance of 15O: a Comparison of PET and
Prompt Gamma Radiation
D. Oxley, P. Dendooven
KVI, University of Groningen, The Netherlands
HT-3-2 (14:15) Experimental Verification of the Determination of Beam
Properties Using Scattered Charged Particles for Real-Time Quality
Assurance in Proton Hadrontherapy
M. Battaglia1,2, V. Bashkirov3, F. Hurley3, R. Schulte3
1
UCSC, USA; 2LBNL, USA; 3Loma Linda University Medical Center, USA
HT-3-3 (14:30) Development of a 2D Scintillating Fiber Detector for
In-Vivo Range Verification in Proton Radiotherapy
O. Koybasi, Massachusetts General Hospital, USA
HT-3-5 (15:00) A High-Frame Rate Monolithic Pixel Detector for Real
Time Beam Imaging and Profilometry
M. L. Caccia, Universita’ degli Studi dell’Insubria, Italy
HT-3-6 (15:15) Proposed Fabrication of 3D Silicon Sensors as a Mini
and Micro-Dosimeter for Quality Assurance in Conventional and
Hadron Therapy
A. Kok, SINTEF, Norway
HT-3-7 (15:30) Study of the Capabilities of the Timepix Detector for
Carbon Ion Beam Radiotherapy Applications
M. Martisikova, Heidelberg University Hospital, Germany
HT-3-8 (15:45) Development of a Range Counter with SiPM Readout
for Proton CT
R. Schulte, Loma Linda Hospital, USA
On behalf of the pCT Collaboration
HT-4-2 (16:30) Proton and Carbon Radiography: Characterizing
Modulation Transfer Function and Spatial Resolution
J. Seco1, M. Oumano1,2, N. Depauw1, M. F. Dias1,3, R. P. Teixeira1,3, O.
Koybasi1, M. F. Spadea4,1
1
Harvard Medical School and Massachusetts General Hospital, USA; 2University
of Massachusetts, USA; 3University of Lisbon, Portugal; 4Magna Graecia
University, Italy
HT-4-3 (16:45) Proton Computed Tomography: an Analysis of the
Outputs
C. Bopp1, J. Colin2, D. Cussol2, C. Finck1, M. Labalme2, M. Rousseau1, D.
Brasse1
1
Université de Strasbourg, IPHC, France; 2LPC CAEN, ENSICAEN, France
HT-4-4 (17:00) Status of Quality Assurance Using Particle Therapy
Simulation Framework in Particle Therapy Facility in Japan
T. Akagi1, T. Aso2, A. Kimura3, S. Kameoka4, Y. Maeda5, N. Matsufuji6, T.
Nishio4, C. Omachi7, T. Sasaki8, T. Toshito7, T. Yamashita1
1
Hyogo Ion Beam Medical Center, Japan; 2Nagaoka University of Technology,
Japan; 3Ashikaga Institute of Technology, Japan; 4National Cancer Center
Hospital East, Japan; 5Fukui Prefectural Hospital Proton Therapy Center, Japan;
6
National Institute for Radiology Science, Japan; 7Nagoya City, Japan; 8KEK,
Japan
HT-4-5 (17:15) Gate Simulation of a Complete Proton Treatment
Combined with Prompt-Gamma Monitoring
D. Sarrut, Université de Lyon, France
HT-4-6 (17:30) PET-based Dose Delivery Verification in
Hadrontherapy: Simulation Study of PET System Designs in Realistic
Clinical Conditions
C. Robert, CNRS, Campus d’Orsay, France
HT-4-7 (17:45) SOI Microdosimetry for In-field and Out-of-field
Hadron Therapy Treatment Fields
D. Prokopovich
Australian Nuclear Science And Technology Organisation, Australia
Session Chairs: Katia Parodi, Heidelberger Ionen Therapie, Heidelberg,
Germany
Patrick J. Le Du, IPNL,IN2P3, France
HT-4-1 (16:15) A Proton Simulator for Testing Implementations of
Proton CT Reconstruction Algorithms on GPGPU Clusters
R. Schulte, Loma Linda Hospital, USA
76 Sunday - Workshop Oral Presentations Sunday - Workshop Oral Presentations 77
Notes
78 Sunday - Workshop Oral Presentations Notes
Sunday - Workshop Oral Presentations 79
07:00
07:30
08:00
Monday, 29 October
Grand Ballroom
Center
Grand Ballroom
South
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
Paradise Pier Pacific
Ballroom
Grand Ballroom
North
Exhibit Hall
North
Monday - NSS Oral Presentations
NP1 NSS Plenary Session 1
Monday, Oct. 29 08:30-10:00 Grand Ballroom Center
Session Chairs: Maxim P. Titov, CEA Saclay, IRFU/SPP,
Ingrid-Maria Gregor, DESY, Germany
09:00
09:30
NP1: NSS Plenary 1
10:00
R01: CdZnTe1
SC6: Medical Image
Reconstruction
SC7: Physics and
Design of Detectors for
SPECT and PET
08:30
NP1-1 (08:30) Official NSS Opening and NPSS Award Ceremony
M. Titov, CEA SACLAY, France; I.-M. Gregor, DESY, Germany
NP1-2 (09:00, invited) The Large Hadron Collider: Unveiling the
Universe
R.-D. Heuer, CERN, Switzerland
NP2 NSS Plenary Session 2
10:30
11:00
11:30
NP2: NSS Plenary 2
R02: Defects
SC6: Medical Image
Reconstruction
12:00
SC7: Physics and
SPECT and PET
Session Chairs: Maxim P. Titov, CEA Saclay, IRFU/SPP, France
NP2-1 (10:30, invited) Recent Highlight from the AMS Cosmic Ray
Observatory on the International Space Station
M. Pohl, Univ. de Genève, Switzerland
NP2-2 (11:15, invited) The National Ignition Facility and Fusion
Ignition: Status and Progress
E. I. Moses, Lawrence Livermore National Laboratory, USA
12:30
13:00
NSS Luncheon
N2 Synchrotron Radiation and FEL
Instrumentation
14:00
14:30
15:00
15:30
LC1: Introduction
16:00
16:30
17:00
17:30
18:00
18:30
LC2: ILC/CLIC Accelerator and
Detector Concepts
N2: Synchrotron Radiation and
FEL Instrumentation
N3: Instrumentation for
Homeland Security I: Detection
R04: RTSD Poster 1
N4: Analog and Digital Circuits I
SC6: Medical Image
Reconstruction
R03: TlBr
SC6: Medical Image
Reconstruction
SC7: Physics and
SPECT and PET
N0: NSS Poster I
SC7: Physics and
SPECT and PET
13:30
Monday, Oct. 29 16:30-18:30 Grand Ballroom South AB
Session Chairs: Markus Kuster, European XFEL GmbH, Germany
Peter Denes, Lawrence Berkeley National Laboratory,
USA
N2-1 (16:30) A 4 Mpixel Multiport CCD Detector with 8 Arrayed
19:00
Sensors for X-Ray Free-Electron Laser Facility SACLA
S. Ono1, T. Kameshima2, K. Kobayashi1,2, T. Kudo1, Y. Kirihara1, K. Ozaki1,
A. Kiyomichi2, T. Abe1, M. Yamaga1,2, T. Horigome3, T. Hatsui1,2
1
RIKEN, Japan; 2Japan Synchrotron Radiation Research Institute, Japan;
3
Institute for Molecular Science, Japan
N2-2 (16:45) A 1 MPixel Fast CCD Sensor for X-Ray Imaging
D. Doering, N. Andresen, D. Contarato, P. Denes, J. Joseph, P. McVittie,
J.-P. Walder, Lawrence Berkeley National Laboratory, USA; J. Weizeorick,
Argonne National Laboratory, USA
N2-3 (17:00) EXCALIBUR: a Three Million Pixels Photon Counting
Area Detector for Coherent Diffraction Imaging Based on the Medipix3
ASIC
N. Tartoni, P. Gibbons, E. Gimenez, I. Horswell, J. Marchal, U. Pedersen,
Z. Pesic, R. Plackett, C. Rau, R. Somayaji, J. Spiers, J. Thompson, B. Willis,
Diamond Light Source ltd., UK; C. Angelsen, P. Booker, S. Burge, J. Lipp, T.
Nicholls, S. Taghavi, M. Thorpe, STFC, Rutherford Appleton Laboratory, UK
N2-4 (17:15) Milestone Achievements in the Development of the
DEPFET Sensor with Signal Compression for the European XFEL
M. Porro1,2, 1Max Planck Institut fuer Extraterrestrische Physik, Germany;
2
MPI Halbeleiterlabor, Germany
On behalf of the DSSC Consortium
19:30
80 80
Monday - NSS Oral Presentations 81
N2-5 (17:30) Development of the LPD, a High Dynamic Range Pixel
Detector for the European XFEL
M. J. French1, C. Angelsen1, S. Burge1, J. Coughlan1, R. Halsall1, M. Hart1,
A. Koch2, M. Kuster2, P. Seller1, T. Nicholls1, T. Stephen1, A. Blue3, A. Joy4,
V. Oshea3, M. Wing4
1
STFC Rutherford Appleton Laboratory, UK; 2Glasgow University, UK;
3
University College, UK; 4European XFEL GmbH, Germany
N2-6 (17:45) The AGIPD Detector for the European XFEL
D. Greiffenberg, Paul-Scherrer-Institut (PSI), Schweiz
On behalf of the AGIPD Collaboration
N2-7 (18:00) The Cornell-SLAC Pixel Array Detector at LCLS
P. A. Hart1, A. Dragone1, B. Duda1, D. Freytag1, R. Herbst1, S. Herrmann1,
C. J. Kenney1, J. Morse2, M. Nordby1, J. Pines1, G. Haller1, S. Boutet1, G.
Williams1
1
SLAC National Accelerator Laborator, US; 2ESRF, France
N2-8 (18:15) Eiger, a Fast Framing, Large Area Pixel Detector for X-Ray
Applications
I. Johnson, A. Bergamaschi, R. Dinapoli, D. Greiffenberg, B. Henrich, R.
Horisberger, A. Mozzanica, V. Radicci, E. Schmid, B. Schmitt, A. Schreiber,
G. Theidel, X. Shi
Paul Scherrer Institut, Switzerland
N3 Instrumentation for Homeland Security I:
Detection
Monday, Oct. 29 16:30-18:30 Magic Kingdom Ballroom 1
Session Chairs: Richard Kouzes, Pacific Northwest National Laboratory,
USA
Sara Pozzi, University of Michigan, USA
N3-1 (16:30, invited) A Decade of Nuclear Science Research for
Homeland Security: Reflections, Perspectives, and Challenges
A. J. Peurrung, Pacific Northwest National Laboratory, USA
N3-2 (17:00) Determining 239Pu Mass Using an HPGe Detector: a New
Technique for Safeguards
N. Mascarenhas, M. Cronholm, A. Lavietes, R. Plenteda
IAEA, Austria
N3-3 (17:15) Performance Optimization of Systems Containing
Boron-10 Lined Proportional Counters
K. S. McKinny, T. R. Anderson, N. H. Johnson
GE Energy, USA
N3-4 (17:30) Alternatives to Helium-3 for Neutron Detection in
National Security Applications
A. T. Lintereur1, J. H. Ely1, E. R. Siciliano1, M. T. Swinhoe2, R. T. Kouzes1
1
Pacific Northwest National Laboratory, USA; 2Los Alamos National Laboratory,
USA
N3-5 (17:45) Forbush Decrease of March 2012 Detected Using a
Commercially-Available Muon-Tomography Cargo Scanner
A. Lehovich, G. S. Blanpied, R. C. Reed, S. C. McKenney, P. P. Kurnadi, P.
C. Lam, M. J. Sossong
Decision Sciences International Corporation, USA
N3-6 (18:00) Spectral Analysis of Aerial Gamma Ray Data from the
Fukushima Dai-Ichi Nuclear Power Plant Accident Response
C. E. Seifert, R. S. Detwiler, J. I. Friese
Pacific Northwest National Laboratory, USA
N3-7 (18:15) Benchmarking Detector and Localization Analysis Toolkit
for Development of Airborne Radiation Detectors
B. J. Quiter1, D. H. Chivers1, R. J. Cooper1, M. Quinlan1, L. Mihailescu1, S.
S. Huh1, A. Zoglauer2, K. Vetter1,3, L. McLean4, T. Hendricks4, K. McCall4
1
Lawrence Berkeley National Laboratory, USA; 2Space Sciences Laboratory,
USA; 3University of California, USA; 4Remote Sensing Laboratory, USA
82 Monday - NSS Oral Presentations N4 Analog and Digital Circuits I
Monday, Oct. 29 16:30-18:30 Magic Kingdom Ballroom 2
Session Chairs: Stuart A. Kleinfelder, University of California, Irvine,
USA
Gianluca Traversi, University of Bergamo, Italy
N4-1 (16:30) SPIROC: Design and Performance of a Dedicated Very
Front-End for an ILC Prototype Hadronic Calorimeter with SiPM
L. Raux1, S. Callier1, S. Conforti di Lorenzo1, F. Dulucq1, C. de La Taille2,
G. Martin-Chassard1, N. Seguin-Moreau1
1
Laboratoire de l’acclrateur linaire (LAL), France; 2IN2P3, France
N4-2 (16:45) Developement of Readout ASIC for FPCCD Vertex
Detector at the ILC
E. Kato1, S. Hisao2, H. Ikeda3, K. Itagaki1, Y. Sugimoto4, Y. Takubo4, H.
Yamamoto1
1
Tohoku University, Japan; 2Shishu University, JAPAN; 3JAXA, JAPAN; 4KEK,
Japan
N4-3 (17:00) Real-Time Clustering in the Belle II Pixel Vertex Detector
A. Wassatsch, R. Richter, C. Kiesling
Max-Planck-Institut fr Physik, Germany
N4-4 (17:15) Development of a Wide-Dynamic Range Front-End ASIC
for the W+Si Sampling Calorimeter
S. Hayashi, H. Hamagaki, T. Gunji, Center for Nuclear Study, University of
Tokyo, Japan; M. Tanaka, KEK, Open-It, Japan; H. Ikeda, JAXA, Open-It,
Japan
N4-5 (17:30) The VICTR Circuit, a Front-End ASIC for Future Silicon
Trackers with Clustering and Tracking Capabilities and Asynchronous
Data Readout
G. Magazzu’, University of California Santa Barbara, USA; M. Johnson, J.
Hoff, R. Lipton, FNAL, USA
N4-6 (17:45) A Sub-10ps Resolution Current Discriminator for Timing
Applications
X. Zhou1,2, Z. Deng1,2, Y. Wang1,2, Y. N. Liu1,2
1
Tsinghua University, China; 2Ministry of Education, China
N4-7 (18:00) Architecture and Design of the AGIPD Detector for the
European XFEL
U. Trunk1, J. Becker1, L. Bianco1, R. D. Dinapoli2, P. Goettlicher1, H.
Graafsma1,3, D. Greiffenberg2, M. Gronewald4, B. Henrich2, H. Hirsemann1,
S. Jack1, R. Klanner5, A. Klyuev1, H. Hans Krueger4, A. Marras1, A.
Mozzanica2, B. Schmitt2, X. Shi2, J. Z. Zhang5, F. Eckhart5, S. Joern5
1
DESY Deutsches Elektronen-Synchrotron, Germany; 2PSI Paul Scherrer
Institut, Switzerland; 3Mid Sweden University, Sweden; 4University of Bonn,
Germany; 5Universty of Hamburg, Germany
N4-8 (18:15) The DSSC Pixel Readout ASIC with Amplitude
Digitization and Local Storage for DEPFET Sensor Matrices at the
European XFEL
F. Erdinger1, P. Fischer1, L. Bombelli2, S. Facchinetti2, K. Hansen3, P.
Kavalakuru3, M. Kirchgessner1, M. Manghisoni4, M. Porro5, E. Quartieri4,
C. Reckleben3, J. Soldat1
1
Heidelberg University, Germany; 2Politecnico di Milano, Italy; 3Deutsches
Elektronensynchrotron DESY, Germany; 4Universita di Bergamo, Italy; 5MaxPlanck-Institut fuer extraterrestrische Physik, Germany
Monday - NSS Oral Presentations 83
Monday - RTSD Oral
Presentations
R03 TlBr
Monday, Oct. 29 Session Chair: 14:00-15:25 Magic Kingdom Ballroom 2
Arnold Burger, Fisk University, USA
R03-1 (14:00, invited) Timing Performance of TlBr Detectors
R01 CdZnTel
Michael Fiederle, Freiburger Materialforschungszentrum,
Germany
R01-1 (09:00, invited) Investigation of the Electric Field Sustainability
Due to the Different Electrical Contact Configurations, on CdZnTe
Materials Grown by THM Method under Different Polarisation
Conditions.
G. Prekas, U. El-Hanany, S. Taherion, L. Gusak, A. Densmore, P. Lu, H.
Chen, G. Macaloney, G. Bindley
Redlen Technologies, Canada
R01-2 (09:20, invited) Development of Photon Counting Energy
Dispersive Detectors for Mammography
J. S. Iwanczyk1, E. Nygard2, J. C. Wessel2, N. Malakhov2, G. Wawrzyniak2,
N. E. Hartsough1, T. Gandhi1, W. C. Barber1
1
DxRay, Inc., USA; 2Interon AS, Norway
R01-3 (09:40) Understanding Edge Effects for Improving the CdZnTe
Detector-Fabrication Process
G. S. Camarda, A. E. Bolotnikov, Y. Cui, A. Hossain, K. Kim, G. Yangs, R.
B. James
Brookhaven National Lab, USA
K. Hitomi1, T. Tada1, T. Onodera2, T. Shoji2, S.-Y. Kim1, Y. Xu1, K. Ishii1
1
Tohoku University, Japan; 2Tohoku Institute of technology, Japan
R03-2 (14:20, invited) Thallium Bromide Gamma-Ray Spectrometers
K. Shah, H. Kim, A. Churilov, Y. Ogorodnik, A. Kargar, G. Ciampi, L.
Cirignano, W. Higgins, S. Kim, Radiation Monitoring Devices Inc., USA; F.
Olschner, Cremat Inc., USA
R03-3 (14:40) TlBr Coplanar Grid Detectors
H. Kim, L. Cirignano, A. Kargar, A. Churilov, G. Ciampi, W. Higgins,
Radiation Monitoring Devices Inc., USA; F. Olschner, Cremat Inc., USA; P. N.
Luke, J. S. Lee, M. Amman, Lawrence Berkeley National Laboratory, USA
R03-4 (14:55) Electro-Migration of Impurities in TlBr
K. H. Kim1, H. Kim2, A. E. Bolotnikov1, G. S. Camarda1, R. Tappero1, A.
Hossain1, Y. Cui1, G. Yang1, L. Cirignano2, K. S. Shah2, R. B. James1
1
Brookhaven National Laboratory, USA; 2Radiation Monitering Devices, Inc.,
USA
R03-5 (15:10) Synchrotron Characterisation of Polarization Effects in
TlBr X-Ray Detectors.
C. C. T. Hansson1, A. Owens1, A. Kozorezov2, F. Quarati3, V. Gostilo4, M.
Shorohov4, J. V. D. Biezen1
1
European Space Agency / ESTEC, The Netherlands; 2University of Lancaster,
United Kingdom; 3Technical University of Delft, The Netherlands; 4Baltic
Scientific Instruments, Latvia
R02 Defects
Martine C. Duff, Savannah River National Lab, USA
R02-1 (10:30, invited) Defect Characterization in Full Encapsulated
CdZnTe
A. Cavallini, B. Fraboni, A. Castaldini, Department of Physics University of
Bologna, Italy; L. Marchini, N. Zambelli, G. Benassi, A. Zappettini, IMEMCNR, Italy
R02-2 (10:50, invited) Asymmetries of CZT Detectors Used for Gamma
Ray Spectroscopy
J. Crocco1, H. Bensalah1, Q. Zheng1, A. Black1, B. Fraboni2, D. Cavalcoli2,
A. Castaldini2, A. Cavallini2, E. Alves3, V. Corregidor3, P. Hidalgo4, O. Vela5,
E. Dieguez1
1
University Autonoma, Spain; 2University of Bologna, Italy; 3Institute of Nuclear
Technology, Portugal; 4CIEMAT, Spain; 5Complutense University, Spain
R02-3 (11:10, invited) Improving the Properties of CdZnTe Crystals by
Post-growth Annealing with Cd and Zn Vapor Control
G. Yang1, A. E. Bolotnikov1, P. M. Fochuk2, Y. Cui1, G. S. Camarda1, A.
Hossain1, K. H. Kim1, R. B. James1
1
Brookhaven National Laboratory, USA; 2Chernivtsi National University,
Ukraine
R02-4 (11:30) Atomic and Electronic Structure of Dislocations in CdTe/
CZT
V. Lordi, D. Aberg, E. Cho
Lawrence Livermore National Lab, USA
R02-5 (11:45) Characterisation and Simulation of 15 mm Thick (Cd,Zn)
Te Nuclear Detectors Grown by MPTVT
M. Ayoub, J. R. Brown, J. N. E. McGrath, P. D. Scott, J. T. Mullins
Kromek, U.K.
84 Monday - RTSD Oral Presentations Monday - RTSD Oral Presentations 85
Monday - Linear Collider Event
Oral Presentations
LC1 Introduction
Session Chair: TBD
LC1-1 (14:00, invited) Welcome to the Special Linear Collider Event
R.-D. Heuer, CERN, Switzerland
LC1-2 (14:10, invited) Brief Overview of the ILC History and
Milestones, Summary of ILC TDR, Perspectives
B. Barish, California Institute of Technology, USA
LC1-3 (14:25, invited) Brief Overview of the CLIC History and
Milestones, Summary of CLIC CDR, Perspectives
S. Stapnes, CERN, Switzerland
LC1-4 (14:40, invited) Physics of the Linear Colliders
H. Murayama1,2
1
LBNL, USA; 2Kavli Institute for the Physics and Mathematics of the Universe
(IPMU), Japan
LC1-5 (15:10, invited) Overview of Detectors for the Linear Collider
H. Yamamoto, Tohoku University, Japan
LC2 ILC/CLIC Accelerator and Detector
Concepts
Session Chair: TBD
LC2-1 (16:30, invited) The Superconducting RF Acceleration and the
International Linear Collider
N. Walker, DESY, Germany
LC2-2 (17:10, invited) X-Band Acceleration, Two-Beam Acceleration,
and the Compact Linear Collider
D. Schulte, CERN, Switzerland
LC2-3 (17:50, invited) State-of-the-art in Vertex Detectors for LC
M. Winter, IPHC Strasbourg, France
LC2-4 (18:15, invited) State-of-the-art in Silicon Tracking for LC
T. Nelson, SLAC National Accelerator Laboratory, USA
86 Monday-LinearColliderEventOralPresentations Monday - NSS Poster
Presentations
N1 NSS Poster Session I
Monday, Oct. 29 14:00-16:00 Exhibit Hall North
Session Chairs: Daniel Haas, SRON Netherlands Institute for Space
Research, The Netherlands
Andreas Mussgiller, DESY, Germany
Marco Petasecca, Centre of Medical Radiation Physics University of Wollongong, Australia
Instrumentation for Homeland Security
N1-1 High Position Resolution MRPC Developed for Muon
Tomography
Y. Wang, X. Fan, X. Li, J. Wang, H. Chen, X. Wang, J. Cheng
Engineering Physics Department, Tsinghua University, China
N1-2 A Large Area Cosmic Ray Detector for the Inspection of Hidden
High-Z Materials Inside Containers
D. Lo Presti, University of Catania - I.N.F.N. Catania, Italy
On behalf of the Muon Portal collaboration
N1-3 Online Baggage Inspection with Single-Slice-Helical CT
W. Bi1, L. Li2, Y. Wang1, L. Zhang2, Z. Chen2
1
China institute of nuclear information and economics, China; 2Tsinghua
University, China
N1-4 Construction, Commissioning and First Data from the CRIPT
Muon Tomography Project
V. Anghel1, J. Armitage2, J. Botte2, K. Boudjemline2, D. Bryman3, J. Bueno3,
E. Charles4, T. Cousins5, A. Erlandson2, G. Gallant4, R. Gazit3, V. Golovko1,
R. Hydomako3, C. Jewett1, G. Jonkmans1, Z. Liu3, M. P. C. Magill6, B.
E. Morgan6, S. Noel5, G. Oakham2, A. Robichaud2, T. J. Stocki6, M.
Thompson1, D. Waller7
1
Atomic Energy of Canada Limited, Canada; 2Carleton University, Canada;
3
Advanced Applied Physics Solutions, Canada; 4Canada Border Services Agency,
Canada; 5International Safety Research, Canada; 6Health Canada, Canada;
7
Defence Research and Development Canada, Canada
N1-5 Activation of Sodium Iodide Detectors in an Active Interrogation
Environment
M. Ellis1, L. Mitchell2, S. Jackson2, J. Zier2, J. O’Malley1, J. Threadgold1, C.
Clemett1, A. Thandi1, P. Martin1
1
AWE, UK; 2Naval Research Laboratory, USA
N1-6 High Energy Gamma Resolution: Signal Analysis and Data Fusion
Methodologies
C. Shenton-Taylor, P. R. Arthur, AWE, RG7 4PR
N1-7 Material Recognition with Dual Energy Single-Slice-Helical CT
W. Bi1, L. Zhang2, Y. Liu2, L. Li2, Y. Wang1, Z. Chen2
1
China institute of nuclear information and economics, China; 2Tsinghua
Univeristy, China
N1-8 Prior Knowledge and Maximum Likelihood Reconstruction
Algorithms for Muon Scattering Tomography
C. A. Steer, S. Quillin, J. Burns, S. Robertson, AWE, UK
N1-9 Photofission for Active SNM Detection II : Intense Pulsed
19F(p,αγ)16O Characteristic Gamma Source
C. Hill, J. O’Malley, M. Ellis, P. Mistry, R. Maddock, J. Precious, Atomic
Weapons Establishment, UK; F. C. Young, S. L. Jackson, D. G. Phipps, R.
Woolf, B. Phlips, Naval Research Laboratory, USA
Monday - NSS Poster Presentations 87
N1-10 Pulse Shape Discrimination for CLYC Based Handheld
Instruments
A. Gueorguiev, J. Glodo, J. Tower, U. Shirwadkar, P. O’Dougherty, K. Shah
RMD Inc., USA
N1-11 The REWARD Project: Real Time Wide Area Radiation
Surveillance System
C. Fleta, Instituto de Microelectronica de Barcelona, IMB-CNM (CSIC), Spain
On behalf of the REWARD Consortium
N1-12 He-4 Scintillation Detectors for Neutron Active Interrogation
U. Gendotti1, R. Chandra1, G. Davatz1,2, H. Friederich1,2, D. Murer1,2, V.
Solovyev3
1
Arktis Radiation Detectors Ltd, Switzerland; 2ETH Zurich, Switzerland;
3
Rapiscan Laboratories, USA
N1-13 A NaI(Tl) Scintillator for in Situ Environmental Studies and
Laboratory Detection Measurements of Aqueous Potassium Chloride
A. J. Parker, C. Boxall, M. J. Joyce, Lancaster University, UK; P. Schotanus,
Scionix Ltd, Netherlands
N1-14 Studies for a High-Resolution Two-Dimensional Time Encoded
Neutron Imager
E. Brubaker, P. Marleau, K. McMillan, N. Renard-Le Galloudec
Sandia National Laboratories, USA
N1-15 False Alarm Suppression of Radiation Portal Monitor
Measurements Using Machine Learning Analysis of Spatial Signatures
S. E. Labov, K. E. Nelson, Lawrence Livermore National Laboratory, USA; A.
Dubrawski, P. Huggins, S. Ray, Carnegie Mellon University, USA
N1-16 Neutrons for Active SNM Detection: Intense Pulsed 7Li(p,n)7Be
Source.
C. D. Clemett, P. Martin, J. Threadgold, C. Hill, M. Ellis, AWE, UK; S. L.
Jackson, R. Woolf, J. C. Zier, L. Mitchell, D. D. Hinshelwood, NRL, USA
N1-17 Study of 3D Reconstruction Algorithm used in Cosmic-Ray
Muon Radiography
J. Cheng1, B. Yu1,2, Z. Zhao1,2, X. Wang1
1
Department of Engineering Physics, Tsinghua University, China; 2Key
Laboratory of Particle & Radiation Imaging (Tsinghua University), Ministry of
Education, China
N1-18 Detection of Photon-Induced Excitations in 235U with LaBr3 (Ce)
Scintillating Detectors
M. Omer1, H. Negm1, H. Zen1, T. Hori1, T. Kii1, K. Masuda1, R. Hajima2,
T. Hayakawa2, T. Shizuma2, I. Daito2, M. Fujiwara3, S. H. Park4, N.
Kikuzawa3, G. Rusev5, A. Tonchev6,7, Y. K. Wu6,7
1
Institute of Advanced Energy, Kyoto University, Japan; 2Japan Atomic Energy
Agency, Japan; 3Research Center of Nuclear Physics, Osaka University, Japan;
4
Korea Atomic Energy Research Institute, South Korea; 5Chemistry Division, Los
Alamos National Laboratory, USA; 6Triangle Universities Nuclear Laboratory,
USA; 7Department of Physics, Duke University, USA
N1-19 Muon Scattering Tomography with Resistive Plate Chambers
P. Baesso1, D. Cussans1, P. Glaysher1, S. Quillin2, S. Robertson2, C. Steer2, C.
Thomay1, J. Velthuis1, C. Vassallo1
1
Bristol University, UK; 2Atomic Weapon Establishment, UK
N1-20 A Peak Detection Method in Noisy Spectrums Using Principal
Component Analysis
E. Min1, M. Ko1, K. Lee1, M. H. Nguyen1, Y. Kim1,2, J. Joung1,2
1
Korea University, Korea; 2Nucare Medical Systems Inc., Korea
N1-21 Determination of Scaling Factors for Low and Intermediate Level
Dry Radioactive Waste from Kozloduy Nuclear Power Plant
K. Mitev, T. Boshkova, G. Gerganov, Sofia University, Bulgaria; C. Andreev,
N. Kirilova, Theta Consult LTD, Bulgaria; E. Stoyanova, V. Zhivkova, M.
Iliev, G. Neshovska, Kozloduy NPP, Bulgaria; G. Georgiev, State Enterprise
Radioactive Waste, Bulgaria
N1-22 A Prototype Scintillating-Fibre Detector for the Cosmic-Ray
Muon Radiography of Legacy Nuclear Waste.
S. L. Nutbeam, University of Glasgow, United Kingdom
88 Monday - NSS Poster Presentations N1-23 Modeling Scattering for Security Applications: a Multiple Beam
X-Ray Diffraction System
C. Cozzini, GE Global Research, Germany; S. Olesinski, G. Harding, Morpho
Detection, Germany
N1-24 Focusing Atmospheric Muons Through Scattering in Dense
Material
G. K. Van Dyk, L. W. Burggraf, A. A. Bickley
Air Force Institute of Technology, USA
N1-25 Radiation Intensity Image Reconstruction in TGS Using ART
Algorithm with Geometrically-Corrected System Matrix and TV
Constraint
Z. Liu1,2, L. Zhang1,2
1
Tsinghua University, China; 2Key Laboratory of Particle & Radiation Imaging
(Tsinghua University), Ministry of Education, China
N1-26 An Imaging Neutron/Gamma-Ray Spectrometer
J. Ryan1, C. Bancroft1, A. Bedell1, P. Bloser1, D. Fourguette2, L. Larocque2,
J. Legere1, A. Madden1, M. McConnell1, H. McTigue1, G. Ritter2, M.
Rousseau1, G. Wassick2
1
University of New Hampshire, USA; 2Michigan Aerospace Corporation, USA
N1-27 Design and Construction of Muon Tomography Facility Based on
MRPC Detector for High-Z Materials Detection
X. Wang1,2, J. Cheng1,2, Y. Wang1,2, Q. Yue1,2, Z. Zhao1,2, Z. Zeng1,2, M.
Zeng1,2, Z. Deng1,2, H. Yi1,2, Z. Luo1,2, X. Yue1,2, B. Yu1,2, H. Pang3, H.
Yang3, S. Liu3, P. Zhu4
1
Key Laboratory of Particle & Radiation Imaging (Tsinghua University),
Ministry of Education, China; 2Tsinghua University, China; 3China Institute of
Atomic Energy, China; 4East China Institute of Technology, China
N1-28 Gamma, Conversion Electron and X-Ray Spectrum of Gd157 for
Use in Neutron Detection
J. Ralston, L. Cao, P. Kandlakunta, P. Mulligan, Ohio State University, USA
N1-29 Design of a Resistorless ASIC Preamplifier for Silicon Strip
Detectors with Non-Linear Pole/Zero Cancellation and OverloadRecovery Circuitry
A. Pullia1,2, S. Capra1
1
University of Milano, Italy; 2INFN, Italy
N1-30 Machine Learning for the Cosmic Ray Inspection and Passive
Tomography Project (CRIPT).
T. J. Stocki1, M. P. C. Magill1, B. E. Morgan1, J. Smith1, D. Ong1, V. N. P.
Anghel2, J. Armitage3, J. Botte3, K. Boudjemline3, D. Bryman4, J. Bueno4,
E. Charles5, T. Cousins6, A. Erlandson3, G. Gallant5, R. Gazit4, V. Golovko2,
R. Hydomako4, C. Jewett2, G. Jonkmans2, Z. Liu4, M. McCall6, S. Noel6, G.
Oakham3, A. Robichaud3, M. Thompson2, D. Waller7
1
Health Canada, Canada; 2Atomic Energy of Canada Ltd., Canada; 3Carleton
University, Canada; 4Advanced Applied Physics Solutions, Canada; 5Canadian
Border Services Agency, Canada; 6International Safety Research, Canada;
7
Defense Research and Development Canada, Canada
N1-31 Diagnosing Machine Learning Based Nuclear Evaluation System
A. Dubrawski, S. Ray, P. Huggins, Carnegie Mellon University, USA; S.
Labov, K. Nelson, Lawrence Livermore National Laboratory, USA
N1-32 Imaging Shielded High-Z Nuclear Material with a Compact
Muon Tomography Station Based on GEM Detectors
M. Hohlmann, V. Bhopatkar, M. J. Staib, J. Twigger
Florida Institute of Technology, USA
N1-33 Automatic Energy Calibration of Field Gamma-Ray
Spectrometers Using Natural Background Radiation
A. J. Caffrey1, D. J. Caffrey2, A. E. Egger1, K. M. Krebs1, C. J. Wharton1
1
Idaho National Laboratory, USA; 2University of California at San Diego, USA
N1-34 Improved Backpack Radiation Detectors for Homeland Security
J. L. Lacy, L. Sun, A. Athanasiades, C. S. Martin, G. J. Vazquez-Flores
Proportional Technologies, Inc., United States
N1-35 Pulsed Photofission Delayed Gamma Ray Detection for Nuclear
Material Identification
H. Yang, The University of Utah, USA; D. R. Norman, Idaho National
Laboratory, USA; D. R. Nakazawa, Canberra Industries, USA
N1-36 Real-Time Anomaly Recognition Techniques for NII X-Ray
Systems
M. Turqueti, J. White, B. Cardoso, Creative Electron, United States
N1-37 Suppressing Background Radiation Using Poisson Principal
Component Analysis
P. Tandon, P. Huggins, A. Dubrawski, Carnegie Mellon University, USA; S.
Labov, K. Nelson, Lawrence Livermore National Lab, USA
N1-38 CLYC in Gamma - Neutron Imaging System
L. S. Pandian, C. Whitney, J. Christian, J. Glodo, A. Gueorguiev, R.
Hawrami, M. R. Squillante, K. S. Shah
Radiation Monitoring Devices, USA
N1-39 Interpolation of Incompletely and Non-Uniformly Sampled
Survey Data for Buried Radioactive Point Source Detection
C. Jones, Z. Long, R. Unz, J. McCown, N. H. Younan
Mississippi State University, USA
N1-40 Investigations of a Small Human Portable Detection System for
Cargo Interrogation
L. J. Mitchell, B. F. Phlips, Naval Research Laboratory, USA; D. Strellis, T.
Gozani, M. King, Rapiscan Labortories, USA
N1-41 Portable Modular Neutron Detectors for Homeland Security
J. L. Lacy, A. Athanasiades, C. S. Martin, L. Sun, G. J. Vazquez-Flores
Proportional Technologies, Inc., USA
N1-42 Empirical and Computational Results from a Portable Prompt
Neutron Spectrometer
E. R. Myers1, T. M. Oakes2, S. L. Bellinger3, W. H. Miller2, T. J. Sobering3, P.
R. Scott1, C. B. Hoshor1, S. B. Swanekamp4, J. W. Schumer4, J. P. Apruzese4,
R. J. Commisso4, S. L. Jackson4, J. C. Zier4, B. V. Weber4, D. P. Murphy4, D.
S. McGregor3, A. N. Caruso1
1
University of Missouri - Kansas City, USA; 2University of Missouri - Columbia,
USA; 3Kansas State University, USA; 4Naval Research Laboratory, USA
N1-43 Determining Accuracy of Ground-Level Exposure Rates
Determined from Aerial Data
C. E. Seifert1, M. S. Reed2, J. M. Benz1, J. W. Hayes1, R. L. Malchow2
1
Pacific Northwest National Laboratory, USA; 2National Security Technologies,
USA
N1-44 Isotopic Composition Analysis Utilizing High-Energy Delayed
γ-Rays from Induced Fission
E. T. E. Reedy1, V. Mozin2, B. Ludewigt3, A. W. Hunt1
1
Idaho State University, USA; 2Lawrence Livermore National Laboratory, USA;
3
Lawrence Berkeley National Laboratory, USA
N1-45 Nuclear Resonance Fluorescence: Active Inspection Techniques
Using Pulsed Bremsstrahlung
H. A. Seipel1, E. T. E. Reedy1, M. T. Kinlaw2, J. T. Johnson2, S. M. Watson2,
G. A. Warren3, A. W. Hunt1
1
Idaho State University, USA; 2Idaho National Laboratory, USA; 3Pacific
Northwest National Laboratory, USA
N1-46 Dual Mode Neutron and Gamma-Ray Scintillation Dosimeter
C. J. Stapels1, E. B. Johnson1, X. J. Chen1, E. C. Chapman1, D. Fernandez1,
H. Lopez1, C. M. Whitney1, K. S. Shah1, F. L. Augustine2, J. F. Christian1
1
Radiaiton Monitoring Devices, USA; 2Augustine Engineering, USA
N1-47 Spent Fuel Modeling Validation for Ultra-High Rate Germanium
Detector Development
D. C. Rodriguez, Pacific Northwest National Laboratory, U.S.A.
On behalf of the Ultra-High Rate Germanium Group and Delayed Gamma
Collaboration
N1-48 A Point-Source Aerial Standoff Detection Algorithm Utilizing
Complex Background Models and a Likelihood Ratio Test
M. Quinlan, D. Chivers, R. Cooper, S. Huh, L. Mihailescu, B. Quiter,
K. Vetter, Lawrence Berkeley National Laboratory, USA; A. Zoglauer, Space
Sciences Laboratory, University of California, USA; L. McLean, T. Hendricks,
K. McCall, Remote Sensing Laboratory, Nellis AFB, USA
90 Monday - NSS Poster Presentations N1-49 Anomaly Detection of Threat Gamma-Ray Signatures with No
Prior Threat Knowledge
D. Boardman, A. Flynn, M. Reinhard, ANSTO, Australia
N1-50 MCNPX Characterization of Compact Superconducting
Cyclotron with 11B Target
M. A. Norsworthy, C. A. Miller, S. D. Clarke, S. A. Pozzi, University of
Michigan, USA; T. A. Antaya, Ionetix Corporation, USA
N1-51 Development of Active Neutron-Based Interrogation System with
D-D Neutron Source for Detection of Special Nuclear Materials
T. Misawa, Y. Takahashi, Y. Yamaguchi, T. Yagi, C. H. Pyeon, K. Masuda, T.
Kajiwara, H. Ohgaki, Kyoto University, Japan
N1-52 A 3D-Filtered Back-Projection Algorithm for Truck-Based
Coded-Aperture Detectors
D. Gunter1,2, A. Haefner3, R. Barnowski3, L. Supic3, S. Huh1, J. Maltz1, L.
Mihailescu1, K. Vetter1,3
1
Lawrence Berkeley National Laboratory, USA; 2Gunter Physics, USA;
3
University of California, USA
N1-53 Advanced Passive Stand-off Detection Capabilities
J. Valentine, R. Kuharski, W. Hood, B. Gardner, R. Penny, SAIC, USA; K.
Nelson, LLNL, USA; K. Ziock, L. Fabris, ORNL, USA
N1-54 Associated Particle Analysis for Cargo Material Identification
Modeling and Validation
D. Penn, L. Warman, Raytheon Applied Signal Technology, USA; D. Holslin,
K. Adams, J. Martinez, Science Applications International Corporation, USA;
D. Taylor, Department of Homeland Security, USA
Neutron Detectors and Instrumentation
N1-55 Production of Stilbene for Fast Neutron Detection
C. Lynch, S. Selin, T. Caughey, A. Inzalaco, Inrad Optics, USA; N. Zaitseva,
L. Carman, Lawrence Livermore National Laboratory, USA
N1-56 Image Reconstruction Using a Three-Plane Dual-Particle Imager
for Standoff Detection of Special Nuclear Material
J. K. Polack, A. Poitrasson-Rivire, M. C. Hamel, M. F. Becchetti, K. Ide, S.
D. Clarke, M. Flaska, S. A. Pozzi, University of Michigan, U.S.A.
N1-57 Multi-Range Zero Dead Time Approach on FPGA Based Wide
Range Neutron Monitoring System
H.-P. Chou, F.-M. Zhu, S.-Y. Chen, National Tsing Hua University, Taiwan
N1-58 Field Portable Neutron Spectrometer Based on the Bonner
Sphere Principles
J. Dubeau, S. S. hakmana Witharana, DETEC, Canada; J. Atanackovic,
A. Yonkeu, Atomic Energy Canada Ltd, Canada; W. Matysiak, McMaster
University, Canada; A. J. Waker, I. Aslam, University of Ontario Institute of
Technology, Canada; J. P. Archambault, National Research Council of Canada,
Canada
N1-59 Mobile Imaging of Neutrons for Emergency Responders
M. Gerling1, J. Goldsmith1, J. Brennan1, S. Kiff1, P. Schuster2, J. Steele1
1
Sandia National Laboratories, USA; 2University of California Berkeley, USA
N1-60 Development of a Large Area Position Sensitive Detector for Fast
Neutron Spectroscopy and Tomography
A. Nowack, J. Brennan, M. Peter, W. Mengesha, S. Mrowka, N. Renard-Le
Galloudec
N1-61 Further Investigations with GEM Detectors for Use on the ISIS
Spallation Neutron Source
D. M. Duxbury, N. J. Rhodes, E. M. Schooneveld, E. J. Spill
Science and Technology Facilities Council, RAL, UK
N1-62 A 4-Channel Multiplex Analyzer for Real-Time, Parallel
Processing of Fast Scintillators
M. J. Joyce, Lancaster University, United Kingdom; M. D. Aspinall, F. D.
Cave, Hybrid Instruments Ltd., United Kingdom
N1-63 A Novel in-situ Transmission Detector for Use During Small
Angle Neutron Measurements
D. E. Pooley, S. E. Rogers, R. K. Heenan, E. M. Schooneveld, N. J. Rhodes,
K. I. Fradley
STFC, Rutherford Appleton Laboratory, UK
N1-64 Neutron Spectrometry with a Boron-Loaded Liquid Scintillator
C. Liao, H. Yang, The University of Utah, USA
N1-65 Study of Li Diffusion in Re, Nb and Hf by Neutron Depth
Profiling
J. Vacik, I. Tomandl, V. Hnatowicz
Nuclear Physics Institute, Academy of Sciences of the Czech Republic, Czech
Republic
N1-66 A Fast Neutron Spectrometer Based on GEM-TPC
D. He1,2, Y. Li1,2, Z. Deng1,2, X. Cheng3, J. Li1,4, M. Huang1,2, Y. Li1,2
1
Tsinghua University, China; 2Ministry of Education, China; 3North China
Electric Power Univ., China; 4Institute of High Energy Physics, China
N1-67 Calibration of EJ309 Liquid Scintillator for Neutron
Spectrometry
J. Iwanowska, L. Swiderski, T. Krakowski, T. Kozlowski, M. Moszynski
National Centre for Nuclear Research, Poland
N1-68 Detector Prototype for Thermal Neutrons with Wavelength
Shifting Fiber Readout
R. Engels1, U. Clemens1, A. Erven1, W. Erven1, R. Fabbri1, M. Fiederle2, A.
Houben3, G. Kemmerling1, H. Loevenich1, S. Mueskes1, W. Schweika1, J.
Schelten1, S. van Waasen1
1
Forschungszentrum Juelich GmbH, Germany; 2University of Freiburg,
Germany; 3RWTH Aachen, Germany
N1-69 The Performance of the Kaon Spectrometer KAOS in MAMI-C
S. Nagao1, P. Achenbach2, N. Arai1, C. Ayerbe Gayoso2, R. Bohm2, O.
Borodina2,3, L. Debenjak4, M. O. Distler2, A. Esser2, Y. Fujii1, T. Gogami1,
M. Gomez Rodrıguez2, S. Hirose1, E. Kim3, J. Kusaka1, A. Margaryan5,
H. Merkel2, U. Muller2, S. N. Nakamura1, J. Pochodzalla2, J. Reinhold6,
T. R. Saito2,3,7, A. Sanchez Lorente7, S. Sanchez Majos2, B. S. Schlimme2,
M. Schoth2, F. Schulz2, C. Sfienti2, S. Sirca4, L. Tang8, K. Tsukada1, D.
Uchiyama1
1
Tohoku University, Japan; 2Johannes Gutenberg-Universitat, Germany; 3GSI
Helmholts Center for Heavy Ion Research, Germany; 4University of Ljubjana and
Institut, Slovenia; 5Yerevan Physics Institute, Armenia; 6Florida International
University, USA; 7Helmholtz Institute Mainz, Germany; 8Hampton University,
USA
N1-70 Development of Gas-Based 2-Dimensional Neutron Detector
with Individual Line Readout and Optical Signal Transmission System
K. Toh1, T. Nakamura1, K. Sakasai1, K. Soyama1, H. Yamamgishi1,2
1
Japan Atomic Energy Agency, Japan; 2Nippon Advanced Technology, Japan
N1-71 Large Area Sensing Arrays for Detection of Thermal Neutrons
G. R. Kunnen, D. Pressler, E. H. Lee, D. R. Allee, Arizona State University,
United States; J. W. Murphy, I. Mejia, M. Quevedo, B. Gnade, The University
of Texas at Dallas, United States
N1-72 Application of Silicon Photomultipliers in a Position-Sensitive
Scintillator Detector for Fast Neutron Imaging
F. Shi, J. Lu, X. Cai, L. Sun, Institute of High Energy Physics, Chinese Academy
of Sciences, P.R.China; Y. Xue, Lanzhou Institute of Physics, P.R.China
N1-73 Statistical Energy Determination in Neutron Detector Systems
for Neutron Scattering Science
R. J. Hall-Wilton1, K. H. Andersen1, D. Anevski2, J. Birch3, A. Hiess1, C.
Hoglund1,3, L. Hultman3, A. Khaplanov1,4, O. Kirstein1, T. Kittelmann1
1
European Spallation Source ESS AB, Sweden; 2Lunds Tekniska Hogskola
(LTH), Sweden; 3Linkoping University, Sweden; 4Institut Laue-Langevin, France
N1-74 Fabrication and Characterization of Source Gratings for Thermal
Neutron Phase Imaging
J. Kim1,2, S. W. Lee1, C. Ahn3, C. Kim2, G. Cho2
1
Korea Atomic Energy Research Institute, South Korea; 2Korea Advanced
Institute of Science and Technology, South Korea; 3National NanoFab Center,
South Korea
92 Monday - NSS Poster Presentations N1-75 Improvement of Vacuum Tube Type Neutron Image Intensifier
for Accelerator-Based Neutron Imaging
T. Kamiyama, H. Sato, K. Kino, Y. Kiyanagi
Faculty of Engineering, Hokkaido University, Japan
N1-76 Study of a 10B-based Multi-Blade Detector for Neutron
Scattering Science
F. Piscitelli1, J.-C. Buffet1, J. Correa1, B. Guerard1, A. Khaplanov1,2, P. Van
Esch1
1
Institut Laue-Langevin, France; 2European Spallation Source, Sweden
N1-77 Resolution and Accuracy Limitations in a Large Area Neutron
Sensitive Anger Camera
R. Riedel, C. Donahue, T. Visscher
Oak Ridge National Lab, USA
N1-78 Evaluation of Neutron/Gamma-Ray Sensitivity Ratio for
LiCaAlF6 Scintillators
K. Watanabe1, Y. Kondo1, Y. Takahashi1, A. Yamazaki1, A. Uritani1, T.
Iguchi1, N. Kawaguchi2, T. Yanagida3, Y. Fujimoto3, K. Fukuda2, S. Ishidu2,
A. Yoshikawa3
1
Nagoya University, Japan; 2Tokuyama　Corp., Japan; 3Tohoku University,
Japan
N1-79 Development of an Optical Fiber Detector for Neutron
Monitoring in Boron Neutron Caputure Therapy
Y. Kawabata, K. Watanabe, S. Maruyama, A. Yamazaki, T. Iguchi, A. Uritani,
Nagoya Universityersity, Japan; A. Yoshikawa, T. Yanagida, Y. Fujimoto,
Tohoku University, Japan
N1-80 Study of 10Boron-Lined Straw-Tube Detector Array for Neutron
Small Angle Scattering
C. Chen1,2, G. Y. Yang1,2, N. S. Zhu1,2,3, Q. W. Huang1,2,4, W. X. Wang1,2
1
Tsinghua University, China; 2Key Laboratory of Radiation Physics & Detection
Technology, China; 3SUN YAT-SEN University, China; 4Anti-Chemical
Command and Engineering Institute, China
N1-81 A Multi-Anode Photomultiplier Tube Based Wavelength-ShiftingFiber Detector for Neutron Diffraction
C.-L. Wang, K. D. Berry, L. G. Clonts, M. L. Crow, Y. Diawara, L. L. Funk,
B. W. Hannan, J. P. Hodges, R. A. Riedel, Oak Ridge National Laboratory,
US; C. Kline, H. E. Workman, PartTec Ltd., US
N1-82 Development of Two Dimensional Thermal Neutron Flux
Monitor Using Multi-Wire Proportional Counter for Boron Neutron
Capture Therapy
H. Tanaka, Y. Sakurai, M. Suzuki, S. Masunaga, Y. Kinashi, K. Ono, A.
Maruhashi, Kyoto University Research Reactor Institute, Japan
N1-83 Development of Epithermal Neutron Imaging with Designed
Resonance Filter
H. Tomita1, T. Kobayashi1, J. Kawarabayashi1, C. Shoda1, N. Fukumoto1, J.
Hori2, T. Matsumoto3, S. Uno4, M. Shoji4, T. Uchida4, T. Iguchi1
1
Nagoya University, Japan; 2Kyoto University, Japan; 3AIST, Japan; 4KEK, Japan
N1-84 Design Issues in Bonded Silicon as a Platform for Pixellated
Element, 3D, Volume Scalable, High Pressure and Exotic Material
Radiation Sensors.
M. S. Derzon, G. R. Bogart, L. D. Claus, D. K. Derzon, P. C. Galambos, M. D.
Henry, R. R. Kay, P. W. Lake, G. K. Robertson, Sandia National Laboratories, US
N1-85 Research of 10BF3 Surrounded Plastic Scintillator as Fast Neutron
Detector
Y. Liu1,2, Y. Yang1,2, Y. Tai1,2, W. Huang1,2,3
1
Tsinghua University, China; 2Ministy of Education, China; 3Anti-Chemical
Command and Engineering Institute, China
N1-86 Quantitative Measurements Using the Probing In-situ with
Neutron and Gamma rays (PING) Instrument for Basalt and Granite
Samples
A. M. Parsons1, J. G. Bodnarik1,2, L. Evans1,3, T. McClanahan1, S. F.
Nowicki1,4, J. Schweitzer5, R. Starr1,6
1
NASA/ Goddard Space Flight Center, USA; 2Vanderbilt University, USA;
3
Computer Sciences Corporation, USA; 4University of Michigan, USA;
5
University of Connecticut, USA; 6Catholic University of America, USA
N1-87 A Neutron Sensitive Microchannel Plate Detector with Cross
Delay Line Readout
K. D. Berry1, H. Z. Bilheux1, M. L. Crow1, Y. Diawara1, W. B. Feller2, L. L.
Funk1, A. Martin3, J. L. Robertson1, C. Wang1
1
Spallation Neutron Source - ORNL, USA; 2NOVA Scientific, Inc., USA;
3
Sensor Sciences, LLC, USA
N1-88 Development of 6LiF:ZnS(Ag)-Based Neutron Detector Coupled
to Wavelength-Shifting Fibers Readout at NIST Center for Neutron
Research
D. Lee1,2, J. B. Ziegler1, N. C. Maliszewskyj1, B. B. Maranville1, C. F.
Majkrzak1
1
National Institute of Standards and Technology, 20899; 2University of
Maryland, 20742
N1-89 Machine Learning for Digital Pulse Shape Discrimination
T. Sanderson, C. Scott, M. Flaska, S. Pozzi
University of Michigan, USA
N1-90 Muon-Induced Neutron Measurements at the Kimballton
Underground Research Facility
M. Sweany, A. Bernstein, N. Bowden, S. Dazeley, Lawrence Livermore
National Lab, USA; E. Brubaker, P. Marleau, D. Reyna, Sandia National Lab,
USA
N1-91 Thermal Neutron and Alpha Detection with ZnO Scintillators
B. J. Connors*1, B. Klein1, N. E. Hertel1, C. J. Summers1, J. Nause2, E. A.
Burgett3, G. S. Mickum1
1
Georgia Institute of Technology, USA; 2Cermet, Inc., USA; 3Idaho State
University, USA
N1-92 Passive Measurement of Organic-Scintillator Neutron Signatures
for Nuclear Safeguards Applications
J. L. Dolan1, E. C. Miller1, A. C. Kaplan1, L. Huang1, A. Enqvist1, M.
Flaska1, S. D. Clarke1, A. Tomanin2, P. Peerani2, D. L. Chichester3, S. A.
Pozzi1
1
University of Michigan, U.S.A; 2European Commission, Italy; 3Idaho National
Laboratory, U.S.A.
N1-93 Application of LiF Coated Diodes to Neutron Spectroscopy for
Thermal Through Fast Energies
M. A. Ford, A. A. Bickley, S. R. McHale, J. W. McClory, J. C. Petrosky
Air Force Institute of Technology, USA
N1-94 A Simulation of Detecting Neutrons from a 252Cf Neutron
Source Using a 6Li Foil Multi-Wire Proportional Counter
K. A. Nelson, S. Bolding, J. K. Shultis, D. S. McGregor
Kansas State University, USA
N1-95 Simulations of the Cosmic-Ray-Induced Neutron Background
M. F. Becchetti, K. Ide, A. Poitrasson-Rivere, M. C. Hammel, J. K. Polack,
M. Flaska, S. D. Clarke, S. A. Pozzi
University of Michigan, United States
N1-96 DPA-SSPM Based Fast Neutron Dosimeter Module for the Space
Environment
C. Whitney, J. Chen, E. Johnson, C. Stapels, E. V. Loef, J. Christian,
Radiation Monitoring Devices, Inc., USA; T. Prettyman, Planetary Sciences
Institute, USA; E. Benton, Oklahoma State University, USA
N1-97 Very Large Area Multi-Element Microstructured Semiconductor
Neutron Detector Panel Array
R. G. Fronk, S. L. Bellinger, D. S. McGregor, Kansas State University
S.M.A.R.T. Laboratory, USA; S. Tim, R. Taylor, D. Huddleston, Kansas State
University Electronics Design Laboratory, USA
N1-98 Neutron Detector Module for Portal Monitors: Straw Diameter
Optimization
J. L. Lacy, A. Athanasiades, C. S. Martin, L. Sun, G. J. Vazquez-Florez
Proportional Technologies, Inc., United States
N1-99 Physics Proof of Principle Results for Pixellated Element Gamma
and Neutron Sensors
M. S. Derzon, G. R. Bogart, L. D. Claus, D. K. Derzon, P. C. Galambos, M.
D. Henry, R. R. Kay, P. W. Lake, R. F. Renzi, G. K. Robertson
94 Monday - NSS Poster Presentations N1-100 Improved Wavelength-Shifting-Fiber Detector for Neutron
Scattering Facility Instruments
J. P. Hodges, C.-L. Wang, L. G. Clonts, Y. Diawara, B. W. Hannan, Oak
Ridge National Laboratory, USA; C. Kline, H. E. Workman, PartTec Ltd,
USA
N1-101 Amorphous Semiconductor Neutron Detector for Well Logging
A. J. Antolak1, S. S. Mao2, K.-N. Leung1,3
1
Sandia National Laboratories, USA; 2Lawrence Berkeley National Laboratory,
USA; 3,
N1-102 Real-Time, Fast-Neutron Spectroscopy for Source Identification
in Mixed-Field Imaging Applications
J. Beaumont1, M. Mellor2, M. Joyce1
1
Lancaster University, UK, United Kingdom; 2Createc Ltd, United Kingdom
N1-103 Development of Two-Dimensional Scintillation Detectors for
Neutron Spin Echo Spectrometers in J-PARC/MLF
T. Nakamura1, M. Katagiri2, T. Hosoya2, K. Toh1, M. Kitaguchi3, M. Hino3,
T. Ebisawa3, K. Sakasai1, K. Soyama1
1
Japan Atomic Energy Agency, Japan; 2Ibaraki University, Japan; 3Kyoto
University, Japan
N1-104 Development of a Segmented Plastic Fast Neutron Detector
S. C. Stave, D. V. Jordan
Pacific Northwest National Laboratory, WA
N1-105 Progress in Development of Plastic Scintillators with Pulse
Shape Discrimination Capability
I. A. Pawelczak, A. M. Glenn, N. P. Zaitseva, H. P. Martinez, M. L. Carman,
S. A. Payne, Lawrence Livermore National Laboratory, USA
N1-106 High Resolution Neutron Imaging of Microfossils
D. Vavrik, Institute of Theoretical and Applied Mechanics AS CR, v. v. i., Czech
Republic; J. Jakubek, S. Pospisil, Institute of Experimental and Applied Physics,
Czech Republic; J. Vacik, Nuclear Physics Institute AS CR, & Research Center
Rez, Czech Republic
N1-107 Nondestructive Assay of UF6 in Large Storage Cylinders Using
the Neutron Scatter Camera
W. Mengesha, M. Gerling, S. D. Kiff, P. Marleau
Sandia National Laboratories (SNL), USA
N1-108 Silicon Based Pillar Structured Thermal Neutron Detectors
R. J. Nikolic, Q. Shao, L. F. Voss, A. M. Conway, R. Radev, T.-F. Wang,
Lawrence Livermore National Lab., USA; M. A. Dar, C. L. Cheung,
University of Nebraska, USA
N1-109 Development of Novel Neutron Detectors with Thin Conversion
Layers in Inclined Geometry
R. Kampmann1,2,3, M. Stoermer1,2, G. Nowak1,2, T. Kuehl3, E. Praetzel3,
C. Horstmann1,2, M. Haese-Seiller1, J.-F. Moulin1,2, D. Hoeche1, R. HallWilton4, M. Mueller1,2, A. Schreyer1,2
1
Helmholtz-Zentrum Geesthacht, Germany; 2ESS Design Update Programme,
Germany; 3DENEX Detektors for Neutrons GmbH, Germany; 4European
Spallation Source ESS AB, Sweden
N1-110 Liquid Scintillator-Based Neutron Detector Development
A. Lavietes, R. Plenteda, N. Mascarenhas, L. M. Cronholm, International
Atomic Energy Agency, Austria; M. Aspinall, Hybrid Instuments, Inc., United
Kingdom; M. Joyce, Lancaster University, United Kingdom; A. Tomanin, P.
Peerani, Joint Research Center, Itally
Nuclear Physics Instrumentation
N1-111 Study of Timing Properties of SiPMs at Fermilab.
A. I. Ronzhin, S. Los, P. Murat, E. Ramberg, Fermi National Accelerator
Laboratory, USA; H. Kim, C.-T. Chen, C.-M. Kao, University of Chicago,
USA; A. Zatserklianiy, University of Puerto Rico, USA; M. Mazzillo, B.
Carbone, G. Condorelli, G. Fallica, A. Piana, D. Sanfilippo, G. Valvo,
STMicroelectronics, Italy; S. Ritt, Paul Scherrer Institute, Switzerland
N1-112 Retrospective Rn-220 Measurements by Compact Discs
S. B. Georgiev, I. S. Dimitrova, D. S. Pressyanov, K. K. Mitev
Sofia University, Bulgaria
N1-113 Improving Performance of Fast, High Resolution LaBr3
Scintillation Detectors in Presence of Pulse Pile-up Effects
S. Riboldi1,2, S. Brambilla2, C. Boiano2, F. Camera1,2
1
Universita’ degli Studi di Milano, Italy; 2I.N.F.N., Italy
N1-114 Detection of the Cerenkov Light from a TeO2 Crystal
D. Pinci, S. Morganti, F. Orio, M. Vignati, C. Voena, I. Dafinei, INFN
- Sezione di Roma, Italy; F. Bellini, Sapienza Universita’ di Roma, Italy; M.
Marafini, Museo Storico della Fisica e Centro Studi e Ricerche E. Fermi, Italy;
N. Casali, Universita’ degli Studi dell’Aquila, Italy
N1-115 Influence of the Water Temperature on Direct Measurements of
Rn-222 in Water by Liquid Scintillation Counting of Polycarbonates
I. S. Dimitrova, S. B. Georgiev, K. K. Mitev, D. S. Pressyanov
Sofia University, Faculty of Physics, Bulgaria
N1-116 CaLIPSO: Measurements of the Optical and Ionisation
Properties of TriMethylBismuth
P. Verrecchia, E. Ramos, D. Yvon, G. Tauzin, V. Reithinger
CEA Saclay, FRANCE
N1-117 Performance of a Radon Sensor Based on a BJT Detector on
High-Resistivity Silicon
G. Verzellesi, University of Modena and Reggio Emilia, Italy; A. Bosi, RSens
Srl, Italy; G.-F. Dalla Betta, University of Trento, Italy
N1-118 Polarization Measurement of 15 MeV Gamma-Rays with
Segmented HPGe AGATA Detectors
F. C. L. Crespi, D. Paradiso, R. Avigo, A. Bracco, F. Camera, Università di
Milano / INFN Milano, Italy; B. Million, O. Wieland, INFN Milano, Italy
N1-119 Study and Experimentation of a High Resolution Gamma
Camera Based on Thick CsI(Tl) Crystals
P. Busca1,2, C. Fiorini1,2, A. Marone1,2, R. Peloso1,2, F. Camera2,3, N. Blasi2, B.
Million2, O. Wieland2
1
Politecnico di Milano, Italy; 2INFN - Sezione Milano, Italy; 3Universita degli
Studi di Milano, Italy
N1-120 Evaluation of Timing Performances in High Resolution Anger
Camera for Nuclear Physics Research
P. Busca1,2, C. Fiorini1,2, R. Quaglia1,2
1
Politecnico di Milano, Italy; 2INFN - Sezione Milano, Italy
N1-121 Standardization of Ga-68 by Means of a 4π Beta-Gamma
Software Coincidence System
M. F. Koskinas1, F. W. Lacerda1, I. M. Yamazaki1, F. Toledo1, M. N. Takeda2,
M. S. Dias1
1
Instituto de Pesquisas Energegicas e Nucleares IPEN - CNEN/SP, Brazil;
2
Universidade de Santo Amaro, Brazil
N1-122 Solid-State Photomultiplier with Front-End Readout for the
PRIMEX Calorimeter
E. B. Johnson, X. J. Chen, C. J. Stapels, C. Whitney, S. Vogel, Radiation
Monitoring Devices, Inc., USA; D. Lydon, DSL Consulting, USA; F.
Augustine, Augustine Engineering, USA; R. Miskimen, University of
Massachusetts, USA
N1-123 The Melting Latent Heat of Semicrystalline PVDF and P(VDFTrFE) Copolymers as an Efficient Tool for Evaluating High Gamma
Doses
A. S. Medeiros, Universidade Federal de Minas Gerais, Brazil; L. O. de Faria,
Centro de Desenvolvimento da Tecnologia Nuclear, Brazil
N1-124 Design and Initial Performance of an Ultra-Low-Noise
Germanium Spectrometer
C. T. Overman, C. E. Aalseth, R. M. Bonicalzi, J. E. Fast, T. W. Hossbach, J.
L. Orrell, B. A. VanDevender
Pacific Northwest National Laboratory, United States
N1-125 Circuit Design and Component Selection for Passive
Temperature Compensation of Gain in Silicon Photomultiplier and
Similar Devices
J. McKisson, F. Barbosa, Jefferson Lab, USA
96 Monday - NSS Poster Presentations N1-126 Target Mass Measurement and Monitoring of the Daya Bay
Antineutrino Detectors
P. Hinrichs, University of Wisconsin-Madison, USA
On behalf of the Daya Bay Collaboration
N1-127 Development of a New Si(Li) Array for the Spectroscopy of the
Hoyle State
T. Kibedi, M. Ng, A. E. Stuchberry, Australian National University, Australia;
T. Krings, D. Protic, C. Ross, SEMIKON Detector GmbH, Germany
Experimental Reactor Instrumentation and
Measurement
N1-128 Development of a New Multiplying Assembly for Research,
Validation, Evaluation, and Learning
D. L. Chichester, M. T. Kinlaw, Idaho National Laboratory, USA
N1-129 Inverse Radiation Modelling for Plant Characterisation
A. B. Shippen, M. P. Mellor, Createc Ltd., UK; M. J. Joyce, Lancaster
University, UK
N1-130 Numerical Study of the External Flow Effect on the Heat
Transfer in a Radiometric Calorimeter Dedicated to Nuclear Heating
Measurements
C. Reynard-Carette, M. Muraglia, J. Brun, M. Carette, A. Janulyte, Y.
Zerega, J. Andre, Aix-Marseille University, France; A. Lyoussi, G. Bignan, D.
Fourmentel, C. Gonnier, P. Guimbal, J.-Y. Malo, J.-F. Villard, J.-P. Chauvin,
CEA, France
Scintillators and Scintillation Detectors
N1-131 Energy Dependence of Scintillation Decay Times Measured
with Gamma-Rays and Compton Electrons
L. Swiderski, M. Moszynski, P. Sibczynski, M. Szawlowski, T. Szczesniak
N1-132 Temperature Dependence Photoluminescence Properties of
Eu2+ Doped CsCaCl3 and CsCaI3 Scintillators
M. Tyagi, M. Zhuravleva, C. L. Melcher, University of Tennessee, USA
N1-133 Performance Studies of Scintillating Ceramic Samples Exposed
to Ionizing Radiation
G. Dissertori, D. Luckey, F. Nessi-Tedaldi, F. Pauss, R. Wallny
ETH Zurich, Switzerland
N1-134 Development of a Modular Fiberdetector with SiPM-Readout
and Tests with Mono-Crystalline Scintillating Fibers
M. Kube, C. Wendel, C. Schmidt, U. Thoma
University Bonn, Germany
N1-135 Performance Improvement in LaBr3(Ce) Through Co-Doping
with Strontium
K. Yang, P. R. Menge, Saint-Gobain Crystals, USA; V. Ouspenski, SaintGobain Recherche, France
N1-136 Direct Observation of Cracking and Simulation of Stress Fields
During Growth of Halide Scintillators
S. Motakef, P. Becla, S. Swider, K. Becla, M. Overholt, CapeSym, Inc., USA
N1-137 Scintillation Characterizations of Rb2LiGdCl6: Ce3+ Single
Crystals
G. Rooh, Abdul Wali Khan University, Pakistan; H. J. Kim, H. Park,
Kyungpook National University, Korea; S. Kim, Cheongju University, Korea
N1-138 Effects of Li1+ Co-Doping on the Scintillation Properties of
Lu0.8Sc0.2BO3:Ce Crystals
D. Ding, Y. Wu, G. Ren, J. Yang
Shanghai Institute of Ceramics, Chinese Academy of Sciences, China
N1-139 Study of Undoped CeF3 Scintillators at Room and Liquid
Nitrogen Temperature
W. Klamra, The Royal Institute of Technology (KTH), Sweden; P. Sibczyński,
M. Moszyński, National Centre for Nuclear Research, Poland; V. Kozlov,
Lebedev Physical Institute, Russia
N1-140 Storage Characteristics of Mixtures of KCl:Eu2+ Phosphors and
Polyethylene Powder by Irradiation of Fast Neutrons
K. Sakasai, K. Toh, T. Nakamura, K. Takakura, C. Konnno, Y. Iwamoto
Japan Atomic Energy Agency, Japan
N1-141 Investigation of Scintillator Arrays for Gamma-Ray Imaging
Detectors Using Thin-Film Process
S. J. Jeon1, M. S. Kim2, W. Yoo2, K. S. Joo1
1
Myongji University, Korea; 2Advanced Microwave Technology, Korea
N1-142 Temperature Dependence of Ce-Doped Gd3(Al,Ga)5O12
Scintillators on the Light Output
M. Seki1, S. Kurosawa1, A. Suzuki1, A. Yamaji1, Y. Fujimoto1, S. Wakahara1,
Y. Futami1, Y. Yokota1, K. Yubuta1, T. Shishido1, M. Kikuchi1, A.
Yoshikawa1,2
1
Tohoku University, Japan; 2Tohoku University,, Japan
N1-143 Combinatorial Screening of Effective Doping in PbF2 for
Introduce of Scintillation
Z. Zhou, Q. Wei, G. Liu, Q. Liu
Shanghai Institute of Ceramics, Chinese Academy of Sciences, China
N1-144 Development of Plastic Scintillators with Inorganic Powders
Y. Kim, G. Cho, H. Yoo, M. Cho, H. Kim, J. Kim, J. H. Bea, M. S. Kim,
D.-U. Kang, H. Kim
Korea Advanced Institute of Science and Technology, South Korea
N1-145 Evaluation of Optical and Scintillation Properties of K CoDoped Eu:LiSrAlF6 Complex Fluoride Single Crystals for Thermal
Neutron Detector
S. Wakahara1, T. Yanagida2, A. Yamaji1, Y. Yokota1, Y. Fujimoto1, M.
Sugiyama1, N. Kawaguchi1,3, S. Kurosawa1, K. Fukuda3, A. Yoshikawa1,2
1
IMR Tohoku university, Japan; 2NICHe Tohoku university, Japan; 3Tokuyama,
Co. Ltd., Japan
N1-146 Scintillation Properties of Undoped and Ce3+-Doped Strontium
Metaborate Crystals
Y. Fujimoto1, T. Yanagida2, N. Kawaguchi3, K. Fukuda3, D. Totsuka4, K.
Watanabe5, A. Yamazaki5, S. Kurosawa1, A. Yoshikawa1,2
1
IMR, Tohoku University, Japan; 2NICHe, Tohoku University, Japan;
3
TOKUYAMA Corp, Japan; 4NIHON KESSHO KOGAKU CO.,LTD, Japan;
5
Nagoya University, Japan
N1-147 Scintillation Properties of SrWO4 Single Crystal
H. Jiang1, G. Rooh2, H. J. Kim1, H. Park1, S. Kim3, M. K. Moon4, J. H. So1,
U. Fawad1
1
Kyungpook National University, Korea; 2Abdul Wali Khan University, Pakistan;
3
Cheongju University, Korea; 4Korea Atomic Energy Research Institute, Korea
N1-148 Characterization of 4x4ch MPPC Array in Scintillation
Spectrometry
M. Grodzicka, M. Moszyński, T. Szczęśniak, M. Szawłowski, National
Centre for Nuclear Research (NCBJ), Poland; J. Baszak, Hamamatsu Photonics
Deutschland GmbH, Germany
N1-149 Eu Concentration Dependence on Scintillation Properties of Eu
Doped SrI2 Single Crystals Grown
K. Nishimoto1, Y. Yokota1, S. Kurosawa1, Y. Fujimoto1, T. Kojima2, F.
Nitanda2, Y. Furukawa2, A. Yoshikawa1,3
1
tohoku university, Japan; 2Oxide Corp, Japan; 3New Industry Creation
Hatchery Center, Japan
N1-150 Progress of BSO Crystals Development at SIC
W. Xiong, Y. Zhou, H. Yuan, Shanghai Institute of Ceramics, P.R. China
N1-151 Properties of Very Large Volume LaBr3:Ce Detector
A. Giaz1,2, L. Pellegri1,2, S. Riboldi1,2, F. Camera1,2, N. Blasi2, C. Boiano2, A.
Bracco1,2, S. Brambilla2, S. Coelli2, F. C. L. Crespi1,2, M. Csatlos3, J. Gulyas3,
A. Krasznahorkay3, B. Million2, L. Stuhl3, O. Wieland2
1
Università di Milano, Italy; 2INFN sezione di Milano, Italy; 3Institute of
Nuclear Research (ATOMKI), Hungary
N1-152 Calculational Study of Surface Condition of Bar-Type
Scintillator for Energy and Position Measurement
J. Kawarabayashi, H. Hayakawa, H. Tomita, T. Iguchi
98 Monday - NSS Poster Presentations N1-153 Optimization of Eu Concentration in LiSrAlF6 Crystalline
Scintilaltor
S. Suzuki1, A. Yamaji1, Y. Fujimoto1, N. Kawaguchi1,2, K. Watanabe3, A.
Yamazaki3, S. Kurosawa1, S. Wakahara1, Y. Yokota1, A. Yoshikawa1,4
1
IMR Tohoku university, Japan; 2TOKUYAMA Corp, Japan; 3Nagoya
University, Japan; 4NICHe Tohoku university, Japan
N1-154 Scintillation Properties of LaBr:Ce with Varying Dopant
Concentrations for Application in TOF-PET
D. N. ter Weele, D. R. Schaart, P. Dorenbos
Delft University of Technology, the Netherlands
N1-155 An Analytic Expression for the Flux Density of Scintillation
Light at the Photocathode
J. Braverman1,2, K.-P. Ziock1,2, M. Harrison1
1
Oak Ridge National Laboratory, United States; 2University of Tennessee, United
States
N1-156 Detailed Analysis of the Performance of Gamma-Ray Detectors
Consisting of a SDD Coupled to LaBr3(Ce) and CsI(Tl)
D. M. Schlosser, H. Soltau, PNSensor GmbH, Germany; A. Niculae,
PNDetector GmbH, Germany; L. Strueder, MPI Halbleiterlabor, Germany; C.
Fiorini, Politecnico di Milano, Germany
N1-157 Energy Resolution and Gamma/Neutron Discrimination in
Xenon-Doped Liquid Argon
C. G. Wahl, E. P. Bernard, D. N. McKinsey, J. Nikkel, Y. Shin, Yale
University, USA; T. Gozani, Rapiscan Laboratories, USA
N1-158 A New Optical Simulator to Perform Light Collection
Estimation in High Spatial Resolution Gamma Cameras
M. Occhipinti1, P. Busca1,2, C. Fiorini1,2, A. Marone1,2, R. Peloso1,2
1
Politecnico di Milano, Italy; 2INFN - Sezione di Milano, Italy
N1-159 Shape-Controlled Scintillator Single Crystals Grown by MicroPulling-Down Method
Y. Yokota1, A. Yamaji1, Y. Fujimoto1, S. Kurosawa1, N. Kawaguchi1,2, K.
Fukuda2, A. Yoshikawa1,3
1
Institute for Materials Research, Tohoku University, Japan; 2Tokuyama
Corporation, Japan; 3New Industry Creation Hatchery Center (NICHe), Tohoku
University, Japan
N1-160 Crystal Growth and Luminescent Properties of Nd-Doped
Ca3(Nb,Ga)5O12
A. Yoshikawa1,2, S. Kurosawa1, A. Suzuki1, M. Seki1, A. Yamaji1, Y.
Fujimoto1, Y. Yokota1, S. Nagata1, T. Shikama1, V. V. Kochurikhin3
1
IMR, Tohoku University, Japan; 2NICHe, Tohoku University, Japan; 3General
Physics Institute, Russia
N1-161 Characterization of In-Doped CsI Scintillator
A. Gektin, N. Shiran, S. Gridin, D. Zosim, Institute for Scintillation
Materials, Ukraine; A. Belsky, C. Dujardin, Universite Claude Bernard Lyon
1, France
N1-162 Radiation Damage of CsI:Eu Crystals
A. V. Gektin, N. V. Shiran, S. A. Vasyukov, Institute for Scintillation
Materials, Ukraine; A. N. Belsky, Universite Claude Bernard Lyon 1, France
N1-163 Development of Low Noise Scintillator Crystals for InterPlanetary Space Missions
C. C. T. Hansson1, A. Owens1, P. Dorenbos2, F. Quarati2, R. Williams3, D.
Hahn4, T. Toepfer4, L. Parthier5, P. Schotanous6, J. V. D. Biezen1
1
European Space Agency / ESTEC, The Netherlands; 2Technical University of
Delft, The Netherlands; 3Praesepe, The Netherlands; 4Hellma Materials GmbH,
Germany; 5Schott, Germany; 6Scionix, The Netherlands
N1-164 Analysis of Cs2LiYC6:Ce3+ Waveforms as Read Out by Solid
State Photomultipliers
B. S. Budden, A. J. Couture, L. C. Stonehill, A. V. Klimenko, J. R. Terry, J.
O. Perry, Los Alamos National Laboratory, USA
N1-165 Garnet Epitaxial Films Co-doped with Rare Earth and
Diamagnetic Ions for Scintillation Applications
M. Kucera1, M. Nikl2, M. Hanus1, Z. Onderisinova1, J. A. Mares2
1
Charles University, Czech Republic; 2Institute of Physics, AS CR, Czech
Republic
N1-166 Gain Stabilization and Pulse Shape Discrimination in a
Thermally-Variant Environment for a Hand-Held Radiation Monitoring
Device Utilizing Cs2LiYCl6:Ce (CLYC) Scintillator
L. C. Stonehill, N. A. Dallmann, B. S. Budden, J. M. Michel, Los Alamos
National Laboratory, USA; M. J. Baginski, D. J. Best, SCI Technology, a
Sanmina-SCI Company, USA; C. Dathy, J. M. Frank, Saint-Gobain Crystals,
USA; M. McClish, Radiation Monitoring Devices, USA; M. B. Smith, Bubble
Technology Industries, Canada
N1-167 Gamma-Neutron Classification Methods Based on Pulse Shape
Discrimination Using Liquid Scintillator
C. Herman, I. Hau, D. Nakazawa, W. Russ, Canberra Industries Inc., USA
N1-168 Progress on Growth and Scintillation Properties of Alkaline
Earth Halide Scintillators CsBa2I5:Eu and BaBrI:Eu
U. Shirwadkar, R. Hawrami, E. van Loef, J. Glodo, K. Shah
Radiation Monitoring Devices, Inc, USA
N1-169 Progress on Growth and Scintillation Properties of Cs2LiYBr6
R. Hawrami, J. Glodo, U. Shirwadkar, K. S. Shah
N1-170 Scintillation Properties of Eu-Doped Scintillators
S. Kurosawa, Y. Yokota, A. Yoshikawa
N1-171 Study of Timing Resolution of Axially-Oriented Scintillators
Coupled to SiPMs for TOF PET and Other Applications
E. Mazzuca, M. Benetti, G.-F. Dalla Betta, University of Trento, Italy; C.
Piemonte, Fondazione Bruno Kessler, Italy
N1-172 A Study on Radiation Hardness of BGO Crystals
L. Zhang1, R. Mao1, S. Wang2, F. Yang1, R.-Y. Zhu1
1
California Institute of Technology, USA; 2Chinese Academy of Sciences, China
N1-173 Sigmalization: a New Approach to Pulse Discrimination
S. A. Ouedraogo1, A. Glen1, N. Leslie1, N. Jason2, P. Iwona1, S. Steven1, W.
Ron1
1
LLNL, USA; 2ORNL, USA
N1-174 Comparison of BCF-10 and BCF-12 Scintillating Fibers for Use
in a 1-Dimensional Linear Sensor
D. L. Chichester, S. M. Watson, J. T. Johnson, Idaho National Lab., USA
N1-175 Czhocralski Growth and Gamma-Ray Response of
Ce:(Gd,Lu,Y)3(Al,Ga)5O12 Single Crystals
K. Kamada1, P. Prusa2, M. Nikl2, T. Yanagida3, T. Endo1, K. Tsutsumi1, A.
Yoshikawa3
1
Furukawa Co., Ltd., Japan; 2Institute of Physics, AS CR,, Czech Republi;
3
N1-176 Czhocralski Growth of Pr:( Lu,Y)3(Al,Ga)5O12 Single Crystals
and Their Scintillation Properties
K. Kamada, K. Tsutsumi, T. Endo, Furukawa Co., Ltd., Japan; M. Nikl,
Institute of Physics, AS CR,, Czech Republi; T. Yanagida, A. Yoshikawa, Tohoku
University, Japan
N1-177 Growth of Sc Doped RE3Al5O12 (RE=Y, Gd, Lu) Single Crystal
by Micro-Pulling-down Method and Their Scintillation Properties
K. Kamada, Furukawa Co., Ltd., Japan; M. Nikl, Institute of Physics, AS CR,,
Czech Republi; T. Yanagida, A. Yoshikawa, Tohoku University, Japan
N1-178 Structure and Scintillation Properties Eu2+-Activated Calcium
Bromide Iodide.
G. Gundiah, S. E. Derenzo, E. D. Bourret-Courchesne
Radiation Damage Effects
N1-179 Silicon Sensor Alliance: Radiation Detector Development for
the LHC Upgrade
X. Wu1, J. Kalliopuska1, H. Jaakko2, K. Wlodek3, F. Manuel4, B. Maurizio5,
R. Ralf6, S. Eranen1
1
VTT, Finland; 2CERN-PH, Switzerland; 3Acreo AB, Sweden; 4IMB-CNM,
Spain; 5FBK, Italy; 6CiS, Germany
100 Monday - NSS Poster Presentations N1-180 The Study of SPICE Modeling and Raiation Test for Evaluation
of Transient Radiation Effects on the Electronic Devices
O. Seung-Chan, L. Nam-ho, Korea Atomic Energy Research Institute, Repulic
of Korea; L. Heung-ho, Chungnam National University, Repulic of Korea
N1-181 Monitoring Radiation Damage in the ATLAS Pixel Detector
C. Troncon, INFN Milano, Italy
On behalf of the ATLAS collaboration
N1-182 Development of N-in-P Planar Pixel Sensors with Active Edge
for the ATLAS High-Luminosity Tracker Upgrade
A. Bagolini1, M. Bomben2, M. Boscardin1, L. Bosisio3, G. Calderini2,4, J.
Chauveau2, G. Giacomini1, C. La Licata4, A. La Rosa5, G. Marchiori2, N.
Zorzi1
1
Fondazione Bruno Kessler, Italy; 2Laboratoire de Physique Nucleaire et des
Hautes Energies (LPNHE), France; 3INFN Sezione di Trieste and Universita’ di
Trieste, Italy; 4INFN Sezione di Pisa and Universita’ degli Studi di Pisa, Italy;
5
Section de Physique (DPNC), Universite’ de Geneve, Switzerland
N1-183 A Low-Power, Radiation-Resistant ASIC for SDD-Based X-Ray
Spectrometers
S. Li, G. De Geronimo, W. Chen, A. D’Anadragora, J. Fried, Z. Li, D. A.
Pinelli, Brookhaven National Laboratory, U.S.; J. A. Gaskin, B. D. Ramsey,
NASA Marshall Space Flight Center, U.S.
N1-184 Single Event Upset Energy Dependence in a Buck-Converter
Power Supply Design
G. Drake1, P. De Lurgio1, A. Gopalakrishnan2, S. Mahadik2, B. Mellado2, J.
Proudfoot1, A. Senthilkumaran2, R. Stanek1
1
Argonne National Laboratory, USA; 2University of Wisconsin - Madison, USA
N1-185 Radiation Tolerance Survey of a Variety of Silicon
Photomultipliers to High Energy Neutron Irradiations
C. Zorn, F. Barbosa, Y. Qiang, Jefferson Laboratory, USA
Photodetectors and Radiation Imaging
Detectors
N1-187 High Fill Factor P-on-N Silicon Photomultipliers for Blue Light
Detection
M. Mazzillo, S. Abbisso, D. Sanfilippo, G. Valvo, B. Carbone, A. Piana, G.
Fallica, STMicroelectronics, Italy; A. Ronzhin, S. Los, M. G. Albrow, E. J.
Ramberg, Fermilab, USA
N1-188 Evaluation of the X-Ray Imaging Properties of Structured
Aluminum-Oxide Matrices Filled with Different Scintillator Materials
J. Muehlbauer1, K. Semmelroth2, P. Krueger3, J. Schreiber3, N. I. Mukhurov4,
N. Uhlmann1
1
Fraunhofer Institute for Integrated Circuits, Germany; 2Fraunhofer Institute for
Integrated Systems and Device Technology, Germany; 3Fraunhofer Institute for
Nondestructive Testing Dresden branch, Germany; 4Stepanov Institute of Physics,
Belarus
N1-189 Pockels Radiation Detection System
D. Blackie, A. Langley, C. Shenton-Taylor, AWE, UK; A. Lohstroh, Surrey
University, UK
N1-190 Study of Maintaining Stable SSPM-Based Detector Gain by
Active Bias Control
X. Sun, K. A. Lan, Y. Shao
UT MD Anderson Cancer Center, United States
N1-191 4pi FOV Active Collimation Imager
T. Lee, W. Lee, Korea University, Korea
N1-192 Comparison of Timing Properties of MPPCs for TOF-PET
Application
M. Yamazaki, Interdisciplinary Graduate School of Science and Engineering,
Shinshu University, Japan; T. Takeshita, Y. Hasegawa, Shinshu University,
Japan
N1-193 Development of SOI Pixel Sensor for Environmental Radiation
Monitor
Y. Sekiguchi1, Y. Arai2, H. Hamagaki1, T. Gunji1, A. Iwata3, T. Ohmoto3, T.
Imamura3
1
University of Tokyo, Japan; 2KEK, Japan; 3A-R-Tec. Co, Japan
N1-194 First Results of an ASIC Controlled γ-Detector Based on a
SiPM-Array and a Monolithic LYSO
P. Conde, A. J. Gonzalez, L. Hernandez, L. Moliner, A. Orero, M. J.
Rodriguez, A. Ros, F. Sanchez, A. Soriano, L. F. Vidal, J. M. Benlloch
Instituto de Instrumentacion para Imagen Molecular (I3M), Spain
N1-195 In-Pixel S/H APS for High-Speed Readout of Large-Area X-Ray
Image
M. S. Kim, D.-U. Kang, D. H. Lee, J.-H. Bae, G. Cho
Korea Advanced Institute of Science and Technology, Republic of Korea
N1-196 Effects of Various Opening and Corner Shapes and TR Size
on SNR of 3-Tr Active Pixel Sensors for High Performance Digital
Radiography
D.-U. Kang, D. H. Lee, M. S. Kim, J. Kim, H. Yoo, M. Cho, Y. Kim, C.
Kim, H. Kim, J.-H. Bae, H. Kim, G. Cho
KAIST, Republic of Korea
N1-197 Design of SiPM Based Electrical Personal Dosimeter
H. Yoo, M. Cho, J. Kim, H. Kim, H. Kim, G. Cho
N1-198 Comparative Evaluation of PIN Photodiodes with Different
Wafer Resistivity
S.-W. Park, Y. Yi, Korea University, South Korea
N1-199 Stochastic Origin Ensemble Algorithm for Fast and Improved
Image Reconstruction in Compton Imaging
J. H. Park1, H. Seo2, Y. S. Kim1, C. H. Kim1
1
Hanyang University, Korea; 2Korea Atomic Energy Research Institute, Korea
N1-200 Energy Resolution Contributions in Reach-Through APDs
L. M. P. Fernandes, A. L. Gouvea, J. M. F. dos Santos
University of Coimbra, Portugal
N1-201 Expanded Operations at the Y-12 Nuclear Detection and Sensor
Testing Center
C. D. Hull, M. R. Williamson, J. A. Cantrell, J. M. Holland, S. W. Russell
Y-12 National Security Complex, USA
N1-202 High Rate X-Ray Spectroscopy with Silicon Drift Detectors
Coupled with CUBE Frontend Electronics
L. Bombelli1,2, R. Alberti2, C. Fiorini1, T. Frizzi2
1
Politecnico di Milano, Italy; 2XGLab SRL, Italy
N1-203 SiPM Cross-Talk Amplification Due to Scintillator Crystal:
Effects on Timing Performance.
A. Gola, C. Piemonte, A. Tarolli
Fondazione Bruno Kessler, Italy
N1-204 Improvement of Low-Energy Gamma-Ray Imaging Performance
of Semiconductor Compton Camera GREI
S. Motomura1, T. Fukuchi1, T. Ida2, M. Hiromura1, H. Haba1, Y. Watanabe1,
S. Enomoto1,2
1
RIKEN CMIS, Japan; 2Okayama University, Japan
N1-205 Reach-Through APDs for X-Ray Detection
A. L. Gouvea, L. M. P. Fernandes, J. M. F. dos Santos
University of Coimbra, Portugal
N1-206 Development of a Procedure for the Functional
Characterization of Silicon Photomultipliers
C. Piemonte, A. Ferri, A. Gola, T. Pro, N. Serra, A. Tarolli, N. Zorzi
FBK, Italy
N1-207 Efficient Single-Detector Gamma Imaging for Civil Nuclear
Inspection
M. P. Mellor1,2, B. A. Shippen1,2, M. J. Joyce2
1
Createc Ltd, UK; 2Lancaster University, UK
102 Monday - NSS Poster Presentations N1-208 Accurate Dose Determination with P-I-N Diodes for Gamma
Ray Fields
F. J. Ramirez-Jimenez, L. Mondragon-Contreras, J. M. Garcia-Hernandez,
M. A. Torres-Bribiesca
Instituto Nacional de Investigaciones Nucleares, Mexico
N1-209 Characterization of the Hamamatsu R11265 Multi-Anode
Photomultipliers Tube with Single Photon Signals
M. Calvi, A. Giachero, C. Gotti, M. Maino, C. Matteuzzi, G. Pessina
INFN Milano Bicocca, Italy
N1-210 Operation of Large-Area APDs at Cryogenic Temperatures
A. Cardini, A. Lai, INFN Sezione di Cagliari, Italy; A. Lai, Universita’ degli
Studi di Cagliari, Italy
N1-211 Light-Induced Afterpulses in Photomultipliers
M. L. Knoetig1, R. Mirzoyan1, M. Tippmann2, U. Menzel3, J. Hose1, M.
Teshima1
1
Max-Planck-Institute for Physics, Germany; 2Technichal University Munich,
Germany; 3University Konstanz, Germany
N1-212 Evaluation of the Timing Properties of a High Quantum
Efficiency Photomultiplier Tube
Q. Peng, W.-S. Choong, W. Moses
N1-213 Studies of Optical Mixers for Use with Silicon Photomultipliers
to Ameliorate Signal Saturation.
B. W. Baumbaugh, A. Heering, J. Marchant, M. McKenna, R. Ruchti, M.
Vigneault
University of Notre Dame, USA
N1-214 Parametric Study of Digital Silicon Photomultiplier Arrays for
Optimized Timing Performance
J. W. Cates1, J. P. Hayward1,2, X. Zhang1, M. Laubach1
1
University of Tennessee, USA; 2Oak Ridge National Laboratory, USA
N1-215 A Novel Gamma-Ray Imaging System Using a Coded Aperture
Compton Camera
A. M. Farber, J. G. Williams, University of Arizona, USA
N1-216 Performance Comparison of Two Compact Multiplexed
Readouts with SensLs SPMArray4 for High-Resolution Detector Module
Y. Qi1, X. Zhang2, C. Zhao2, L. Chen2, M. Petasecca1, M. Safavi-Naeini1, M.
Lerch1, A. Rosenfeld1
1
University of Wollongong, AUSTRALIA; 2Chinese Academy of Sciences, China
N1-217 Development of Large Area Silica Aerogel Used as RICH
Radiator for the Belle II Experiment
M. Tabata1,2, I. Adachi3, Y. Hatakeyama4, H. Kawai2, T. Morita2, K.
Nishikawa2, T. Sumiyoshi5
1
Japan Aerospace Exploration Agency (JAXA), Japan; 2Chiba University,
Japan; 3High Energy Accelerator Research Organization (KEK), Japan; 4Nihon
University, Japan; 5Tokyo Metropolitan University, Japan
N1-218 The Next Generation Photo Sensor with Multi Arrays of SiPM
Sensors
H. Y. Lee, J. A. Jeon, J. Lee, I. H. Park, Ewha Womans University, Korea; S.
K. Yang, S.-W. Kim, Yonsei University, Korea
N1-219 Software-based Digital Pulse Processing for Silicon
Photomultiplier Radiation Detectors
R. M. Preston1,2, R. Bencardino3, J. E. Eberhardt1, J. R. Tickner1
1
Commonwealth Scientific and Industrial Research Organisation, Australia;
2
University of Wollongong, Australia; 3European Commission, Luxembourg
N1-220 Utilizing Experimentally Benchmarked Electron-Tracking
Compton Imaging Simulations to Guide the Design of Future Imagers
A. B. Coffer1, B. Plimley1, K. Vetter1,2
1
University of California - Berkeley, USA; 2Lawrence Berkeley National
Laboratory, USA
N1-221 Impact of CCD Pixel Pitch and Noise on Electron Track
Compton Imaging
B. C. Plimley1, A. Coffer1, D. Chivers2, K. Vetter1,2
1
UC Berkeley, USA; 2Lawrence Berkeley National Laboratory, USA
N1-222 Development of an Optical Module for the Next-Generation
Neutrino Detector LENA and Studies on Fast Afterpulsing in PMTs
M. Tippmann, Technische Universitaet Muenchen, Germany
On behalf of the LENA project
N1-223 Relation Between Photo-Cathode QE and Sb Film Properties
for Development of High Performance Bi-Alkali Photo-Cathodes
J. Xie, Argonne National Laboratory, US
On behalf of the LAPPD
N1-224 Development and Evaluation of Large Area CMOS Sensor for
Dynamic X-Ray Imaging
S. Jeon1, M.-S. Shin2, C. Kim1, B. K. Cha1, C. Seo1
1
Korea Electrotechnology Research Institute, Korea; 2Hanyang University, Korea
Synchrotron Radiation and FEL
Instrumentation
N1-225 Physics and Electronics Simulations of the Large Pixel Detector
at EuXFEL
A. Joy1, M. French2, P. Seller2, M. Wing1
1
University College London, United Kingdom; 2Rutherford Appleton Laboratory,
United Kingdom
N1-226 Characterization of Medipix3RX with Synchrotron Radiation
E. N. Gimenez1, N. Tartoni1, M. Campbell2, R. Ballabriga2, X. Llopart2, G.
Blaj2, J. Marchal1, K. J. S. Sawhney1
1
Diamond Light Source, UK; 2CERN, Switzerland
N1-227 Progress of FD-SOI Technology for X-Ray Pixel Detectors
M. Okihara1, H. Kasai2, N. Miura2, N. Kuriyama2, Y. Nagatomo1, T.
Hatsui3, M. Omodani3, T. Miyoshi4, Y. Arai4
1
LAPIS Semiconductor Co., Ltd., Japan; 2LAPIS Semiconductor Miyagi Co.,
Ltd., Japan; 3Harima Institute RIKEN Spring-8 Center, Japan; 4High Energy
Accelerator Research Organization, Japan
N1-228 Calibration of DEPFETs with Internal Signal Compression
S. Aschauer1, P. Lechner1, M. Porro2, C. Sandow1, G. Weidenspointner2
1
PNSensor GmbH, Germany; 2Max-Plank Institute fuer extraterrestrische
Physik, Germany
N1-229 Numerical Simulation for the Space Charge Effect on the MultiChannel Ionization Chamber Time Response Signal
A. K. O. Nasr, W. Schenk, A. H. Walenta, Siegen University, Germany
N1-230 Calibration of the Non-Linear System Gain of a Prototype Setup of the DSSC Detector for the European XFEL
G. Weidenspointner1,2, R. Andritschke1,2, D. Moch1,2, M. Porro1,2, S.
Schlee1,2, L. Strueder1,2, S. Aschauer3, P. Lechner3, G. Lutz3, C. Sandow3, F.
Erdinger4, P. Fischer4, M. Kirchgessner4, J. Soldat4, K. Hansen5
1
MPI Halbleiterlabor, Germany; 2Max-Planck-Institut fuer extraterrestrische
Physik, Germany; 3PNSensor, Germany; 4Heidelberg University, Germany;
5
Deutsches Elektronen-Synchrotron, Germany
N1-231 The APA Pixel Readout ASIC for an APD Based Fast 2D X-Ray
Hybrid Pixel Detector
C. Thil1, A. Q. R. Baron2, P. Fajardo3, P. Fischer1, H. Graafsma4
1
Heidelberg University, Germany; 2RIKEN, Japan; 3European Synchrotron
Radiation Facility, France; 4Deutsches Elektronen-Synchrotron, Germany
N1-232 Status of the Detector Development Activities for the European
XFEL
M. Kuster, A. Koch, J. Sztuk-Dambietz, M. Turcato
European XFEL GmbH, Germany
N1-233 Variable Beam Attenuators for Synchrotron Beamlines
J. Hasi, C. J. Kenney, SLAC National Accelerator Laboratory, USA; A. C.
Thompson, E. Westbrook, Molecular Biology Consortium, USA; S. I. Parker,
University of Hawaii, USA; C. Da Via, University of Manchester, UK
N1-234 High-Speed CMOS Detector for Time-Resolved Synchrotron
Applications
B. Singh1, S. R. Miller1, H. B. Bhandari1, T. C. Irving2, V. V. Nagarkar1
1
Radiation Monitoring Devices, Inc., USA; 2Illinois Institute of Technology, USA
104 Monday - NSS Poster Presentations N1-235 Charge Pump Detector: Optimization with Process and Device
Simulation
J. Segal, C. Kenney, SLAC, USA
N1-236 High-Z Radiation Shields for X-Ray Free Electron Laser
Detectors
A. Tomada, L. Manger, J. Tice, C. Kenney, B. Duda
SLAC National Accelerator Laboratory, USA
N1-237 Characterization of the eLine ASICs in Prototype Detector
Systems for LCLS
G. A. Carini1, A. Dragone1, B.-L. Berube’2, P. Caragiulo1, D. M. Fritz1, P.
A. Hart1, R. Herbst1, S. Herrmann1, C. J. Kenney1, A. J. Kuczewski3, H. T.
Lemke1, J. Mead3, J. Morse4, J. Pines1, A. Robert1, D. P. Siddons3, D. Zhu1,
G. Haller1
1
SLAC National Accelerator Laboratory, USA; 2Universite’ de Sherbrooke,
Canada; 3Brookhaven National Laboratory, USA; 4European Synchrotron
Radiation Facility, France
N1-238 CSpad-140k Experimental Applications at LCLS
S. Herrmann, S. Boutet, G. Carini, A. Dragone, D. Freytag, G. Haller, P.
Hart, R. Herbst, C. Kenney, J. Pines, G. Williams
N1-239 Beamstrahlung Radiation for Beam-Beam Instability
R. Ayad1, J. H. Madani1, G. Bonvicini2, C. Boulahouache1, A. Ahmad1
1
University Of Tabuk, Saudi aarabia; 2Wayne State University, USA
Monday - RTSD Poster
Presentations
R04-11 Tests of a Prototype Nuclear-Medical Imaging System Based on
R04 RTSD Poster 1
Monday, Oct. 29 Session Chair: 16:30-18:30 Grand Ballroom North
Jan Franc, Institute of Physics, Charles University, Czech
Republic
R04-1 Direction-Sensitive Hand-Held Gamma-Ray Spectrometer
S. Mukhopadhyay
National Security Technologies Inc., LLC, USA
R04-2 Design of a Low Noise Readout ASIC for CdZnTe Detector
J. Luo1,2, Z. Deng1,2, G. Q. Wang3, C. R. Cheng3, Y. N. Liu1,2
1
(Tsinghua University), China; 3Beijing Hamamatsu Photon Techniques Co.Ltd.,
China
R04-3 Simulation Study on Stacked Coplanar Grid (Cd,Zn)Te Sensors
for Radiation Surveillance
J. P. Balbuena1, U. Parzefall2, M. Fiederle3, M. Dambacher3, C. Disch1, A.
Fauler3, A. Zwerger1
1
Freiburger Materialforschungszentrum, Albert-Ludwigs-Universitat, Germany;
2
Physikalisches Institut, Albert-Ludwigs-Universitat, Germany; 3X-ray Imaging
Europe (XIE), Germany
R04-4 Temperature-Dependent Measurements of Time-of-Flight Current
Waveforms in Schottky CdTe Detectors
K. Suzuki, T. Sawada, Hokkaido Institute of Technology, Japan; S. Seto,
Ishikawa National College of Technology, Japan
R04-5 Investigation of Temporal Response of CdZnTe Detectors by
Using the High-Flux Pulsed X-Rays
Y. Xu, Y. He, C. Wang, L. Xu, T. Wang, G. Zha, W. Jie
Northwestern Polytechnical University, P. R. China
R04-6 A Study of a Fine Pitched Pixelated CdZnTe Detector with a
Digital Waveform Acquisition System.
J. Miyamoto, T. Kutter, Lousiana State University, USA
R04-7 Advancement in the BNL H3Dv4 ASIC Readout System for 3-D
Position Sensitive CdZnTe Detectors
F. Zhang, Z. He, The University of Michigan, USA; G. De Geronimo, E.
Vernon, J. Fried, Brookhaven National Laboratory, USA
R04-8 Low-temperature Photoluminescence Investigation of CdTe,
CdZnTe and CdMnTe Detector-grade Crystals
G. Yang, A. E. Bolotnikov, Y. Cui, G. S. Camarda, A. Hossain, K. H.
Kim, R. B. James, Brookhaven National Laboratory, USA; J. Franc, Charles
University Prague, Czech Republic; V. Babentsov, Institute of Semiconductor
Physics, Ukraine
R04-9 Complementary Characterization of High Z Semiconductor
Medipix Detectors by Using Synchrotron Radiation
E. Hamann1, A. Cecilia1, D. Haenschke2, F. Xu1, A. Fauler3, T. Baumbach1,2,
M. Fiederle1,3
1
Karlsruhe Institute of Technology (KIT) ISS/ANKA, Germany; 2Laboratory
for Applications of Synchrotron Radiation (LAS), Germany; 3Freiburger
Materialforschungszenturm FMF, Germany
R04-10 Imaging with the Medipix Scanner MARS at KIT
J. Butzer1, E. Hamann1, V. Altapova2, F. Chen1, A. Cecilia1, F. Kuchling1, B.
Trimborn1, A. Butler3, P. Butler3, M. Fiederle4, T. Baumbach1,2
1
ANKA/Institute for Synchrotron Radiation, Karlsruhe Institute of Technology,
Germany; 2Laboratory for Application of Synchrotron Radiation, Karlsruhe
Institute of Technology, Germany; 3MARS Bioimaging Ltd, New Zealand;
4
Freiburger Materialforschungszentrum, Albert-Ludwigs-Universitt Freiburg,
Germany
106 Monday - RTSD Poster Presentations CZT Detectors and an Interwoven Collimator
Y. Cui1, T. Lall2, G. S. Camarda1, A. Hossain1, K.-H. Kim1, G. Yang1, R. B.
James1
1
Brookhaven National Laboratory, USA; 2Gamma Medical Technologies,
Canada
R04-12 Spectroscopic Detectors in CT-Reconstruction
M. P. Pichotka1, G. Blaj2, S. Procz1, J. Luebke1, M. Campbell2, M. Fiederle1
1
Freiburger Materialforschungszentrum FMF, Germany; 2CERN, CH
R04-13 Study of the Polarization Process in TlBr Gamma-Ray Detectors
C. L. Thrall, W. R. Kaye, Z. He, Univeristy of Michigan, USA; H. Kim, L.
Cirignano, K. Shah, Radiation Monitoring Devices, Inc., USA
R04-14 Impact of Operating Temperature on Pixelated CdZnTe
Detector Systems
J. D. Mann, Z. He, University of Michigan, U.S.A.
R04-15 Identification and Reconstruction of Side-Neighbor Charge
Leak Events on 3-D Semiconductor Detectors Using Digital ASIC
H. Yang, Z. He, University of Michigan, 48105
R04-16 Hybrid (Cd,Zn)Te / Scintillator Gamma Ray Detectors for
Spectroscopic Dose Rate Measurements
L. J. Harkness, L. Hudson, C. H. Duff, I. Radley, Kromek, U.K.
R04-18 Time-Dependent Compton Image Reconstruction of Moving
Sources
J. M. Jaworski, J. A. Fessler, Z. He
R04-19 Analysis of Stressed TlBr Gamma Spectrometers
A. M. Conway, L. F. Voss, P. R. Beck, A. J. Nelson, R. T. Graff, R. J. Nikolic,
S. A. Payne, Lawrence Livermore National Laboratory, USA; H. Kim, L.
Cirignano, K. Shah, Radiation Monitoring Devices, Inc, USA
R04-20 Impact of Sub-Pixel Position Information on Compton Image
Reconstruction
W. Wang, Y. Zhu, Z. He, University of Michigan, USA
R04-21 Characterization of the Structural and Electronic Properties of
Ga2(Se0.33Te0.67)3
N. M. Abdul-Jabbar1,2, E. D. Bourret-Courchesne2, B. D. Wirth3
1
University of California, USA; 2Lawrence Berkeley National Laboratory, USA;
3
University of Tennessee, USA
R04-22 A New Four-Side Abuttable Photon-Counting Readout ASIC for
X-Ray Imaging Applications
M. Clajus, S. Snyder, D. Castruita, L. He, R. Stinnett, T. Tumer, A.
Volkovskii, F. Walker
NOVA R&D, Inc., USA
R04-23 Performance of 2-keV Digitizer ASIC: VAD_UM V1.2, for 3-D
Position-Sensitive Pixellated Semiconductor Detectors
Y. Zhu, Z. He, University of Michigan, USA; S. Mikkelsen, T. M. Johansen,
GAMMA MEDICA-IDEAS, Norway
R04-24 Proton Radiography Studies with a Hand Phantom Using a
Prototype Proton CT Scanner
A. S. Plumb, V. Feng, R. Johnson, J. Lustig-Yeager, S. Macafee, T. Plautz, H.
Sadrozinski, D. Steinberg, A. Zatserklyaniy, Santa Cruz Institute for Particle
Physics, USA; V. Bashkirov, F. Hurley, R. Schulte, Loma Linda University
Medical Center, USA
R04-25 Multi-Elemental Segregation Analysis of Thallium Bromide
Impurities Purified by the Repeated Bridgman Technique
R. A. Santos1, R. F. Gennari2, J. F. T. Martins1, M. M. Hamada1, C. H.
Mesquita1
1
Instituto de Pesquisas Energeticas e Nucleares - IPEN/CNEN-SP, Brasil;
2
Instituto de Fsica - USP, Brasil
R04-26 Study of Surface Passivation and Contact Deposition Techniques
in CdZnTe X-Ray and Gamma-Ray Detectors
S. U. Egarievwe, D. Jones, I. O. Okwechime, S. O. Babalola, M. L. Drabo,
Alabama A&M University, U.S.A.; A. Hossain, G. S. Camarda, A. E.
Bolotnikov, R. B. James, Brookhaven National Laboratory, U.S.A.
Monday - RTSD Poster Presentations 107
R04-27 Dislocation and Defect Structure Around Micro-Indentations
and Te Precipitates in CZT
V. Babentsov, F. Sizov, Institute of Semiconductor Physics, Ukraine; J. Franc,
Charles University, Czech Republic; P. Fochuk, Chernivtsi National University,
Ukraine; G. Yang, A. Bolotnikov, R. B. James, Brookhaven National
Laboratory, USA
R04-28 Characterization of Thallium Bromide Crystals Purified by the
Filter Method
T. Onodera1, K. Hitomi2, T. Shoji1
1
Tohoku Institute of technology, Japan; 2Tohoku University, Japan
R04-29 Charge Carriers Low-Field Mobility Dependence on
Temperature of an All-Carbon Based Detector
G. Conte1,2, M. Girolami2, G. Mini3, C. Tintori3, A. Galbiati4, A.
Bolshakov5, V. G. Ralchenko5, V. Konov5, M. Komelonko5
1
University Roma Tre, Italy; 2CNR-IFN, Italy; 3CAEN SpA, Italy; 4SolarisPhotonics, U.K.; 5Russian Academy of Sciences, Russia
R04-30 Grain Growth and Characteristics of Chlorine Doped Thick
Polycrystalline CdZnTe Films
A. Yoshimatsu, T. Yoshimuta, S. Tokuda, H. Kishihara, M. Kaino, T. Doki,
T. Sato, Technology Research Laboratory, Shimadzu Corporation, Japan; T.
Okamoto, Kisarazu National College of Technology, Japan
R04-31 Numerical Simulations of Uranium-Loaded Microstructured
Silicon Thermal Neutron Detectors
C. A. Kruschwitz, NSTec, LLC., Los Alamos Operations, USA
R04-32 Charge Amplification in CdZnTe Schottky Barrier Diode
Detectors at Alpha-Particles Registration
V. Ivanov, A. Loutchanski1, P. Dorogov, ZRF RITEC SIA, Latvia; M.
Shorohov, Baltic Scientific Instriments Ltd., Latvia
R04-33 Surface Treatment Effects of CdZnTe Crystal Grown by LPB
Method at KAERI
H. S. Kim, J. H. Ha, Y. S. Kim, Korea Atomic Energy Research Institute,
Republic of Korea; H. J. Choi, Sungkyunkwan Univ., Republic of Korea
R04-34 Performance Characteristics of CsI(Tl)/PIN Photodiode
Radiation Detectors with Respect to the Active Area of the Fabricated
PIN Photodiode
H. S. Kim, J. H. Ha, Y. S. Kim, Korea Atomic Energy Research Institute,
Republic of Korea; H. J. Choi, Sungkyunkwan Univ., Republic of Korea
R04-35 Microstructural Characterization of CdZnTe(CZT)crystal Ingot
Grown by Low Pressure Bridgman Method at KAERI
H. J. Choi, H. S. Kim, J. H. Ha, K. H. Lee
Korea Atomic Energy Research Institute, Republic of Korea
R04-36 Influence of Crystal Growth Technology on CZT Radiation
Detectors
Q. Zheng1, J. Crocco1, P. Wellmann2, A. Osvet2, U. Kunecke2, F. Dierre1, H.
Bensalah1, A. Black1, O. Vela3, J. M. Perez3, E. Dieguez1
1
Universidad Autonoma de Madrid, Spain; 2University of Erlangen-Nuremberg,
Germany; 3CIEMAT, Spain
R04-37 The X- Ray Spectrometer Onboard ChangE-2 Lunar Orbiter and
Its Primary Results
H. Wang, W. Peng, X. Cui, X. Liang, C. Zhang
Institute of high energy physics of Chinese Academy of sciences, China
R04-38 Through Silicon Via Redistribution of I/O Pads for 4-Side ButtAble Imaging Detectors.
P. Seller, S. J. Bell, A. A. Schneider, M. C. Veale, M. D. Wilson
Rutherford Appleton Laboratory, UK
R04-39 Coincidence Measurements with Stacked (Cd,Zn)Te Coplanar
Grid Detectors
C. Disch1, A. Zwerger1, A. Fauler1, M. Dambacher1, W. Eickhoff2, U.
Stoehlker3, M. Fiederle1
1
Freiburger Materialforschungszentrum, Germany; 2Bundesamt fuer
Strahlenschutz, Germany; 3CTBTO, Austria
108 Monday - RTSD Poster Presentations R04-40 Low Energy Characterization of CdTe Caliste HD Module at
SOLEX Facility
S. Dubos1, O. Limousin1, C. Blondel1, B. Cordier1, P. Ferrando1, W. Marty2,
Y. Menesguen1, A. Meuris1, T. Orduna1, T. Tourrette1, A. Sauvageon1, S.
Schanne1
1
CEA Saclay, France; 2IRAP, France
R04-41 Room-Temperature Solid-State Radiation Detectors Based on
Spintronics
N. Gary, S. Teng, A. Tiwari, H. Yang, The University of Utah, USA
R04-42 TCAD Simulations of Charge Induction in Small Pixel Cd(Zn)
Te X-Ray Detectors
S. J. Bell1,2, P. Seller1, M. C. Veale1, M. D. Wilson1, A. Schneider1, P. J.
Sellin2, M. A. Baker2
1
Rutherford Appleton Laboratory, UK; 2University of Surrey, UK
R04-43 High Energy Resolution CdTe Schottky Diode γ-Ray Detectors
L. Kosyachenko1, T. Aoki2,3, C. Lambropoulos4, V. Gnatyuk2,5, V.
Sklyarchuk1, O. Maslyanchuk1, E. Grushko1, O. Sklyarchuk1, A. Koike3
1
Chernivtsi National University, Ukraine; 2Shizuoka University, Japan;
3
Incubation Center, Japan; 4Technological Educational Institute of Chalkida,
Greece; 5V.E. Lashkaryov Institute of Semiconductor Physics, Ukraine
R04-44 Software for Inclusions Recognition and Analisys
P. Fochuk, L. Dyachenko, S. Ostapov, O. Kopach, Chernivtsi National
University, Ukraine; A. E. Bolotnikov, R. B. James, Brookhaven National
Laboratory, USA
R04-45 Effect of Growth Conditions on the Properties of (Cd,Mn)Te
D. M. Kochanowska, A. Mycielski, M. Witkowska-Baran, B. Witkowska, W.
Kaliszek, A. Szadkowski, R. Jakieła, A. Reszka, B. Kowalski, A. Suchocki, P.
Nowakowski, A. Kamińska
Institute of Physics Polish Academy of Sciences, Poland
R04-46 Materials and Photosensor Devices with High Radiation
Stability
I. Rarenko, P. Fochuk, V. Koshkin, V. Sklyarchuk, O. Panchuk, L.
Kosyachenko, S. Dremlyuzhenko
Chernivtsi National University, Ukraine
R04-47 Effect of Contact Preparation on the Electric Field Profile in
CdTe and CdZnTe Detectors
S. Uxa, E. Belas, R. Grill, P. Praus
Institute of Physics, Charles University, Czech Republic
R04-48 Pixel-Binning Effects on the Response Performance of X-Ray
Photon-Counting Pixel Detectors
H. Youn1, J. P. Marchal2, H. K. Kim1, S. Yun1,3, J. Tanguay3, I. A.
Cunningham3
1
Pusan National University, South Korea; 2Harwell Science and Innovation
Campus, U.K.; 3Robarts Research Institute, Canada
R04-49 Electrical Investigation of Semiconductor Pixel Detectors using
Finite-Element Methods
H. R. Park, H. Youn, J. C. Han, O. Joe, H. K. Kim
Pusan National University, South Korea
R04-50 Amorphous Electrical Contacts to (Cd,Mn)Te Crystal Platelets:
Effect of the Crystal Surface Preparation on the Quality of the Contacts
M. Witkowska-Baran, A. Mycielski, D. M. Kochanowska, A. Szadkowski, A.
Reszka, R. Jakieła, E. Łusakowska, W. Kaliszek, B. Witkowska, B. Kowalski
Institute of Physics Polish Academy of Sciences, Poland
R04-51 α-HgI2 Crystal Growth and Characterization for New
Semiconductor Radiation Detector
S. Yeo, J. Ha, H. S. Kim, Y. S. Kim
Korea Atomic Energy Research Institute, Korea (ROK)
R04-52 Concept for a Nanometer-Resolution X-Ray Computed
Tomography System for Non-Destructive Testing Based on Room
Temperature Semiconductor Detector Modules
M. Habl1, M. Firsching1, F. Nachtrab1,2, T. Hofmann1, N. Uhlmann1
1
Development Center X-Ray Technology EZRT, Fraunhofer Institute for
Integrated Circuits IIS, Germany; 2Engineering of Advanced Materials,
Friedrich-Alexander-Universitaet Erlangen-Nuernberg, Germany
R04-53 Portable High Resolution Coplanar Grid (Cd,Zn)Te Gamma
Ray Detection System for Radiation Surveillance
M. Dambacher1, A. Zwerger1,2, A. Fauler1,2, C. Disch2, M. Fiederle1,2
1
X-ray Imaging Europe, Germany; 2Freiburger Materialforschungszentrum,
Germany
R04-54 Adjacent 2-Pixel Event Discrimination in 3-D Position Sensitive
Imaging CdZnTe Detectors
C. R. Brown, Y. Zhu, H. Yang, Z. He,
R04-55 Fabrication and Characterization of segmented CdTe Detectors
intended for imaging X-Rays on-board Solar Orbiter
M. Bednarzik, R. Resanovic, Paul Scherrer Institut, Switzerland; O. Grimm,
V. Commichau, ETH Zurich, Switzerland; O. Limousin, A. Meuris, CEA
Saclay, France; G. Hurford, A. Benz, S. Krucker, University of Applied Sciences
for Northwestern Switzerland, Switzerland
R04-56 Improvement of the Quality of CdZnTe Detectors after Laser
Irradiation
H. Bensalah1, A. Medvids2, J. Crocco1, A. Michko2, E. Dauksta2, V. Ivanov2,
Q. Zheng1, J. L. Plaza1, E. Dieguez1
1
Universidad Autonoma de Madrid, Spain; 2Riga Technical University, Latvia
R04-57 A Small 3D CZT Payload for Hard X Ray Polarimetry and
Spectroscopic Imaging
E. Caroli1, J. M. Alvarez Pastor2, N. Auricchio1, C. Budtz-Jrgensen3, R. M.
Curado da Silva4, S. Del Sordo5, P. Ferrando6, P. Laurent6, O. Limousin6, J.
L. Galvez2, C. P. Gloster4, M. Hernanz2, J. Isern2, I. Kuvvetli3, J. M. Maia4,
A. Meuris6, N. Produit7, J. B. Stephen1, A. Zappettini8
1
INAF/IASF-Bologna, Italy; 2CSIC-IEEC, Universitat Autonoma de Barcelona,
Spain; 3DTU Space, Technical University of Denmark, Denmark; 4LIP,
University of Coimbra, Portugal; 5INAF/IASF-Palermo, Italy; 6SAP/CEA Saclay,
France; 7ISDC, Data Centre for Astrophysics, Switzerland; 8IMEM/CNR, Italy
R04-58 An Integrated Low-Noise Wide-Bandwidth Charge-Sensitive
Microprobe for Semiconductor Detectors
A. Pullia1,2, E. Frontini1
1
R04-59 Dynamics of Charge Collection in Pixelated Semiconductor
Sensor Studied with Heavy Ions and Timepix
P. Soukup1, J. Jakubek1, M. Martisikova2,3, M. Kroupa1, S. Pospisil1
1
Institute of Experimental and Applied Physics, Czech Technical University in
Prague, Czech Republic; 2Heidelberg University Hospital, germany; 3German
Cancer Research Center - DKFZ, Germany
R04-60 Study of the Effects of Stress on CdTe Nuclear Detectors
M. Ayoub1, J. N. E. McGrath1, M. Hage-Ali2, I. Radley1
1
Kromek, U.K.; 2CLEA-CNRSL, Lebanon
R04-61 Ionizing Radiation Detection via CdTe Nanowires Assembled
Using Vacuum Filtration
M. F. Becchetti, M. D. Hammig, G. Kim, J. Il Park, N. A. Kotov
University of Michigan, United States
R04-62 Non-Uniformities Observed in TlBr- and Scintillator- Materials
G. S. Camarda, A. E. Bolotnikov, Y. Cui, A. Hossain, K. Kim, G. Yangs, R.
B. James
Brookhaven National Lab, USA
R04-63 Suppression of Interface-Induced Noise by the Control of
Electron-Phonon Interactions
M. D. Hammig, M. Jeong, I. Kwon
R04-64 A Gamma-Ray Detection System Using Pixelated CdZnTe
Detectors and GASSIPLEX Readout Electronics
Y. Yin, X. Chen, H. Wu, L. Yang, D. Xu
School of Nuclear Science and Technology, Lanzhou University, China
R04-65 Numerical Simulation of TEES Glow Curve in CdTe Radiation
Detectors
H. Elhadidy1, J. Franc2, R. Grill2, O. Sik1, J. Sikula1
1
Brno University of Technology, Czech Republic; 2Charles University, Czech
Republic
110 Monday - RTSD Poster Presentations R04-66 Influence of Crystallization and Doping in the
Thermoluminescence Response of Lead Borate Glass Ceramics
L. Fornaro, M. Rodriguez, A. Cardenas, E. Castiglioni, J. Castiglioni
Universidad de la Republica, Uruguay
R04-67 A Dual-Mode Readout System for a CdTe Based MRCompatible Ultrahigh Resolution SPECT/PET System
J. C. Zhang1,2, Z.-M. Shen1, F.-K. Tang3, L.-J. Meng1
1
Univeristy of Illinois at Urbana-Champaign, U.S.A.; 2Institute of Mordern
Physics, Chinese Academy of Sciences, China; 3Univeristy of Chicago, U.S.A.
R04-68 Feasibility Study of Hybrid Structure for Ecofriendly Radiation
Detector
J. N. Kim1, J. W. Shin1, Y. K. Lee1, Y. J. Lee1, S. J. Noh1, S. H. Cho2, S. H.
Nam1
1
Inje University, Republic of Korea; 2Ehwa Womans University, Republic of
Korea
R04-69 The Applicability Evaluations of X-Ray Conversion Material for
the Quality Assurance of the Radiation Therapy Apparatus.
S. Noh1, S. Kim1, Y. Song1, J. Kim2, S. Heo1, S. Park3, S. Nam1,4
1
Department of Biomedical Engineering,Inje university, South Korea;
2
Department of Medical Image Science, Inje University, South Korea; 3Radiation
oncology, Busan paik hospital, South Korea; 4Medical Imaging Research Center,
Inje University, South Korea
R04-70 Study of Deep Levels in High Resistivity CdTe and CdZnTe by
Charge and Discharge Current Measurement
V. Dědič1, J. Franc1, H. Elhadidy2, R. Grill1, E. Belas1, P. Moravec1, P.
Hoschl1
1
Charles University, Faculty of Mathematics and Physics, Czech Republic; 2Brno
University of Technology, Faculty of Electrical engineering, Czech Republic
R04-71 Growth, Fabrication and Testing of Bismuth Tri-Iodide (BiI3)
Semiconductor Radiation Detectors
J. E. Baciak, S. S. Gokhale, H. Han, K. Jordan, J. C. Nino
University of Florida, USA
Notes
112 Monday - RTSD Poster Presentations Notes
Notes
114 Monday - RTSD Poster Presentations Notes
07:00
07:30
R05: Applications 1
LC5: ILC/CLIC Accelerator
Technologies for Industrial
Applications I
JNM: NSS/MIC Joint Session
LC6: ILC/CLIC Accelerator
Technologies for Industrial
Applications II /
Forum Discussion
JNMR: NSS/MIC/RTSD Triple
Joint Session
10:00
LC4: ILC/CLIC Detector
Spin-offs and ILC/CLIC
Accelerator Instrumentation
N11: Instr. for Homeland
Security III: Active Interrogation
09:30
LC3: ILC/CLIC Detector Concepts and Summary of Detector
Spin-Offs
Homeland Security II: Imaging
09:00
N5: Neutron Detectors and
Instrumentation I
N9: Analog and Digital Circuits
III
08:30
N6: Analog and Digital
Circuits II
N10: Scintillators and
Scintillation Detectors I
JMR: MIC/RTSD Joint
Session
N7: Simulation
08:00
Tuesday, 30 October
Grand Ballroom
Center
Grand Ballroom
South
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
Grand Ballroom
North
Exhibit Hall
North
Exhibit Hall South
Monorail A+B
Rainforest Café,
Downtown Disney
10:30
11:00
11:30
12:00
12:30
13:00
13:30
NSS Refresher
Course 1
14:00
RTSD Luncheon
14:30
15:00
15:30
N12: Astrophysics and Space
Instrumentation I
N13: Gaseous Detectors I :
Performance Reports
R06: RTSD Poster 2
16:00
Industrial Exhibition
Exhibitor Tech. Sessions
16:30
17:00
17:30
18:00
N14: NSS Poster Session II
18:30
19:00
19:30
Exhibitor
Reception
116 116
Tuesday - NSS Oral Presentations
N5 Neutron Detectors and Instrumentation I
Tuesday, Oct. 30 08:00-10:00 Magic Kingdom Ballroom 1
Session Chairs: John Valentine, SAIC, USA
Nolan Hertel, Georgia Institute of Technology, USA
N5-1 (08:00) Novel Boron-Based Silicon Neutron Detectors for High
Gamma-Ray Rejection
C. Fleta, C. Guardiola, M. Lozano, G. Pellegrini, D. Quirion, J. Rodriguez,
Instituto de Microelectronica de Barcelona, IMB-CNM (CSIC), Spain; F.
Garcia, Helsinki Institute of Physics, University of Helsinki, Finland
N5-2 (08:15) Application of Time Projection Chambers with GEMs and
Pixels to Directional Fast Neutron Spectroscopy
S. E. Vahsen, M. T. Hedges, M. D. Rosen, S. J. Ross, I. S. Seong, T. N.
Thorpe, J. Yamaoka, University of Hawaii, USA; M. Garcia-Sciveres, J. A.
Kadyk, K. Olives-Mallory, Lawrence Berkeley National Laboratory, USA
N5-3 (08:30) Neutron and Gamma Ray Response of a Modular Li Foil
Multi-Wire Proportional Counter
K. A. Nelson, S. L. Bellinger, D. Francia, A. J. Schmidt, C. Wayant, D. S.
McGregor, Kansas State University, USA
N5-4 (08:45) Investigation of Three-Dimensional Localisation of
Neutron Sources Using Parallel Axis Imaging
K. A. Akurugoda Gamage, M. J. Joyce
Lancaster University, United Kingdom
N5-5 (09:00) Characterization of Neutron Scintillation Detector and
Li-Ion Battery Anodes Using Neutron Depth Profiling
P. L. Mulligan, L. R. Cao, A. Co, M. Canova
The Ohio State University, USA
N5-6 (09:15) Assaying Used Nuclear Fuel Assemblies Using Lead
Slowing-down Spectroscopy
G. A. Warren, K. K. Anderson, A. M. Casella, C. J. Gesh, J. A. Kulisek
N5-7 (09:30) Spatially Resolved Remote Measurement of Temperature
by Neutron Resonance Absorption
A. S. Tremsin, J. B. McPhate, J. V. Vallerga, O. H. W. Siegmund, University
of California at Berkeley, USA; W. Kockelmann, D. E. Pooley, Rutherford
Appleton Laboratory, UK; R. Raffanti, Techne Instruments, USA; W. B. Feller,
Nova Scientific, USA
N5-8 (09:45) Response Characterization for the Deuterium-Based
Liquid Scintillation Detector EJ315
C. C. Lawrence1, A. P. Enqvist1, T. N. Massey2, M. Flaska1, S. D. Clarke1, F.
D. Becchetti1, S. A. Pozzi1
1
University of Michigan, United States; 2Ohio University, United States
N6 Analog and Digital Circuits II
Session Chairs: Jean-Francois C. Genat, CNRS/IN2P3/LPNHE, France
Marcel Trimpl, Fermi National Laboratory, USA
N6-1 (08:00) LAr TPC Electronics Lifetime at 300 K and 77 K and
Reliability under Thermal Cycling
S. Li, H. Chen, G. De Geronimo, J. Ma, V. Radeka
Brookhaven National Laboratory, U.S.A.
N6-2 (08:15) The New PILATUS3 ASIC with Instant Retrigger
Capability
T. Loeliger, C. Broennimann, T. Donath, M. Schneebeli, R. Schnyder, P.
Trueb, DECTRIS Ltd., Switzerland
N6-3 (08:30) Front-End ASIC for High-Resolution and High-Rate
CsI(Tl)-Si Detectors
A. D’Andragora1, G. De Geronimo1, J. Kindem2, E. Vernon1
1
Brookhaven National Laboratory, USA; 2Digirad Corporation, USA
N6-4 (08:45) SCATS, a TDC for the PID of Superb Experiment
C. Beigbeder1, V. Tocut1, D. Breton1, S. Drouet2, L. Leterrier2, J. Maalmi1,
M. el Berni1, P. Vallerand2
1
LAL - CNRS - In2p3, France; 2LPC - CNRS -In2p3, France
N6-5 (09:00) Readout Front-End Electronics for Large Area X-Ray
Linear Silicon Drift Detectors for Space Missions
M. Ahangarianabhari, G. Bertuccio, D. Macera, Politecnico di Milano, Italy;
P. Malcovati, M. Grassi, University of Pavia, Italy; G. Baldazzi, University of
Bologna, Italy; M. Feroci, INAF/IASF, Italy; C. Labanti, INAF-IASF-Bologna,
Italy; A. Rashevsky, A. Vacchi, G. Zampa, N. Zampa, INFN - Trieste, Italy
N6-6 (09:15) Super-Altro 16: a Front-End System on Chip for DSP
Based Readout of Gaseous Detectors
M. De Gaspari, P. Aspell, H. Franca, E. Garcia Garcia, L. Musa
CERN, Switzerland
N6-7 (09:30) Code-Density Calibration of Nyquist-Rate Analog-toDigital Converters
C. R. Grace, P. Denes, D. Gnani, H. von der Lippe, J.-P. Walder
N6-8 (09:45) VMM1 - an ASIC for Micropattern Detectors
G. De Geronimo, J. Fried, S. Li, N. Nambiar, E. Vernon, V. Polychronakos
Brookhaven National Laboratory, USA
N7 Simulation
Session Chairs: Georg Weidenspointner, MPI Halbleiterlabor, Germany
John Mattingly, North Carolina State University, USA
N7-1 (08:00) MCNPX 2.7.0 - New Features Demonstrated
G. W. McKinney, J. W. Durkee, J. S. Elson, M. L. Fensin, J. S. Hendricks,
M. R. James, R. C. Johns, D. B. Pelowitz, L. S. Waters, T. A. Wilcox
Los Alamos National Laboratory, USA
N7-2 (08:15) MCNP6 Enhancements of Delayed-Particle Production
G. W. McKinney, Los Alamos National Laboratory, USA
N7-3 (08:30) Paths to Geant4 Evolution: Refactoring, Reengineering
and Physics
M. Batic1, M. Han2, S. Hauf3, G. Hoff4, C. H. Kim2, M. Kuster5, M. G.
Pia1, P. Saracco1, H. Seo6, G. Weidenspointner7, A. Zoglauer8
1
INFN Genova, Italy; 2Hanyang Univ., Korea; 3Darmstadt Technical Univ.,
Germany; 4PUCRS, Brazil; 5European XFEL GmbH, Germany; 6KAERI,
Korea; 7MPI Halbleiterlabor, Germany; 8UC Berkeley, USA
N7-4 (08:45) State-of-the-Art Simulation of Photon Interactions with
Matter
M. Batic1, G. Hoff2, M. G. Pia1, P. Saracco1
1
INFN Genova, Italy; 2PUCRS, Brazil
N7-5 (09:00) ITS Version 6.4: the Integrated TIGER Series of Monte
Carlo Electron/Photon Radiation Transport Codes
R. P. Kensek1, T. W. Laub1, B. C. Franke1, M. J. Crawford2, G. D. Valdez1
1
Sandia National Laboratories, USA; 2Raytheon Company, USA
N7-6 (09:15) The SCEPTRE Radiation Transport Code Project
C. Drumm, Sandia National Laboratories, USA
N7-7 (09:30) The FLUKA Monte Carlo Code and Its Applications
M. C. Morone1,2, 1University of Roma Tor Vergata, Italy; 2INFN, Italy
On behalf of the FLUKA Collaboration
N7-8 (09:45) Uncertainty Quantification in Generic Monte Carlo
Simulations
P. Saracco, M. Batic, G. Hoff, M. G. Pia, I.N.F.N., Italy
118 Tuesday - NSS Oral Presentations N8 Instrumentation for Homeland Security II:
Imaging
Session Chairs: Shaun D. Clarke, University of Michigan, USA
Mark Wrobel, DNDO, USA
N8-1 (10:30) Combining Radiography and Passive Measurements for
Radiological Threat Detection in Cargo
E. A. Miller, T. A. White, K. D. Jarman, R. T. Kouzes, J. A. Kulisek, S. M.
Robinson, C. Scherrer, R. S. Wittman
N8-2 (10:45) A Novel Technique to Detect Special Nuclear Material
Using Cosmic Rays
C. Thomay, J. Velthuis, P. Baesso, D. Cussans, University of Bristol, UK; S.
Quillin, S. Robertson, C. Steer, Atomic Weapons Establishment, UK
N8-3 (11:00) Compton Imaging with a Planar Semiconductor System
A. Sweeney1, A. J. Boston1, H. C. Boston1, J. R. Cresswell1, J. Dormand1, M.
Ellis2, L. J. Harkness1, T. Hughes1, M. Jones1, D. S. Judson1, P. Kendall2, S.
Moon1, P. J. Nolan1, V. Pucknell3, D. Scraggs1, D. A. Seddon1, C. ShentonTaylor2, J. Simpson3, M. J. Slee1, A. Thandi2
1
University of Liverpool, UK; 2Atomic Weapons Establishment, UK; 3STFC
Daresbury Laboratory, UK
N8-4 (11:15) Scalable Compton Camera Arrays for Standoff Radiation
Detection: Proof of Principle and Prototype Demonstration
G. Pausch1, H. Brands2, T. Glaser2, C.-M. Herbach1, L. Hoy2, Y. Kong1, M.
Kuester1, R. Lentering1, J. Preston2, K. Roemer1, F. Scherwinski1, J. Stein1,
N. Teofilov1, J. Verity2, A. Wolf1
1
FLIR Radiation GmbH, Germany; 2FLIR Radiation Detection, Tennessee
N8-5 (11:30) Dual Gamma-Ray and Fast Neutron Imaging for Mobile,
Standoff Detection of Nuclear Threat Sources
J. P. Hayward1, B. Ayaz-Maierhafer1, L. Fabris2, J. Newby2, B. Dabbs1, J.
Sparger1, P. A. Hausladen2, M. A. Blackston2, K. P. Ziock2
1
N8-6 (11:45) Grid-Free Backprojection-Maximization Algorithm for 3D
Imag- Ing Using a Vehicle-Mounted Coded Aperture Gamma Camera
J. S. Maltz1, D. L. Gunter1, L. Mihailescu1, R. Barnowski1,2, S. Huh1, T.
Aucott1,2, K. Vetter1,2
1
Lawrence Berkeley National Lab, USA; 2University of California, Berkeley,
USA
N8-7 (12:00) Real-Time Radioactive Source Localization with a Moving
Coded-Aperture Detector System at Low Count Rates
S. S. Huh, J. Maltz, D. Gunter, L. Mihailescu, K. Vetter
Lawrence Berkeley National Lab, USA
N8-8 (12:15) Motion Correction for Passive Radiation Imaging of Small
Vessels in Ship-to-Ship Inspections
K. P. Ziock, C. B. Boehnen, J. M. Ernst, L. Fabris, J. P. Hayward, V. C.
Paquit, D. R. Patlolla
Oak Ridge National Laboratory, USA
N9 Analog and Digital Circuits III
Session Chairs: Lorenzo Fabris, Oak Ridge National Laboratory, USA
Luigi Gaioni, INFN Pavia, Italy
N9-1 (10:30) Radiation-Hard/High-Speed Parallel Optical Links
K. K. Gan, The Ohio State University, USA
N9-2 (10:45) GEMEX, a Compact Readout System
B. Voss1, F. Garcia2, J. Hoffmann1, V. Kleipa1, J. Kunkel1, N. Kurz1, A.
Prochazka1, I. Rusanov1, M. Shizu1, P. Skott1
1
GSI Helmholtzzentrum für Schwerionenforschung GmbH, Germany; 2Helsinki
Institute of Physics, Finland
N9-3 (11:00) eLine100: a Front End ASIC for LCLS Detectors in Low
Noise Applications
A. Dragone, P. Caragiulo, D. Freytag, P. A. Hart, R. Herbst, S. Herrmann,
C. Kenney, J. Segal, G. Haller
N9-4 (11:15) 12-Bit, 3 GS/s, Radiation-Hard Time-Interleaved ADC for
Particle Detector Applications
E. O. Mikkola, S. Venkatesan, Ridgetop Group Inc., USA; A. Nazari, Arizona
State University, USA
N9-5 (11:30) A Prototype Pixel Readout Integrated Circuit with
Reconstitution of Full Signals for X-Ray Photon Science
G. W. Deptuch1, P. Grybos2, J. Hoff1, F. Khalid1, P. Maj2, R. Szczygiel2, M.
Trimpl1
1
Fermilab, USA; 2AGH-UST, Poland
N9-6 (11:45) An Integrated Low-Noise Charge-Sensitive Preamplifier
with Virtually Unlimited Spectroscopic Dynamic Range
A. Pullia1,2, F. Zocca2
1
N9-7 (12:00) SPADIC 1.0 - a Multi-Channel Charge Pulse
Amplification, Digitization and Processing ASIC for Detector
Applications
T. Armbruster, P. Fischer, M. Krieger, I. Peric
Heidelberg University, Germany
N9-8 (12:15) VERDI-3: Multi-Detector Readout ASIC
A. Celani1, R. Quaglia2, C. Fiorini2, T. Frizzi1, O. Evrard3, C. Cherukuri3, B.
Zakrzewski4, J. Pavlick4
1
XGLab s.r.l., Italy; 2Politecnico di Milano, Italy; 3Canberra Semiconductors
N.V., Belgium; 4Canberra Bumn Areva, USA
N10 Scintillators and Scintillation
Detectors I
Session Chairs: Etiennette Auffray, CERN, Switzerland
Hong Joo Kim, Kyungpook National University, South
Korea
N10-1 (10:30) Improvement of LaBr3:5%Ce Scintillation Properties by
Sr Co-Doping
M. S. Alekhin1, K. W. Kraemer2, D. A. Biner2, P. Dorenbos1
1
Delft University of Technology, The Netherlands; 2University of Bern, Switzerland
N10-2 (10:45) Scintillation Properties of CsBa2I5:Eu2+
M. S. Alekhin1, K. W. Kraemer2, D. A. Biner2, P. Dorenbos1
1
Delft University of Technology, The Netherlands; 2University of Bern,
Switzerland
N10-3 (11:00) Controlling Oxygen Defect Luminescence in Undoped
and Europium Doped BaBrCl and BaBrI Scintillators
E. C. Samulon, E. D. Bourret, Z. Yan, G. Bizarri
N10-4 (11:15) PbI2 as a Bright, Ultra-Fast Scintillator
S. E. Derenzo1, E. Bourret-Courchesne1, Z. Yan1, G. Bizarri1, A. Canning1,2,
G. Zhang1,2
1
Lawrence Berkeley National Laboratory, U.S.A.; 2University of California,
U.S.A.
N10-5 (11:30) Measurement of Impurities in Iodine-Based Starting
Materials and Their Observed Effect on Growth of Scintillators
S. Swider, S. Motakef, P. Becla, K. Becla, D. Bliss
CapeSym, Inc., USA
N10-6 (11:45) Optical Absorption and Temperature-Dependent
Photoluminescence Study of Undoped Strontium Iodide
J. Chen1,2, S. Wang1, L. Chen1
1
Shanghai Institute of Ceramics, Chinese Academy of Sciences, China; 2Graduate
University of Chinese Academy of Sciences, China
120 Tuesday - NSS Oral Presentations N10-7 (12:00) High Resolution and High Contrast Imaging with Thin
SrI2-Scintillator Screens
L. O. Alaribe1, M. Fiederle1,2, A. Cecilia2, E. Hamman2, P. Vagovic2, A.
Zwerger1
1
FMF-Freiburger Materialforschungszentrum, Germany; 2Karlsruher Institute
for Technology (KIT), Germany
N11 Instrumentation for Homeland Security
III: Active Interrogation
Session Chairs: Michael C. Wright, Oak Ridge National Laboratory, USA
Nathan H. Johnson, GE Emergy, USA
N11-1 (14:00, invited) Estimation of the Performance Capabilities
and Utility of Multiple Active Neutron Interrogation Signatures for the
Detection of Shielded Highly Enriched Uranium
D. L. Chichester, S. J. Thompson, S. M. Watson, J. T. Johnson, E. H.
Seabury, Idaho National Laboratory, USA
N11-2 (14:30) Active Detection of Special Nuclear Material Recommendations for Interrogation Source Approach in a Prototype
Active Detection System
J. O’Malley, P. N. Martin, R. Maddock, C. Hill, J. Threadgold, Atomic Weapons
Establishment, UK; S. L. Jackson, J. Schumer, R. Commisso, B. Phlips, Naval
Research Laboratory, USA; J. F. Davis, Defense Threat Reduction Agency, USA
N11-3 (14:45) A Characterization of the Induced Background for
Intense Pulsed Active Detection
S. B. Swanekamp1, J. P. Apruzese2, R. J. Commisso1, S. L. Jackson1, D.
Mosher2, J. W. Schumer1, B. V. Weber1, J. C. Zier1
1
Naval Research Laboratory, USA; 2Independent Consultant, USA
N11-4 (15:00) Fission Signature Interferences in Active Inspection
Techniques Utilizing High-Energy Bremsstrahlung
A. W. Hunt1, E. S. Cardenas1, M. T. Kinlaw2, E. T. E. Reedy1, H. A. Seipel1,
B. W. Blackburn3
1
Idaho State University, USA; 2Idaho National Laboratory, USA; 3Raytheon,
USA
N11-5 (15:15) Neutron-Sensitive Detectors for Intense Pulsed Active
Detection
E. Brubaker, J. Brennan, D. Derzon, M. Derzon, M. Gerling, P. Lake, P.
Marleau, S. Mrowka, B. Oliver, T. Renk, R. Renzi, J. Steele
N11-6 (15:30) Outdoor Stand-off Interrogation of Fissionable Material
E. A. Wulf1, A. L. Hutcheson1, B. E. Leas2, L. J. Mitchell1, B. V. Weber1, R.
S. Woolf3, B. F. Phlips1
1
Naval Research Laboratory, USA; 2SRA International, USA; 3National Research
Council/NRL, USA
N11-7 (15:45) The Imaging Detector Subsystem Electronics of the
Fieldable Nuclear Materials Identification System (FNMIS)
C. L. Britton, M. N. Ericson, S. S. Frank, L. Fabris, M. S. Emery, E.
Farquhar, N. D. Bull, D. E. Hurst, R. Lind, J. T. Mihalczo, D. Archer, J. A.
Mullens, J. Carter, S. McConchie, E. D. Sword, J. E. Radle
Oak Ridge National Lab, USA
N12 Astrophysics and Space Instrumentation I
Session Chairs: Diego Casadei, New York University, USA
Martin Pohl, DPNC, Univ. de Genève, Switzerland
N12-1 (14:00) Status and Results of the ANTARES and KN3NeT
Neutrino Telescope
U. Emanuele, IFIC - CSIC - University of Valencia, SPAIN
On behalf of the ANTARES Collaboration
N12-2 (14:30) Towards COUPP-500kg: a Large Bubble Chamber for
Dark Matter Detection
J. I. Collar, University of Chicago, USAS
On behalf of the COUPP collaboration
N12-3 (14:45) Cosmic Ray Physics above 100 TeV with ARGO-YBJ
Experiment
S. Mastroianni, INFN, Italy
On behalf of the ARGO-YBJ Collaboration
N12-4 (15:00) FACT - a Fact!
T. Bretz, EPF Lausanne, Switzerland
On behalf of the FACT collaboration
N12-5 (15:15) The PAMELA Experiment: Six Years of Cosmic Rays
Investigation
M. Boezio, INFN - Sezione di Trieste, Italy
On behalf of the PAMELA Collaboration
N12-6 (15:30) Expected Radiation Damage of Reverse-Type Avalanche
Photodiodes for the Future Space Missions
J. Kataoka, T. Saito, M. Yoshino, T. Nakamori, Waseda University, Japan;
Y. Yatsu, Tokyo Institute of Technology, Japan; Y. Ishikawa, Y. Matsunaga,
Hamamatsu Photonics, Japan; H. Tajima, Nagoya University, Japan; M.
Kokubun, JAXA, Japan; P. G. Edwards, Australia Telescope National Facility,
Australia
N12-7 (15:45) Precision Measurements of the Sun Diameter with the
Drift-Scan Method, Using a High Frame Rate Monolithic Active Pixel
Sensor
M. L. Caccia, M. Maspero, Università dell’Insubria, Italy; R. Ramelli, M.
Bianda, IRSOL, Switzerland
N13-6 (15:15) Thick GEM-Based Detectors of Single Photons for
Cherenkov Imaging Applications
S. Dalla Torre, INFN, Italy
On behalf of the Alessandria-Aveiro-Freiburg-Liberec-Prague-Torino-Trieste
Collaboration
N13-7 (15:30) Ion Back Flow Reduction Using a THCOBRA in a
THGEM Based VUV Photosensor
C. A. Santos1, F. Pereira1, T. Lopes1, C. D. R. Azevedo1, F. D. Amaro2, J. M.
F. Dos Santos2, A. Breskin3, R. Chechik3, J. F. C. A. Veloso1
1
University of Aveiro, Portugal; 2University of Coimbra, Portugal; 3Weizmann
Institute of Science, Israel
N13-8 (15:45) Neutron Imaging Detector Based on the μPIC MicroPixel Gaseous Chamber
J. D. Parker1, M. Harada2, K. Hattori1, S. Iwaki1, S. Kabuki1, Y. Kishimoto1,
H. Kubo1, S. Kurosawa1, K. Miuchi1, H. Nishimura1, T. Oku2, T. Sawano1,
T. Shinohara2, J.-I. Suzuki2, A. Takada1, T. Tanimori1, K. Ueno1
1
Kyoto University, Japan; 2Japan Atomic Energy Agency, Japan
N13 Gaseous Detectors I: Performance
Reports
Session Chairs: Leszek Ropelewski, CERN, Switzerland
Harry van der Graaf, Nikhef, Netherlands
N13-1 (14:00) The Construction and Testing of the First Straw Tracker
Module in NA62
H. Danielsson, CERN, Switzerland
On behalf of the NA62 Collaboration
N13-2 (14:15) Production and Test of the First Two Layers of the
KLOE-2 Inner Tracker
E. De Lucia1, A. Balla1, G. Bencivenni1, P. Branchini2, A. Budano2,
M. Capodiferro3, S. Cerioni1, P. Ciambrone1, G. De Robertis4, A. Di
Domenico3, D. Domenici1, J. Dong1, G. Fanizzi4, G. Felici1, M. Gatta1, N.
Lacalamita4, R. Liuzzi4, F. Loddo4, M. Mongelli4, G. Morello1, A. Pelosi3, L.
Quintieri1, A. Ranieri4, E. Tshadadze1, V. Valentino4
1
INFN-LNF, Italy; 2INFN-Roma Tre, Italy; 3Sapienza Universita’ di Roma e
INFN-Roma, Italy; 4INFN-Bari, Italy
N13-3 (14:30) Performance of Muon Drift Tube Detectors for LHC
Upgrades at Very High Neutral and Charged Particle Irradiation Rates
H. Kroha, B. Bittner, J. Dubbert, O. Kortner, A. Manfredini, S. Ott, R.
Richter, P. Schwegler, D. Zanzi, Max-Planck-Institut fuer Physik, Germany;
O. Biebel, A. Engl, R. Hertenberger, A. Zibell, Ludwig-Maximilians
University, Germany
N13-4 (14:45) Performance of the TOTEM Triple-GEM T2 Telescope
S. Lami, INFN, Italy
On behalf of the TOTEM T2 Group
N13-5 (15:00) The Operational Experience of the Triple-GEM Detectors
of the LHCb Muon System: Summary of 2 Years of Data Taking
A. Cardini, INFN Sezione di Cagliari, Italy; G. Bencivenni, INFN Lab.
Nazionali Frascati, Italy
122 Tuesday - NSS Oral Presentations Tuesday - NSS Oral Presentations 123
Tuesday - RTSD Oral
Presentations
Tuesday - Joint Oral
Presentations
R05 Applications 1
JMR MIC/RTSD Joint Session
Tuesday, Oct. 30 Session Chair: 10:30-11:55 Grand Ballroom Center
Larry Franks, Consultant, USA
R05-1 (10:30, invited) Visualization of Radioactive Substances with a Si/
CdTe Compton Camera
T. Takahashi, S. Watanabe, S. Takeda, ISAS/JAXA, Japan; H. Tajima, Nagoya
University, Japan
R05-2 (10:50, invited) New Results of Testing an Array of Virtual FrischGrid Detectors Using a 3D-ASIC Readout System
A. E. Bolotnikov, G. S. Camarda, Y. Cui, G. De Geronimo, A. Hossain, K.
H. Kim, G. Yang, E. Vernon, R. B. James
R05-3 (11:10) A New Low-Power ASIC for Handheld and Unattended
High-Resolution Gamma-Ray Spectroscopy
A. Volkovskii, M. Clajus, S. Snyder, T. Tumer
NOVA R&D, Inc., USA
R05-4 (11:25) Development of CdTe Detectors with 100 μm 3-D
Resolution for Future Single Photon Emission Microscopy Applications
L.-J. Meng1, J.-C. Zhang1,2, R. Durrant3, K. Spartiotis3
1
University of Illinois at Urbana-Champaign, U.S.A.; 2Institute of Mordern
Physics, Chinese Academy of Sciences, China; 3Oy AJAT Ltd., Finland
R05-5 (11:40) Large Array of Advanced CZT Imaging Detectors for
Hard X-Ray Telescope ProtoEXIST2 and MIRAX
J. Hong, B. Allen, J. Grindlay, Harvard-Smithsonian Astrophysical
Observatory, USA; R. Baker, S. Barthelmy, Goddard Space Flight Center, USA;
P. Mao, H. Miyasaka, California Institute of Technology, USA
Tuesday, Oct. 30 08:30-10:00 Grand Ballroom Center
Session Chairs: Kyeong Min Kim, Korea Institute of Radiological and
Medical Sciences, South Korea
Benjamin M. W. Tsui, Johns Hopkins University, USA
JMR-1 (08:30) Correction of the Detection Efficiency of Individual
Pixels for CdTe Detector in X-Ray Imaging
Y.-N. Choi, H.-J. Kim, H.-M. Cho, S.-W. Lee
Yonsei unversity, Korea
JMR-2 (08:45) Optimal Architecture of CdZnTe Detectors for Photon
Counting, Multispectral Medical X-Ray Imaging: Comparison Between
Simulation and Experiment
A. K. Rossall, M. E. Myronakis, D. G. Darambara, Institute of Cancer
Research, UK; A. Cherlin, I. Radley, M. Ayoub, Kromek Ltd, UK
JMR-3 (09:00) Characterization of Inter-Detector Effects in a 3-D
Position-Sensitive Dual-CZT Detector Modules for PET
Y. Gu, C. S. Levin, Stanford University, USA
JMR-4 (09:15) High Flux X-Ray Imaging with CdZnTe Arrays
W. C. Barber1, J. C. Wessel2, E. Nygard2, N. Malakhov2, G. Wawrzyniak2, N.
E. Hartsough1, T. Gandhi1
1
DxRay Inc., USA; 2Interon AS, Norway
JMR-5 (09:30, invited) Evaluation of a CZT Detection Module Concept
for SPECT
G. Montemont, S. Lux, O. Monnet, S. Stanchina, L. Verger
CEA-Leti, MINATEC Campus, France
JMR-6 (09:45) High Energy 4-Pi Compton Imaging Using a 3D
Position Sensitive CdZnTe Detector Array
E. M. Dughie1,2, J. M. Jaworski1, Z. He1
1
University of Michigan, USA; 2University of New Mexico, USA
JNM NSS/MIC Joint Session
Session Chairs: Katia Parodi, Heidelberger Ionen Therapie, Heidelberg,
Germany
JNM-1 (14:00) Measurement of the Physical PSF for an Integrated PET/
MR Using Targeted Positron Beams
C. C. Watson, Siemens Healthcare, USA
JNM-2 (14:15) EndoTOFPET-US: a Novel Multimodal Tool for
Endoscopy and Positron Emission Tomography
E. Garutti, University of Hamburg, Germany
On behalf of the EndoTOFPET-US collaboration
JNM-3 (14:30) First In-Vivo Images with the KIT 3D Ultrasound
Computer Tomograph
H. E. H. Gemmeke, L. Berger, M. Birk, R. Dapp, T. Hopp, B. Kohout,
E. Kretzek, A. Menshikov, D. Tcherniakovski, M. Zapf, N. V. Ruiter, KIT,
Germany; W. Kaiser, Uni Jena, Germany
JNM-4 (14:45) A Prototype Animal PET with DOI Measurement Using
SSPM Arrays and Parallel Readout Electronics
Y. Shao1, X. Sun1, K. A. Lan1, C. Bircher1, J. Wu2, K. Lou1
1
The University of Texas M.D. Anderson Cancer Center, USA; 2Tsinghua
University, China
124 Tuesday - RTSD Oral Presentations Tuesday - Joint Oral Presentations 125
JNM-5 (15:00) Proton Interaction Vertex Imaging with Silicon-Pixel
CMOS Telescopes for Carbon Therapy Quality Control
V. Reithinger1, C. Ray1, J. Baudot2, S. Brons3, D. Dauvergne1, G. Dedes1, P.
Henriquet1, J. Krimmer1, K. Parodi3, E. Testa1, M. De Rydt4, M. Winter2
1
Universit de Lyon, UCBL, CNRS/IN2P3, Institut de Physique Nucleaire de
Lyon, France; 2Universit de Strasbourg, CNRS/IN2P3, Institut Pluridisciplinaire
Hubert Curien, France; 3Heidelberg Ion Beam Therapy Center, Germany;
4
InstituutvoorKern- en Stralingsfysica, KU Leuven, Belgium
JNM-6 (15:15) Status of the Development of a Single Gamma-Ray
Imaging System for in-vivo Dosimetry at Particle Beams
F. Fiedler1, C. Golnik2, T. Kormoll2, A. Mueller2, H. Rohling2, S. Schne1, W.
Enghardt1,2
1
Helmholtz-Zentrum Dresden-Rossendorf, Germany; 2OncoRay, Germany
JNM-7 (15:30) Novel Strip Encoding DoI Detector Based on G-APDs
A. Kolb1, C. Parl1, C.-C. Liu1, E. Lorenz2, B. J. Pichler1
1
University of Tuebingen, Germany; 2Max Planck Institute, Germany
JNM-8 (15:45) Modeling Considerations for Improving Accuracy of a
Proton Therapy Beam with GEANT4
S. R. Barnes, G. A. McAuley, A. J. Wroe, J. M. Slater, Loma Linda University,
USA
JNMR NSS/MIC/RTSD Triple Joint Session
Session Chairs: Andrew L. Goertzen, University of Manitoba, Canada
Michael Fiederle, Freiburger Materialforschungszentrum,
Germany
JNMR-1 (16:30) A Status Update on Proton Imaging for Applications
in Medicine
R. W. Schulte, Loma Linda University Medical Center, USA
JNMR-2 (17:00) How Photonic Crystals Can Improve the Timing
Resolution of Scintillators
P. R. Lecoq, E. Auffray, A. Knapitsch, CERN, Switzerland
JNMR-3 (17:15) Towards Fragment Distinction in Therapeutic Carbon
Ion Beams: A Novel Experimental Approach Using the Timepix Detector
B. Hartmann1,2, K. Gwosch1, C. Granja3, J. Jakubek3, S. Pospisil3, O.
Jaekel1,2,4, M. Martisikova1,2
1
German Cancer Research Center (DKFZ), Germany; 2Heidelberg University
Hospital, Germany; 3Czech Technical University in Prague, Czech Republic;
4
Heidelberg Ion-Beam Therapy Center, Germany
JNMR-4 (17:30, invited) Si/CdTe Medipix3 CT for Material Sciences
S. Procz1, A. Fauler1, A. Zwerger1, M. Pichotka1, E. Hamann2, M. Mix3, M.
Fiederle1
1
University Freiburg, Germany; 2Karlsruhe Institute for Technology (KIT),
Germany; 3Uniklinikum Freiburg, Germany
JNMR-5 (17:45, invited) Clinical Trials of ProxiScan Compact Gamma
Camera in Prostate Cancer Diagnosis
Y. Cui1, T. Lall2, G. Mahler1, G. Meinken1, P. Vaska1, A. Bolotnikov1, G. De
Geronimo1, A. Hossain1, K.-H. Kim1, G. Yang1, B. Franc3, T. Johnson3, Y. Seo4,
A. Rittenboch5, B. Tsui5, M. Pomper5, S. Cho5, K. Weisman6, R. B. James1
1
Brookhaven National Laboratory, USA; 2Hybridyne Imaging Technolgies, Inc.,
Canada; 3Radiological Associates of Sacramento, USA; 4University of California
at San Francisco, USA; 5Johns Hopkins Medical Institutions, USA; 6Medstate
Hospital, USA
JNMR-6 (18:00) High-Resolution, High-Sensitivity PET Detectors
Using Laser-Engraved LYSO and SiPM
H. Sabet, H. Kudrolli, B. Singh, V. V. Nagarkar
RADIATION MONITORING DEVICES INC, USA
JNMR-7 (18:15) Characterization of Monolithic Scintillator TOF-PET
Detectors Based on Digital SiPM Arrays
G. Borghi, H. T. van Dam, S. Seifert, V. Tabacchini, D. R. Schaart
Delft University of Technology, Netherlands
126 Tuesday - Joint Oral Presentations Tuesday - Linear Collider Event
Oral Presentations
LC3 ILC/CLIC Detector Concepts and
Summary of Detector Spin-Offs
Tuesday, Oct. 30 08:00-10:00 Grand Ballroom South AB
Session Chair: TBD
LC3-1 (08:00, invited) State-of-the-art in Gaseous Tracking for LC
T. Matsuda, KEK/IPNS, Japan
LC3-2 (08:25, invited) State-of-the-art in Electromagnetic Calorimetry
for LC
J.-C. Brient, Ecole Polytechnique, France
LC3-3 (08:50, invited) State-of-the-art in Hadronic Calorimetry for LC
J. Repond, Argonne National Laboratory, USA
LC3-4 (09:15, invited) State-of-the-art in Forward Calorimetry and
other Miscellaneous Detector Applications
S. Kulis, AGH University of Science and Technology, Poland
LC3-5 (09:30, invited) Summary of the Spin-off Document “ILC
Detector R&D: Its Impact”
M. Demarteau, Argonne National Laboratory, USA
LC4 ILC/CLIC Detector Spin-offs and ILC/
CLIC Accelerator Instrumentation
Session Chair: TBD
LC4-1 (10:30, invited) From ILC Imaging Calorimeter to a PET
Detector
E. Garutti, University of Hamburg, Germany
LC4-2 (11:00, invited) LC Spin-offs outside Medical Imaging
C. De La Taille, IN2P3/CNRS, France
LC4-3 (11:30, invited) Linear Collider Instrumentation
T. Lefevre, CERN, Switzerland
LC4-4 (11:50, invited) Linear Collider Module Control and
Stabilization
A. Jeremie, LAPP, France
LC4-5 (12:10, invited) Alignment Challenges for a Future Linear
Collider
H. Schmickler, CERN, Switzerland
LC5 ILC/CLIC Accelerator Technologies for
Session Chair: TBD
LC5-1 (14:00, invited) Opportunities for Applications of LC Technology
(Institutional Perspective)
M. C. Ross, SLAC National Accelerator Laboratory, USA
LC5-2 (14:25, invited) Overview of Industrial, Medical, Energy and
Security Related Accelerator Use (Industry Perspective)
N. Holtkamp, SLAC National Accelerator Laboratory, USA
LC5-3 (14:50, invited) Applications of Superconducting RF Linear
J. Rathke, Advanced Energy Systems, USA
Tuesday-LinearColliderEventOralPresentations 127
LC5-4 (15:15, invited) Applications of Normal-Conducting RF Linear
W. Wuensch, CERN, Switzerland
LC5-5 (15:40, invited) Applications of Linear Collider Supporting RF
Technology (Industry Perspective)
S. Lenci, Communications & Power Industries LLC, USA
LC6 ILC/CLIC Accelerator Technologies for
Industrial Applications II
Session Chair: TBD
LC6-1 (16:30, invited) Applications of Linear Collider Supporting
Instrumentation Technology (Industry Perspective)
M. Ross, SLAC National Accelerator Laboratory, USA
LC6-2 (16:55, invited) The status of Advanced Accelerator Association
Promoting Science and Technology
M. Matsuoka
Secretary General, Advanced Accelerator Association Promoting Science &
Technology, Japan
LC7 Forum Discussion about LC perspectives
Session Chair: TBD
LC6-3 (17:30) Forum Discussion about LC perspectives
Rolf-Dieter Heuer, CERN, Switzerland, Joachim Mnich, DESY, Germany,
Atsuto Suzuki, KEK, Japan, Pier Oddone, FNAL, USA
128 Tuesday-LinearColliderEventOralPresentations Tuesday - NSS Poster
Presentations
N14 NSS Poster Session II
Tuesday, Oct. 30 16:30-18:30 Exhibit Hall North
Session Chairs: Lorenzo Fabris, Oak Ridge National Laboratory, USA
Jose Repond, Argonne National Laboratory, USA
Marcel Stanitzki, DESY, Germany
Accelerator Technologies and Beam Line
Instrumentation
N14-1 Development of a Compact Laser-Compton X-Ray Source Using
Optical Super-Cavity at KEK-LUCX
K. Sakaue, M. Washio, Waseda University, Japan; S. Araki, M. Fukuda, N.
Terunuma, J. Urakawa, High Energy Accelerator Research Organization (KEK), Japan
N14-2 The Beam Profile Monitor for UA9 Experiment
F. Iacoangeli, G. Cavoto, INFN, Italy
N14-3 LLRF Control System for TTX
H. Lu, Q. Du, Tsinghua University, China
N14-4 A Prototype of CVD Diamond Based Beam Loss Monitoring
Detector for the SSRF and the NSRL
M. Zeng1,2, X. Ouyang1, D. Zhang3, X. Xu3, Y. Li4, J. Li4
1
Ministry of Education, China; 2Tsinghua University, China; 3Chinese Academy
of Sciences, China; 4University of Science and Technology of China, China
N14-5 Study of the Electronics Design for a High Resolution
Hodoscope for Beam Positioning
J. M. Blasco Igual, E. Sanchis, V. Gonzalez, D. Barrientos, J. Egea, J. D.
Martin, D. Granero, University of Valencia, Spain
N14-6 Considerations for Neutron Irradiation When Using Constant
and Pulsed Sources
M. R. Halstead1, J. C. Petrosky1, J. W. McClory1, S. Clark2, P. E. Sokol3,4
1
Air Force Institute of Technology, United States; 2Naval Surface Warfare Center
(Crane Division), United States; 3Indiana University, United States; 4Center for
the Exploration of Energy and Matter, United States
N14-7 Development of Longitudinal Profile Monitor for Ultra-Short
Electron Beam Using EO Sampling Method
R. Kuroda1, M. Kumaki2, Y. Taira1, H. Toyokawa1, K. Yamada1
1
National Institute of Advanced Industrial Science and Technology (AIST),
Japan; 2Waseda University, Japan
Analog and Digital Circuits
N14-8 SKIROC2, Front End Chip Designed to ReadOut the
Electromagnetic Calorimeter at the ILC
S. Callier1, F. Dulucq1, C. de La Taille1,2, G. Martin-Chassard1, N. SeguinMoreau1
1
OMEGA - LAL - IN2P3/CNRS, FRANCE; 2IN2P3 / CNRS, FRANCE
N14-9 Improvement of the CC2 Charge Sensitive Preamplifier for the
GERDA Phase II Experiment
S. Riboldi1,2, A. Pullia1,2, C. Cattadori2
1
Universita’ degli Studi di Milano, Italy; 2INFN, Italy
N14-10 An Analog Solution Generating the Dynamic Threshold for
TODT Digitizing Scheme
W. Yonggang, Z. Wensong
University of Science and Technolgy of China, China
Tuesday - NSS Poster Presentations 129
N14-11 CLARO-CMOS, an ASIC for Single Photon Counting with
PMTs, MCPs and SiPMs
P. Carniti1, M. De Matteis2, A. Giachero1,3, C. Gotti3,4, M. Maino1,3, G.
Pessina1,3
1
University of Milano Bicocca, Italy; 2University of Salento, Italy; 3INFN section
of Milano Bicocca, Italy; 4University of Firenze, Italy
N14-12 Time Amplification Using Closed-Loop Differential Difference
Amplifier
H.-P. Chou, M. Chung, W. Liu
National Tsing Hua University, Taiwan
N14-13 An Area-Efficient and High Resolution Time-to-Digital
Converter Using Gated-Ring-Oscillator
C.-Y. Li, H.-P. Chou, National Tsing Hua University, Taiwan
N14-14 OMEGAPIX2: 3D Integrated Circuit Prototype Dedicated to
Read Out Plannar Pixel Sensor
D. Thienpont, IN2P3/LAL/OMEGA, FRANCE
N14-15 A/D and D/A Processing Unit for Astrophysics Applications
M. Bitossi, A. Gennai, D. Passuello, I.N.F.N. PISA, ITALY
N14-16 CASAGEM: A Readout ASIC for MPGDs
L. He1,2, Z. Deng1,2, Y. N. Liu1,2
1
N14-17 16bit Multi-Energy Level Detecting Photon Counting ROIC
S.-Y. Soh, J. Jeong, A. Han, E. Kim, K. Hong, H. Lee, Y. Kim, C. Kwak,
M.-J. Soh
Luxen Technologies, Inc., Korea, Rep. of
N14-19 FPGA-Based Architecture for Fast Feature Extraction with High
Resolution
A. Y. Sukhanov, Brookhaven National Laboratory, USA
On behalf of the PHENIX
N14-20 Fully Active Voltage Divider for PMT Photo-Detector
P. Margulis, M. Heifets
Applied Materials (Israel) Ltd., Israel
N14-21 A Versatile Low-Noise Wide-Range Charge-Sensitive
Preamplifier for HPGe Detectors
A. Pullia1,2, G. Pascovici3, C. Ur2
1
University of Milano, Italy; 2INFN, Italy; 3University of Koeln, Germany
N14-22 Digi-Opt12: 12-Channel 14/16-Bit 100/125-MS/s Digitizer
with Optical Output for GALILEO/AGATA
A. Pullia1,2, D. Barrientos2,3, D. Bazzacco2, M. Bellato2, D. Bortolato2, R.
Isocrate2
1
University of Milano, Italy; 2INFN, Italy; 3IFIC, Spain
N14-23 Dynamic Time-over-Threshold Method for Multi-Channel APD
Based Gamma-Ray Detectors
T. Orita, H. Takahashi, K. Shimazoe
The University of Tokyo, Japan
N14-24 Designing the Front-End Electronics of a SiPM Based γ-Ray
Detection System for Optimal Time Resolution
F. Corsi1,2, F. Ciciriello1, F. Licciulli1, C. Marzocca1,2, G. Matarrese1,2, A. Del
Guerra3,2, M. G. Bisogni3,2
1
Politecnico Di Bari, Italy; 2INFN, Italy; 3Universit di Pisa, Italy
N14-25 Multi-Correlated Double Sampling vs Analog Shaper: Low
Power ASIC for Pixelated CdTe
A. Michalowska, O. Gevin, O. Limousin, CEA Saclay, France
N14-26 Time-to-Digital Converters for PET: An Examination of
Metrology Aspects
M. W. Fishburn, E. Charbon
Delft University of Technology, Netherlands
N14-27 Fast Analog Front-End for the Readout of the SuperB SVT
Inner Layers
G. Traversi1, L. Gaioni1, M. Manghisoni1, L. Ratti2, V. Re1
1
University of Bergamo and INFN, Italy; 2University of Pavia and INFN, Italy
130 Tuesday - NSS Poster Presentations N14-28 Low Power, Low Noise Charge Sensitive Amplifier in CMOS
0.18 μM for Fine Pitch Pixelated CdTe Detector Readout
O. Gevin, A. Michalowska, O. Limousin, CEA, France
N14-29 A Design of Noble Sample-and-Hold Circuit Using a MicroInductor to Improve the Contrast Resolution of X-Ray CMOS Image
Sensors
D. H. Lee, G. Cho, J. H. Bae, H. Kim, J. Y. Kim, C. Kim, D.-U. Kang, M.
S. Kim, M. Cho, H. Yoo, Y. Kim, H. Kim, J. Lee
N14-30 Development of an Amplifier IC with Wide Dynamic Range for
Si Detector in RIKEN SAMURAI Spectrometer
A. Takuma, K. Kurita, Rikkyo University, Japan; M. Tanaka, KEK, Japan; A.
Taketani, RIKEN, Japan
N14-31 Development of a Readout Electronic for the Measurement
of Ionization in Liquid Xenon Compton Telescope Containing MicroPatterns
O. Lemaire1, W.-T. Chen1, J.-P. Cussonneau1, E. Delagnes2, J. Donnard1, S.
Duval1, O. Gevin2, A.-F. M. Hadi1, E. Morteau1, T. Oger1, L. Scotto-lavina1,
D. Thers1
1
SUBATECH, France; 2CEA, France
N14-32 Timing Performance of FBK SiPMs Coupled to the PETA3
Readout ASIC.
A. Tarolli, C. Piemonte, A. Gola, Fondazione Bruno Kessler, Italy; P. Fischer,
M. Ritzert, Univ. of Heidelberg, Germany
N14-33 A Scalable Digital Pulse Process Module for the MRPC Detector
of Muon Tomography
X. Yue1,2, M. Zeng1,2, Z. Deng1,2, Z. Zeng1,2, X. Wang1,2, J. Cheng1,2
1
Ministry of Education, China; 2Tsinghua University, China
N14-34 A 16 Channels Multi-Detector Pulse Shape Amplifier with
Serialized Readout
C. Boiano1, S. Riboldi1,2, A. Guglielmetti1,2
1
INFN, Italy; 2Universit degli Studi di Milano, Italy
N14-35 Noise Considerations for a Very Low Threshold Semiconductor
Detector System
J. D. Leon, A. Knecht, M. L. Miller, R. G. H. Robertson, T. D. Van Wechel
University of Washington, USA
N14-36 A 34 Gbps Data Transmission System with FPGAs Embedded
Transceivers and QSFP+ Modules.
R. Ammendola, A. Biagioni, O. Frezza, F. Lo Cicero, A. Lonardo, P. S.
Paolucci, D. Rossetti, A. Salamon, G. Salina, F. Simula, L. Tosoratto, P.
Vicini
INFN, Italy
N14-37 STiC - a Mixed Mode Chip for SiPM ToF Applications
W. Shen, T. Harion, K. Briggl, H.-C. Schultz-Coulon, M. Ritzert, P. Fischer
University of Heidelberg, Germany
N14-38 Time-over-Threshold Processing Implementation for Silicon
Detectors with Large Capacitances
K. Kasinski, R. Kleczek, P. Grybos, R. Szczygiel
AGH University of Science and Technology, Poland
N14-39 A Low Cross-Talk 3-Channel Analog Multiplexer with a 12-Bit
25-MS/s Pipelined ADC
F. Rarbi, D. Dzahini, L. Gallin-Martel
LPSC - IN2P3, France
N14-40 Solid State Radiation Measurement System for High Flux
Applications
V. Buck, M. Mowrer, D. Perkins, N. Annetta, M. Wilson, C. Bouton
Battelle Memorial Institute, USA
N14-41 A Low-Utilization FPGA-Based TDC and Time-Processing
System for Use in Integrated PET Event Processing
G. J. Mann, O. Ivanov, K. C. Burr, G.-C. Wang, D. Gagnon
Toshiba Medical Research Institute, USA
N14-42 sLine: an High Voltage Switcher ASIC for LCLS Detectors with
Rolling Shutter
P. Caragiulo, A. Dragone, R. Herbst, G. Haller
N14-43 eLine10k: an High Dynamic Range Front End ASIC for LCLS
Detectors
A. Dragone1, P. Caragiulo1, G. A. Carini1, R. Herbst1, J.-F. Pratte2, P.
O’Connor3, P. Rehak3, D. P. Siddons3, G. Haller1
1
SLAC National Accelerator Laboratory, USA; 2Universite’ de Sherbrooke,
Canada; 3Brookhaven National Laboratory, USA
N14-44 Readout Electronics Development Based on an ASIC for PET
Detector Using PMT-Quadrant-Sharing
T. Xu1,2, J. Chen3, L. Lu1,2, Z. Deng1,2, T. Ma1,2, S. Wang1,2, Y. Liu1,2
1
Tsinghua University, China; 2Ministry of Education, China; 3National Institute
of Metrology, China
N14-45 Development and Tests of the Front-End Readout System for
the Belle II Aerogel RICH
A. Seljak1, I. Adachi2, R. Dolenec1, K. Hara2, M. Higuchi3, T. Iijima4, S.
Iwata5, H. Kakuno5, H. Kawai6, T. Kawasaki7, S. Korpar8,1, P. Krizan9,1, T.
Kumita5, W. Mori10, S. Nishida2, S. Ogawa10, R. Pestotnik1, E. Ribezl1, Y.
Sakashita5, L. Santelj1, T. Sumiyoshi5, H. Takagaki5, M. Tabata6,11, Y. Yusa7,
R. Verheyden1
1
J. Stefan Institute, Slovenia; 2IPNS, High Energy Accelerator Research
Organization (KEK), Japan; 3Tokyo University of Science, Japan; 4Nagoya
University, Japan; 5Tokyo Metropolitan University, Japan; 6Chiba University,
Japan; 7Niigata University, Japan; 8University of Maribor, Slovenia; 9University
of Ljubljana, Slovenia; 10Toho University, Japan; 11Japan Aerospace Exploration
Agency (JAXA), Japan
Astrophysics and Space Instrumentation
N14-46 Multiband Charge-Coupled Device
C.-E. Chang1, J. D. Segal2, C. J. Kenney2, A. J. Roodman2, R. T. Howe1
1
Stanford University, CA; 2SLAC National Accelerator Laboratory, CA
N14-47 Design of Electronics of LEPD Onboard the CSES Satellite
F. Wu, H. Wang, Institute of High Energy Physics, China
N14-48 Balloon-Flight Test of a Lanthanum Bromide Gamma-Ray
Detector with Silicon Photo-Multiplier Readout
P. F. Bloser, J. S. Legere, J. R. Wurz, L. F. Jablonski, C. M. Bancroft, M. L.
McConnell, J. M. Ryan
University of New Hampshire, USA
N14-49 Verification of Compton-Imaged Low-Significance Sources on
the Example of High-Energy COMPTEL Data
A. Zoglauer, S. E. Boggs, University of California at Berkeley, USA
N14-50 The Upgraded Readout System of the MAGIC Telescopes
D. Tescaro, INFN, Italy
On behalf of the MAGIC Collaboration
N14-51 ASPIC: an Integrated Circuit for LSST CCDs Readout
V. Tocut, H. Lebbolo, J. Jeglot, C. Juramy, P. Antilogus
CNRS, France
N14-52 Performance of the Pulse Shape Processor for the Soft X-Ray
Spectrometer Onboard ASTRO-H
S. Takeda1, M. S. Tashiro1, Y. Ishisaki2, M. Tsujimoto3, H. Seta4, Y.
Shimoda1, S. Yamaguchi1, K. Mitsuda3, Y. Terada1, Y. Takei3
1
Saitama University, Japan; 2Tokyo Metropolitan University, Japan; 3ISAS/
JAXA, Japan; 4Rikkyo, Japan
N14-53 Development of a Detector Based on Silicon Drift Detectors for
Gamma-Ray Spectroscopy for Astronomy Applications
C. Fiorini1,2, R. Peloso1,2, L. Bombelli1,2, P. Busca1,2, R. Quaglia1,2, A.
Geraci1,2, P. Bellutti3, M. Boscardin3, F. Ficorella3, G. Giacomini3, A.
Picciotto3, C. Piemonte3, N. Zorzi3, N. Nelms4, B. Shortt4
1
Politecnico di Milano, Italia; 2INFN sezione Milano, Italia; 3Fondazione Bruno
Kessler - FBK, Italy; 4European Space Agency, The Netherlands
132 Tuesday - NSS Poster Presentations N14-54 Readout Electronics and DAQ System for Silicon Drift Detector
Arrays in Gamma Ray Spectroscopy Applications
R. Quaglia1,2, A. Abba1, L. Bombelli1,2, P. Busca1,2, F. Caponio1, C. Fiorini1,2,
A. Geraci1, R. Peloso1,2
1
Politecnico di Milano, Italy; 2INFN - Sezione Milano, Italy
N14-55 A Low-Resistivity, Thin-Window, Thinner-Silicon, N-Type,
Hexagonal-Spiral, Silicon Drift Detector Array
W. Chen1, G. De Geronimo1, J. A. Gaskin2, S. Li1, Z. Li1, B. D. Ramseya2,
G. Smith1
1
Brookhaven National Lab, USA; 2The MSFC/National Space Science and
Technology Center,, USA
Computing and Software for Experiments
N14-56 The Design and Realization of Detector Control System of Daya
Bay Neutrino Experiment
Y. Mei
Institute of High Energy Physics , Academia Sinica, CHINA
N14-57 Simulation of Radiation Tolerance of N-in-P Slim-Edge
Detectors for Close-to-Bem Experiments at HL-LHC
J. P. Balbuena1,2, G. Pellegrini2, C. Fleta2, M. Lozano2, G. Ruggiero3, M.
Ullan2, E. Verbitskaya4
1
Freiburg Materials Research Center, Albert-Ludwigs University, Germany;
2
Centro Nacional de Microelectronica IMB-CNM (CSIC), Spain; 3CERN,
Switzerland; 4Ioffe Physico-Technical Institute, Russian Academy of Sciences,
Russia
N14-58 Study of Surface Effects in the Operation of 3D Microstrip
Detectors with Ultra-Thin Silicon Substrates
J. P. Balbuena1,2, G. Pellegrini2, C. Fleta2, C. Guardiola2, M. Lozano2, D.
Quirion2, M. Ullan2, F. Garcia3
1
Freiburg Materials Research Center, Albert-Ludwigs University, Germany;
2
Centro Nacional de Microelectronica IMB-CNM (CSIC), Spain; 3Helsinki
Institute of Physics, Finland
N14-59 Combined MCNP/GADRAS Simulation of HPGe Gamma
Spectra
M. Rawool-Sullivan, Los Alamos National Laboratory, USA; J. Mattingly,
North Carolina State University, USA; D. J. Mitchell, Sandia National
Laboratories, USA
N14-60 Regularization Approach for Abel Transform Based Image
Reconstruction by X-Ray Radiograph Tomography
S. H. Wei
Institute of Applied Physics and Computational Mathematics, China
N14-61 Monitoring Tool for Digital Errors in the ATLAS Tile
Calorimeter Readout
M. Cuciuc, Horia Hulubei National Institute of Physics and Nuclear
Engineering - IFIN HH, Romania
On behalf of the ATLAS Tile Calorimeter System
N14-62 Administration and Management of Computing Critical
Services for the CMS Experiment
J. Molina Perez, CERN, Switzerland
N14-63 Radiation Monitoring of Dry SNF Storage Casks: Feasibility
Study
A. Ivanov, V. Pedash, V. Kolbasin, V. Tarasov, Institute for scintillation
materials NAS Ukraine, Ukraine; I. Bodnar, J. Lambert, Argonne National
Laboratory, USA
N14-64 An Attenuated Projector for Iterative Reconstruction Algorithm
of a Novel Tomographic Gamma Scanner
M. A. Belzunce1,2, C. Verrastro1,2, E. Venialgo1,2, E. Da Ponte1, A.
Carimatto1,2, L. Martinez Garbino1,2, J. Alarcon1,2, D. Estryk1
1
CNEA, Argentina; 2UTN-FRBA, Argentina
N14-65 Physics Data Libraries: Content and Algorithms for Improved
Monte Carlo Simulation
M. Batic1, M. Han2, S. Hauf3, G. Hoff4, C. H. Kim2, M. Kuster5, M. G.
Pia1, P. Saracco1, H. Seo6, G. Weidenspointner7
1
INFN Genova, Italy; 2Hanyang Univ., Korea; 3Darmstadt Technical Univ.,
Germany; 4PUCRS, Brazil; 5European XFEL GmbH, Germany; 6KAERI,
Korea; 7MPI Halbleiterlabor, Germany
N14-66 New Developments of the Statistical Toolkit
M. Batic1, A. Pfeiffer2, A. M. Paganoni3, M. G. Pia1, A. Ribon2
1
INFN Genova, Italy; 2CERN, Switzerland; 3Politecnico di Milano, Italy
N14-67 A 3-D Simulation Code of Electron-Hole Transport and Signal
Formation with Coulomb Repulsion and Thermal Diffusion in 2-D
Semiconductor Detectors
A. Castoldi1,2, C. Guazzoni1,2, P. Zambon1,2
1
Politecnico di Milano, Italy; 2INFN, Italy
N14-68 Iterative Reconstruction of Coded Source Neutron Radiographs
P. Bingham, H. Santos-Villalobos, Oak Ridge National Laboratory, USA; J.
Gregor, University of Tennessee, USA
N14-69 CALICE Software Framework and Operational Experience
R. Poeschl, LAL Orsay, France, On behalf of the CALICE Collaboration
N14-70 New Computational Methodology for the Execution of Massive
Distributed Calculations: Its Application to the Neoclassical Transport in
Nuclear Fusion Plasmas
A. J. Rubio-Montero1, E. Huedo2, F. Castejon3, J. L. Velasco3, R. MayoGarcia1
1
CIEMAT, Spain; 2UCM, Spain; 3Euratom-CIEMAT Association, Spain
N14-71 SuperB Production System for Simulated Events
F. Bianchi1, V. Ciaschini2, M. Corvo3, D. Del Prete4, A. Di Simone5, G.
Donvito6, A. Fella7, P. Franchini2, F. Giacomini2, A. Gianoli8, S. Longo9,
S. Luitz10, E. Luppi11, M. Manzali11, S. Pardi4, A. Perez12, M. Rama13, G.
Russo4, B. Santeramo6, R. Stroili14, L. Tomassetti11
1
University of Torino and INFN, Italy; 2INFN CNAF, Italy; 3CNRS and INFN
Padova, Italy; 4University of Napoli Federico II and INFN, Italy; 5University
of Roma Tor Vergata and INFN, Italy; 6INFN Sezione di Bari, Italy; 7CNRS,
INFN Pisa and University of Ferrara, Italy; 8INFN Sezione di Ferrara, Italy;
9
INFN Sezione di Padova, Italy; 10SLAC, USA; 11University of Ferrara and
INFN, Italy; 12INFN Sezione di Pisa, Italy; 13INFN LNF, Italy; 14University of
Padova and INFN, Italy
N14-72 A Prototype Suite for Data-Analysis Management of the SuperB
Experiment
F. Bianchi1, V. Ciaschini2, M. Corvo3, D. Delprete4, A. Di Simone5, G.
Donvito6, A. Fella7, P. Franchini2, F. Giacomini2, A. Gianoli8, S. Longo9,
Russo4, B. Santeramo6, R. Stroili14, L. Tomassetti11
1
University of Torino and INFN, Italy; 2INFN CNAF, Italy; 3CNRS and INFN
Padova, Italy; 4University of Napoli Federico II and INFN, Italy; 5University
of Roma Tor Vergata and INFN, Italy; 6INFN Sezione di Bari, Italy; 7CNRS,
9
N14-73 On-Demand Lung CT Analysis with the M5L-CAD via the
WIDEN Front-End Web Interface and an OpenNebula-Based Cloud
Back-End
D. Berzano1,2, S. Bagnasco1, R. Brunetti1, N. Camarlinghi3,1, P. Cerello1,
S. Chauvie4,1, G. De Nunzio5,1, E. Fiorina1,2, M. E. Fantacci3,1, E. Lopez
Torres6,1
1
Istituto Nazionale di Fisica Nucleare, Italy; 2Universita di Torino, Italy;
3
Universita di Pisa, Italy; 4Ospedale S.Croce e Carle, Italy; 5Universita del
Salento, Italy; 6CEADEN, Cuba
N14-74 Evaluation of the Solid Radioactive Waste Activity in Nuclear
Medicine: Definition of a Shape Factor to Real Geometries
C. R. Brambila, NuclearMed - Fsica Mdica Ltda, Brazil; G. Hoff, Pontifical
Catholic University in Rio Grande do Sul, Brazil
134 Tuesday - NSS Poster Presentations N14-75 LHCb Software and Conditions Database Cross-Compatibility
Tracking: a Graph Driven Approach
M. Cattaneo1, M. Clemencic1, I. Shapoval1,2
1
CERN, Switzerland; 2KIPT, Ukraine
N14-76 Study of the Improvements in Geant4 Toolkit in Brachytherapy
High Dose Rate Dosimetry: Validation and Comparison among
Different Versions of Geant4 Physics List
G. Hoff, Pontifical Catholic University in Rio Grande do Sul, Brazil; V. F.
Cassola, Universidade Federal de Pernambuco, Brazil
N14-77 Validation of MCNPX-PoliMi Fission Models
S. A. Pozzi, S. D. Clarke, W. J. Walsh, E. C. Miller, J. L. Dolan, M. Flaska,
B. M. Wieger, A. Enqvist, University of Michigan, USA; E. Padovani,
Polytechnic of Milan, Italy; J. K. Mattingly, North Carolina State University,
USA; D. L. Chichester, Idaho National Laboratory, USA; P. Peerani, European
Commission Joint Research Centre, Italy
N14-78 Comparison of Geant4 Version 9.3 Simulations with
Experimental from a Prototype Proton CT Scanner
E. Milhoretto1, H. Schelin2, I. Evseev1, S. Paschuk1, F. Silva1, J. C.
Lourenco1, V. Denyak2, O. Yevseyeva3, J. Assis3, R. Lopes4, R. Schulte5, F.
Hurley5
1
Federal University of Technology Parana, Brazil; 2Pele Pequeno Principe Research
Institute, Brazil; 3Polytechnical Institute of the UERJ, Brazil; 4Federal University of
Rio de Janeiro, Brazil; 5Loma Linda Medical University Center, USA
N14-79 Deriving Electron Beam Spectrum from Depth-Charge Curve
by Neural Networks for 6-10 MeV Industrial Accelerators
O. U. Baiev, V. T. Lazurik,
V.N. Karazin Kharkiv National University, Ukraine
N14-80 R&D Activities on Data Management and Storage Solutions for
SuperB Experiment
G. Donvito1, F. Bianchi2, V. Ciaschini3, M. Corvo4, D. Del Prete5, A. Di
Simone6, A. Fella7, P. Franchini3, F. Giacomini3, A. Gianoli8, S. Longo9,
Russo5, B. Santeramo1, R. Stroili14, L. Tomasetti11
1
INFN Sezione di Bari, Italy; 2University of Torino and INFN, Italy; 3INFN
CNAF, Italy; 4CNRS and INFN Padova, Italy; 5University of Napoli Federico
II and INFN, Italy; 6University of Roma Tor Vergata and INFN, Italy; 7CNRS,
9
N14-81 Comparison of Geant4 and MCNPX-PoliMi Induced Fission
Models
S. F. Naeem, S. D. Clarke, S. A. Pozzi, University of Michigan, USA
N14-82 Spectral Analysis for the High Efficiency Multimode Imager
M. L. Galloway1, A. Zoglauer1, M. Amman2, S. E. Boggs1, P. N. Luke2
1
University of California, Berkeley, U.S.A.; 2Lawrence Berkeley National
Laboratory, U.S.A.
N14-83 3DPDF: Open Source Solutions for Incorporating 3D
Information in PDF Files.
N. Graf, SLAC National Accelerator Laboratory, USA
N14-84 mesh2gdml: from CAD to GDML
N14-85 lcsim: a Detector Response Simulation Toolkit
N14-86 Analysis of Coincident Events Using the Classical N-Scatter
Approximation
D. Gunter1,2, A. Haefner3, R. Barnowski3, L. Supic3, S. Huh1, J. Maltz1, L.
Mihailescu1, K. Vetter1,3
1
Lawrence Berkeley National Laboratory, USA; 2Gunter Physics, Inc., USA;
3
University of California, Berkeley, USA
N14-87 Elastic Data Analysis Clusters in the Cloud: Using Scalr for
Turnkey Cluster Deployment of Scalable Data Analysis Clusters
V. Hendrix, Lawrence Berkeley National Lab, USA; D. Benjamin, Duke
University, USA
N14-88 On Aberration of the Cherenkov Radiation Angular
Distribution and Threshold
V. Grichine, P.N. Lebedev Physical Institute of RAS, RF
N14-89 RooStats Statistical Tools for Computing Limits and Discovery
Significance at LHC
L. Moneta, CERN, Switzerland
On behalf of the RooStats Group
N14-90 Simulating Coherent Scatter Diffraction in GEANT4: Results of
Development, Validation and Testing
A. J. Kapadia1,2, P. Sahbaee1,3, M. D. Belley2, A. S. Chawla2, E. Samei1,2, D.
Brady2
1
Duke University Medical Center, USA; 2Duke University, USA; 3NC State
University, USA
N14-91 Simulation of Highly Ionizing Particles in Liquid Argon
Calorimeters
S. Burdin, The University of Liverpool, UK; M. Horbatsch, W. Taylor, York
University, Canada
N14-240 HPGe Validation Measurements of the Geant4 Radioactive
Decay Simulation
S. Hauf1, M. Kuster2, M. Batič3, Z. W. Bell4, D. H. H. Hoffmann1, G.
Hoff5, P. M. Lang1, M. G. Pia3, A. Weckmann1, G. Weidenspointner6,7, A.
Zoglauer8
1
TU Darmstadt, Germany; 2European XFEL GmbH, Germany; 3INFN Sezione
di Genova, Italy; 4Oak Ridge National Laboratory, USA; 5PUCRS, Brazil; 6Max
Planck Institute for Extraterrestrial Physics - MPE, Germany; 7Max Planck
Halbleiterlabor, Germany; 8University of California at Berkeley, USA
Data Acquisition and Analysis Systems
N14-92 Statistical Analysis of Two-Window Counting
S. E. Beach1, T. M. Semkow1,2, A. J. Khan1, A. Bari1, C. J. Bradt1, D. K.
Haines1, U.-F. Syed1
1
New York State Department of Health, USA; 2University at Albany SUNY,
USA
N14-93 An MVT Based All-Digital DAQ for Energy Determination in
Radiation Detection
L. Lin1,2, A. Long1,2,3, P. Xiao1,2, S. Liu1, H. Jiang1, E. Dai1, Q. Xie1,2
1
Huazhong University of Science and Technology, China; 2Wuhan National
Laboratory for Optoelectronics, China; 3Jinggangshan University, China
N14-94 Fast Colors: DWDM at 6.6 Gb/s and Beyond in Real-Time
DAQ Systems
A. Aloisio1,2, F. Ameli2, A. D’Amico2, V. Izzo1,2, V. Bocci2, R. Giordano1,2
1
Universit di Napoli Federico II, Italy; 2INFN, Italy
N14-95 Position Sensitivity in Scintillation Detectors by Pulse Shape
Analysis
M. Ellis, AWE, UK
N14-96 FPGA Based Pulse Shape Discrimination and Coincidence
Energy Measurement for a Phoswich Detector
A. T. Farsoni, B. Alemayehu, A. Alhawsawi, E. M. Becker
Oregon State Universtiy, USA
N14-97 A Multi Channel High Accuracy Real Time DAQ System for the
Fast Neutron Spectrometer Based on GEM-TPC
C. Xiaolei1, H. Dao2, L. Fang1, O. Xiaoping1
1
North China Electirc Power University, China; 2Tsinghua University, China
N14-98 A Multichannel Data Acquisition System for Bolometer
Detectors Based on Microcontroller Cortex M3 Architecture
F. Bianchi, A. Giachero, C. Gotti, M. Maino, G. Pessina
Istituto Nazionale di Fisica Nucleare Sezione di Milano Bicocca, Italy
N14-99 Evaluation of a Modular PET System Architecture with
Synchronization over Data Links
R. J. Aliaga, V. Herrero, J. M. Monzo, R. Gadea, R. J. Colom, A. Ros
Universidad Politecnica de Valencia, Spain
136 Tuesday - NSS Poster Presentations N14-100 Kmax-Based Data Acquisition System for the University of
Kentucky Accelerator Laboratory
B. P. Crider, Univ. of Kentucky, USA; R. B. Piercey, Eastern Kentucky Univ., USA
N14-101 Multifunction Fast Recorder ADC12500 for Plasma
Diagnostics
E. A. Puryga1,2, S. V. Ivanenko1, A. A. Ivanova1,2, A. D. Khilchenko1, A. N.
Kvashnin1
1
Institute of Nuclear Physics SB RAS, Russian Federation; 2Novosibirsk State
Technical University, Russian Federation
N14-102 Gamma-Ray Spectrometer with High Event Processing Rate
A. A. Ivanova1,2,3, S. V. Ivanenko1,3, A. N. Kvashnin1, A. D. Khilchenko1,2,3,
E. A. Puriga1,2,3, A. F. Rovenskikh1, P. V. Zubarev1
1
Budker Institute of Nuclear Physics SB RAS, Russia; 2Novosibirsk State
Technical University, Russia; 3Novosibirsk State University, Russia
N14-103 Data Acquisition System for Thomson Scattering Diagnostic of
ITER Divertor Region
S. Ivanenko1, A. Khilchenko1, P. Zubarev1, A. Kvashnin1, A. Ivanova1,2, E.
Puryga1,2
1
Budker Institute of Nuclear Physics, Russia; 2Novosibirsk State Technical
University, Russia
N14-104 An Automated System for Testing of Readout Electronics of
Position Sensitive X-ray Detectors
P. Maj, A. Goral, P. Grybos, AGH University of Science and Technology, Poland
N14-105 The Design and Implementation of DAQ in Daya Bay Reactor
Neutrino Experiment
Y.-S. Yeh, National Chiao Tung University, Taiwan
On behalf of the Daya Bay Collaboration
N14-106 Design and Development of Data Acquisition System in China
JinPing Deep Underground Laboratory
Q. Du, J. Li, T. Xue, H. Yu, Y. Wu, Q. Yue, K. Kang
Tsinghua University, China
N14-107 Multichannel DAQ System for SiPM Matrices
V. K. Stankova, C. Lacasta, C. Solaz, G. Llosa, M. Trovato, J. E. Gillam, M.
Rafecas, Inst. de Fisica Corpuscular (IFIC), Spain
N14-108 A MTCA.4 Clock and Control System for the EuXFEL 2D
Detectors: Tests and Further Development
E. Motuk, M. Postranecky, M. Warren, M. Wing
University College London, UK
N14-109 Towards the Integration of a Multichannel Fully Digital
Acquisition System for Imaging Applications
A. Abba, F. Caponio, C. Fiorini, A. Geraci, G. Ripamonti
Politecnico di Milano, Italy
N14-110 DAQ System for the Readout of Silicon Pixel Detectors Based
on VataGP7 Front-End ASIC
V. K. Stankova1, E. Chesi2, V. Cindro3, N. H. Clinthorne4, E. Cochran2,
B. Grosicar3, H. Kagan2, K. Honscheid2, C. Lacasta1, C. Brzezinski1, M.
Mikuz3,5, C. Solaz1, A. Student3, P. Weilhammer2, D. Zontar3, G. Llosa1
1
Inst. de Fisica Corpuscular (IFIC), Spain; 2Ohio State University, USA;
3
Joef Stefan Institute, Slovenia; 4University of Michigan, USA; 5University of
Ljubljana, Slovenia
N14-111 A Flexible General Purpose VME Data Acquisition System in a
Kmax Environment
S. Brambilla1, C. Boiano1, S. Riboldi2, F. Camera1,2
1
I.N.F.N., ITALY; 2Universita’ degli Studi di Milano, Italy
N14-112 S-LINK on a Chip for Embedded Applications
V. Izzo1, A. Aloisio1,2, D. Della Volpe1,2, R. Giordano1,2, S. Haas3, S.
Perrella1,2
1
Istituto Nazionale di Fisica Nucleare, sez. Napoli, ITALY; 2Universita’ degli
Studi di Napoli Federico II, ITALY; 3CERN, Switzerland
N14-113 Energy Reconstruction from PileUp Events
E. Stiliaris1,2, A. Pakou3, D. Pierroutsakou4, M. Mazzocco4
1
National & Kapodistrian University of Athens, Greece; 2Institute of Accelerating
Systems & Applications, Greece; 3The University of Ioannina, Greece; 4INFN, Italy
N14-114 RCDAQ: A New Readout System for the CERN SRS Readout
Electronics
M. L. Purschke, Brookhaven National Lab, USA
On behalf of the PHENIX Collaboration
N14-115 Peak-Valley Analysis of Three-Quanta Positron Annihilation:
Validity, Limitation and Optimization
M. P. Chin, CERN, Switzerland; M. Alkhorayef, King Saud University, Saudi
Arabia; N. M. Spyrou, University of Surrey, United Kingdom
N14-116 Mass Production Automated Test System for the NEXT SiPM
Tracking Plane
A. Gil, D. Lorca, M. Querol, J. Rodrguez
IFIC-University of Valencia, Spain
N14-117 Novel Noise Estimation Approach for X-Ray Detectors on
FPGAs
F. Aschauer, Max Planck Institute for Extraterrestrial Physics, Germany; W.
Stechele, Technische Universitaet Muenchen, Germany
N14-118 High Performance Web Applications for Secure System
Monitoring and Control
C. C. W. Robson, S. B. Silverstein, P. Plucinski, C. Bohm
Stockholms universitet, Sweden
N14-119 An Improved Time Synchronization Algorithm on
1000BASE-T Ethernet
F. Nagy, J. Imrek, G. Hegyesi, I. Valastyan, J. Molnar
Institute of Nuclear Research of the Hungarian Academy of Sciences, Hungary
N14-120 Sensor Network Architecture for a Fully Digital and Scalable
SPAD Based PET System
C. Veerappan1, C. Bruschini2, E. Charbon1
1
TU Delft, Netherlands; 2EPFL, Switzerland
Gaseous Detectors
N14-121 Prototype Development of a GEM-TPC with N-Xyter/Xyter
Readout Electronics for the Super-Frs of the Fair Facility
F. Garcia1, R. Janik2, R. Turpeinen1, B. Voss3, V. Kleipa3, A. Prochazka3, J.
Hoffmann3, I. Rusanov3, N. Kurz3, S. Minami3, M. Pikna2, P. Strmen2, R.
Lauhakangas1, E. Tuominen1, B. Sitar2
1
Helsinki Institute of Physics and Department of Physcal Sciences, University of
Helsinki, Finland; 2Comenius University, Slovakia; 3GSI Helmholtzzentrum,
Germany
N14-122 The Performance and Radiation Hardness of the Outer Tracker
Detector for LHCb
N. Tuning, NIKHEF, Netherlands
On behalf of the LHCb Outer Tracker Collaboration
N14-123 Electric Field Modeling of an Ultra-Low-Background
Proportional Counter
A. Seifert, C. E. Aalseth, A. R. Day, E. W. Hoppe, M. E. Keillor, E. K. Mace,
C. T. Overman, M. E. Panisko, B. A. VanDevender, R. M. Williams
N14-124 Study of VUV Detector Based on Thinner THGEM
W. Xie, Y. Li, J. Li, Y. Li, Q. Yue, Tsinghua University, China
N14-125 MWPC Gain Monitoring Through Time Measurements
G. Passaleva, Istituto Nazionale di Fisica Nucleare - Florence, Italy; D. Pinci,
Istituto Nazionale di Fisica Nucleare - Rome1, Italy
N14-126 Systematic Study of RPC Performances in Polluted or Varying
Gas Mixtures Compositions: an Online Monitor System for the RPC Gas
Mixture at LHC
B. Mandelli1,2, M. Capeans2, R. Guida2
1
University of Oslo, Norway; 2CERN, Switzerland
N14-127 Results from the First Operational Period of the CF4
Recuperation Plant for the Cathode Strip Chambers Detector at the
CMS Experiment
R. Guida1, M. Capeans1, F. Hahn1, S. Haider1, B. Mandelli1,2
1
CERN, Switzerland; 2University of Oslo, Norway
138 Tuesday - NSS Poster Presentations N14-128 Induced Charge Profile in Glass RPC Operated in Avalanche
Mode
S. Narita, Iwate University, Japan; Y. Hoshi, Tohoku Gakuin Unversity,
Japan; K. Neichi, Tohoku Gakuin University, Japan; A. Yamaguchi, Tohoku
University, Japan
N14-129 The Large-Area Gamma-Ray Imaging Sensor with GEMs
T. Fusayasu1, S. Koshimuta2, M. Inuzuka3, A. Nukariya4, K. Abe2, Y.
Tanaka1, H. Hamagaki4
1
Nagasaki Institute of Applied Science, Japan; 2Scienergy Co., Ltd., Japan;
3
National Research Institute for Cultural Properties, Japan; 4University of Tokyo,
Japan
N14-130 Development of GEM with Glass Insulator
Y. Sekiguchi, H. Hamagaki, T. Gunji, University of Tokyo, Japan; T.
Tamagawa, RIKEN, Japan
N14-131 New Development of μ-PIC with Resistive Cathode and
Capacitive Readout
A. Ochi, Y. Homma, H. Komai, Y. Edo, T. Yamaguchi, Kobe University,
Japan; R. D. Oliveira, CERN, Switzerland
N14-132 Development of a Common Gas Analysis Approach for the Gas
Systems of All the Experiments at the CERN Large Hadron Collider
R. Guida1, M. Capeans1, F. Hahn1, S. Haider1, B. Mandelli1,2
1
CERN, Switzerland; 2University of Oslo, Norway
N14-133 X-Ray Imaging Detector Based on a 2D Sensitive THCOBRA
with Resistive Line Readout
A. L. M. Silva1, C. D. R. Azevedo1, L. Carramate1, T. Lopes1, R. de Oliveira2,
J. F. C. Veloso1
1
University of Aveiro, Portugal; 2CERN, Switzerland
N14-134 GEM Detectors in the CERN Experimental Areas
S. Duarte Pinto, P. Carrire, J. Spanggaard, G. Tranquille
CERN, Switzerland
N14-135 Ion Back Flow Reduction in a THGEM Based Detector for
Single Photons
C. A. Santos1,2, Q. Lui3, S. Levorato4,2, S. S. Dasgupta2, F. Tessarotto2, S.
Dalla Torre2, J. F. C. A. Veloso1
1
University of Aveiro, Portugal; 2INFN - Sezione di Trieste, Italy; 3Graduate
University of Chinese Academy of Science, China; 4University of Trieste, Italy
N14-136 End-Point Measurement of the Ionization Yield at 7 keV for
Nuclear Recoils in Liquid Argon
M. Foxe1,2, A. Bernstein2, J. Coleman3, C. Hagmann2, T. H. Joshi4,2, I.
Jovanovic1, K. Kazkaz2, K. Mavrokoridis3, V. Mozin2, S. V. Pereverzev2, S.
Sangiorgio2, P. Sorensen2
1
The Pennsylvania State University, USA; 2Lawrence Livermore National
Laboratory, USA; 3University of Liverpool, UK; 4University of California:
Berkeley, USA
N14-137 Test Beam Results of New Full-Scale Prototypes for CMS
High-Eta Muon System Future Upgrade
S. Colafranceschi, CERN, Switzerland
N14-138 Aging Test of the CMS MPGD Prototype at the CERN Gamma
Irradiation Facility (GIF)
J. A. Merlin, University of Strasbourg, France
High Density Detector Processing and
Interconnect Technologies
N14-139 Algorithms for Cooperative and Distributed Radiation Source
Detection
C. A. Steer, G. Hurst, AWE, UK
N14-140 Analysis of SOI Technologies Based on the TRAPPISTe
Prototype Measurements
P. L. Alvarez, E. Martin, C. Ferrer, Universitat Autonoma de Barcelona, Spain;
L. Soung Yee, E. Cortina, Universite Catholique de Louvain, Belgium
N14-141 Development of Monolithic Detector Systems Within the
TRAPPISTe Project
P. L. Alvarez, E. Martin, C. Ferrer, Universitat Autonoma de Barcelona, Spain;
L. Soung Yee, E. Cortina, Universite Catholique de Louvain, Belgium
High Energy Physics Instrumentation (incl.
large detection systems)
N14-142 New Photomultiplier Active Base for Hall C Jefferson Lab
Lead Tungstate Calorimeter
V. Popov, Thomas Jefferson National Accelerator Facility, USA; H. Mkrtchyan,
A. I. Alikhanyan National Science Laboratory, Armenia
N14-143 Commissioning of the Testbeam Prototype of the CALICE Tile
Hadron Calorimeter
M. Reinecke, DESY, Germany
On behalf of the CALICE Collaboration
N14-144 The CHarged ANTIcounter for the NA62 Experiment at
CERN
P. Massarotti1,2, F. Ambrosino1,2, T. Capussela1,2, D. Di Filippo1,2, M.
Napolitano1,2, V. Palladino3, L. Roscilli2, G. Saracino1,2, C. Paglia4, D.
Tagnani4, G. Corradi4
1
Universit degli studi di Napoli, Italy; 2INFN sez. Napoli, Italy; 3INFN sez.
Roma, Italy; 4Laboratori Nazionali di Frascati, Italy
N14-145 Construction and Commissioning of a an Ultra-Granular
Hadronic Calorimeter Prototype
I. B. Laktineh, IPNL-UCBL-IN2P3, France
On behalf of the Calice collaboration/ILD concept collaboration
N14-146 Experience with Constructing and Operating the World’s
Largest Silicon-Based Electromagnetic Calorimeter - the CMS Preshower
S.-W. Li, National Central University, Taiwan
N14-147 Calibration of the CMS Electromagnetic Calorimeter at the
LHC
F. De Guio, Universita’ degli Studi di Milano-Bicocca and INFN, Italy
On behalf of the CMS collaboration
N14-148 The DEPFET Multi Chip Module for Belle II
L. Andricek1,2, 1MPI fuer Physik, Germany; 2MPI Halbleiterlabor, Germany
On behalf of the DEPFET Collaboration
N14-149 Construction of a Large Scale Prototype of a SiW
Electromagnetic Calorimeter for a Future Lepton Collider
R. Poeschl, LAL Orsay, France
N14-150 The LHCb Silicon Tracker
A. A. Gallas Torreira, University of Santiago de Compostela, Spain
On behalf of the LHCb Silicon Tracker group
N14-151 An Ultra-Pure and Challenging Gas System for Studying the
Formation of Aerosols and Clouds in the CLOUD Experiment at the
CERN PS
R. Guida, CERN, Switzerland
On behalf of the CLOUD collaboration
N14-152 Response of the CALICE Sc-W Electromagnetic Calorimeter
Physics Prototype to Electrons
M. A. Khan, Kyungpook National University, South Korea
N14-153 A Diode-Pumped DP2-447 Blue Laser for Monitoring CMS
Lead Tungstate Crystal Calorimeter at the LHC
K. Zhu, CALTECH, USA
On behalf of the CMS ECAL group
N14-154 3D Silicon Sensors- Large Area Production, QA and
Development for the CERN ATLAS Experiment Pixel Sensor Upgrade
A. Kok1, M. Boscardin2, G.-F. Dalle Betta3, C. Da Via4, G. Darbo5, C.
Fleta6, C. Gemme5, P. J.-P. Grenier7, S. Grinstein6, T.-E. Hansen1, J. Hasi7,
C. Kenney7, S. I. Parker8, G. Pellegrini6, E. Vianello2, N. Zorzi2
1
SINTEF, Norway; 2Fondazione Bruno Kessler, Italy; 3University of Trento,
140 Tuesday - NSS Poster Presentations Italy; 4The University of Manchester, UK; 5INFN, Italy; 6Centro National de
Microelectronica, Spain; 7SLAC National Accelerator Laboratory, USA; 8The
University of Hawaii, USA
N14-155 New Pixel Detectors for the Upgrade of the ALICE Inner
Tracking System
C. Cavicchioli, CERN, Switzerland
On behalf of the ALICE Collaboration
N14-156 Optical Properties of Radiator Bar Prototypes for the PANDA
Barrel DIRC
G. Kalicy1,2, D. Lehmann1, K. Peters1,2, G. Schepers1, C. Schwarz1, J.
Schwiening1
1
GSI, Germany; 2Goethe University, Germany
N14-157 Construction and Test of New sMDT Chambers for the
Upgrade of the ATLAS Muon Spectrometer
H. K. Kroha, B. Bittner, J. Dubbert, O. Kortner, A. Manfredini, S. Nowak,
R. Richter, P. Schwegler, D. Zanzi, Max-Planck-Institut fuer Physik, Germany;
O. Biebel, R. Hertenberger, Ludwig-Maximilians University, Germany
N14-158 Design and Fabrication of Sensor Prototypes for the End-Cap
Tracker of the ATLAS Upgrade
M. Ullan1, V. Benitez1, C. Lacasta2, G. Pellegrini1, C. Fleta1, C. Garcia2, M.
Lozano1
1
Centro Nacional de Microelectronica (CNM-CSIC), Spain; 2Instituto de Fsica
corpuscular (IFIC-CSIC), Spain
N14-159 Reliability Analysis of a Low Voltage Power Supply Design for
the Front-End Electronics of the Atlas Tile Calorimeter
A. Senthilkumaran1, G. Drake2, A. Gopalakrishnan1, S. Mahadik1, B.
Mellado1, J. Proudfoot2
1
University of Wisconsin - Madison, USA; 2Argonne National Laboratory, USA
N14-160 The Muon Trigger Upgrade with Resistive Plate Chambers in
PHENIX
M. S. Daugherity, Abilene Christian University, USA
N14-161 Fast Calibration UV LED System for CALICE Scintillator
based Tile Hadron Calorimeter
I. Polak, Institute of Physics ASCR, Prague, Czech republic
On behalf of the CALICE
N14-162 Performance of a Large Area Silica Aerogel Cherenkov Counter
M. Wada-Katsumi1,2, Y. Hasegawa1, H. Kawai1, K. Marubashi1, K. Mase1, T.
Nakano3, H. Nakayama4, M. Tabata1,5, M. Yosoi3
1
Chiba University, Japan; 2National Institute of Radiological Sciences, Japan;
3
Osaka University, Japan; 4Kisarazu National School of Technology, Japan;
5
Japan Aerospace Exploration Agency, Japan
N14-163 Monitoring and Correcting for Response Changes in the CMS
Lead-Tungstate Electromagnetic Calorimeter
A. Thea, ETH Zuerich, Switzerland
N14-164 Pixel Senor and Module Development for the HL-LHC ATLAS
Pixel System
R. L. Bates, C. Buttar, A. Blue, A. G. Stewart, K. Doonan, J. Ashby, The
University of Glasgow, UK; G. Casse, P. Dervan, D. Forshaw, I. Tsurin, The
University of Liverpool, UK; J. Pater, S. Brown, The University of Manchester, UK
Instrumentation for Bio-Medical Research
N14-165 A Real-Time, Large Area, High Space Resolution Particle
Radiography System
D. Lo Presti1, G. V. Russo1, N. Randazzo2, V. Sipala3, E. Leonora2, F.
Longhitano2, P. Cristina1, G. A. P. Cirrone2, F. Romano2, S. Aiello2
1
University of Catania, Italy; 2Istituto Nazionale di Fisica Nucleare, Italy;
3
University of Sassari, Italy
N14-166 PET-TOF Study of Silicon Photomultipliers with DRS4
Readout.
A. I. Ronzhin, S. Los, M. Martens, P. Murat, E. Ramberg, Fermi National
Accelerator Laboratory, USA; H. Kim, C.-M. Kao, C.-T. Chen, University
of Chicago, USA; K. Niessen, SUNY of Buffalo, USA; A. Zatserklianiy,
University of Puert Rico, USA; M. Mazzillo, B. Carbone, G. Condorelli, G.
Fallica, A. Piana, D. Sanfilippo, G. Valvo, STMicroelectronic, Italy; S. Ritt,
Paul Scherrer Institute, Switzerland
N14-167 A Time of Arrival Estimator Based on Multiple Timestamps for
Digital PET Detectors
L. H. C. Braga, L. Gasparini, D. Stoppa,
Fondazione Bruno Kessler (FBK), Italy
N14-168 Towards a High-Dynamic Dose-Range Irradiation Setup for
Radiobiology and Radiophysiology
S. Ghithan1,2, F. Alves3,4, R. Ferreira Marques1,2, F. Fraga1,2, H. Simões1, P.
Crespo1
1
LIP - Laboratório de Instrumentação e Física Experimental de Partículas,
Portugal; 2FCTUC - Physics Department, Faculty of Science and Technology,
University of Coimbra, Portugal; 3ICNAS - Instituto de Ciências Nucleares
Aplicadas à Saúde, Portugal; 4ESTeSC - Escola Superior de Tecnologia da Saúde
de Coimbra, Portugal
N14-169 Depth of Interaction Estimation Using Artificial Neural
Network for Continuous Crystal PET Detector
W. Yonggang, C. Xinyi, L. Deng
N14-170 A Simple and Robust Method for Fast Crystal Identification
X. Wang, G. Hu, H. Zhang, Tsinghua University, China
N14-171 Beam Profile Monitoring System for Proton Therapy and
Monte Carlo Modeling of Proton Beam Longitudinal Development in
Water in 100-400MeV
C.-H. Lin, P.-K. Teng, M.-L. Chu, F.-X. Chang, Academia Sinica, Taiwan;
A. E. Chen, S.-Y. Cai, P.-R. Tsai, Y.-W. Tsai, National Central University,
Taiwan; C.-H. Wang, National United University, Taiwan; C.-W. Hsieh,
National Chiayi University, Taiwan; T.-S. Duh, J.-H. Lee, Institute of Nuclear
Energy Research, Taiwan; C.-C. Lee, S.-J. Dai, T.-C. Chao, C.-J. Tung, Chang
Gung University, Taiwan
N14-172 Toward the Development of a Fully CMOS Single-Photon
Detector for PET Systems: a Montecarlo Simulator as an Optimization
Tool to Support the Sensor Design
L. Gasparini1, L. H. C. Braga1, B. Jtkos2, E. Lőrincz2, D. Stoppa1
1
Fondazione Bruno Kessler, Italy; 2Budapest University of Technology &
Economics, Hungary
N14-173 X-Ray Detector Made of Plastic Scintillators and WLS
Fiber for Real-Time Dose Distribution Monitoring in Interventional
Radiology
F. Nishikido1, T. Moritake2, S. Kishimoto3, T. Yamaya1
1
National Institute of Radiological Sciences, Japan; 2Tukuba University, Japan;
3
High Energy Accelerator Research Organization, Japan
N14-174 Experimental Verification of Beam Position and Size
Determination Using Scattered Charged Particles for Real Time Quality
Assurance in Proton Hadrontherapy
M. Battaglia, SCIPP - UCSC and LBNL, USA; V. Bashkirov, F. Hurley, R.
Schulte, Loma Linda University Medical Center, USA
N14-175 Highly Integrated LuAG-APD Time over Threshold PET
Detector Using Pulse Train Method
K. Shimazoe, H. Takahashi, T. Orita, Y. Nakamura
N14-176 Neutral and Charged Particles’ Flux Measurement for Released
Dose Imaging in Hadrontherapy
S. Fiore1, C. Agodi2, G. Battistoni3, F. Bellini1,4, G. A. P. Cirrone2, F.
Collamati1,4, G. Cuttone2, E. De Lucia5, M. De Napoli2, A. Di Domenico1,4,
R. Faccini1,4, F. Ferroni1,4, P. Gauzzi1,4, E. Iarocci5,1, M. Marafini1,6, I.
Mattei5,7, S. Muraro3, A. Paoloni5, V. Patera5,1, L. Piersanti5,1, F. Romano2,6,
A. Sarti5,1, A. Sciubba5,1, E. Vitale3, C. Voena1,4
1
Sapienza Universita’ di Roma, Italy; 2Laboratori Nazionali del Sud dell’INFN,
Italy; 3INFN Sez. di Milano, Italy; 4INFN Sez. di Roma, Italy; 5Laboratori
Nazionali di Frascati dell’ INFN, Italy; 6Museo Storico della Fisica e Centro
Studi e Ricerche Enrico Fermi, Italy; 7Universita’ degli Studi di Roma Tre, Italy
142 Tuesday - NSS Poster Presentations N14-177 Development of a Proton Computed Tomography System for
Pre-Clinical Tests
M. Scaringella1, M. Brianzi2, M. Bruzzi1,2, M. Bucciolini2,1, G. A. P. Cirrone2,
C. Civinini2, G. Cuttone2, D. Lo Presti2,3, S. Pallotta2,1, C. Pugliatti2,3, N.
Randazzo2, F. Romano2,4, V. Sipala5,2, C. Stancampiano2,3, C. Talamonti2,1,
M. Tesi1, M. Zani2,1
1
University of Florence, Italy; 2INFN, Italy; 3University of Catania, Italy;
4
Centro Studi e Ricerche e Museo Storico della Fisica, Italy; 5University of
Sassari, Italy
N14-178 Development of Prompt Gamma Measurement System Based
on CsI(Tl) Detector Array for Proton Beam Range Verification
H. R. Lee1, J. H. Park1, S. Kim2, C. H. Kim1
1
Hanyang University, Korea; 2Hanyang University hospital, Korea
N14-179 High Dynamic Range X-Ray Flux Monitoring System
T. Hofmann1, M. Hertlein1,2, F. Nachtrab1,2, N. Uhlmann1
1
Fraunhofer Institute for Integrated Circuits IIS, Germany; 2University ErlangenNuremberg, Germany
N14-180 Study of the Transient Response of PI/a-Se Photodetectors for
Indirect Conversion Medical Imaging
S. Abbaszadeh, N. Allec, K. S. Karim
University of Waterloo, Canada
N14-181 3D Beam Monitoring for 12C Radiotherapy by Tracking of
Secondary Ions Using the Timepix Detector
K. Gwosch1, B. Hartmann1,2, J. Jakubek3, S. Pospisil3, O. Jaekel1,2,4, M.
Martisikova1,2
1
German Cancer Research Center, Germany; 2Heidelberg University Hospital,
Germany; 3Czech Technical University in Prague, Czech Republic; 4Heidelberg
Ion-Beam Therapy Center, Germany
N14-182 Novel Time over Threshold Based Readout Method for MRI
Compatible Small Animal PET Detector
I. Valastyan1,2, J. Gal1, G. Hegyesi1, G. Kalinka1, F. Nagy1, B. Kiraly1, J.
Imrek1, J. Molnar1, M. Colarieti-Tosti2, Z. Szabo3, L. Balkay3
1
Institute of Nuclear Research of the Hungarian Academy of Sciences, Hungary;
2
Royal Institute of Technology, Sweden; 3University of Debrecen, Hungary
N14-183 Radiation Hardness of a Large Area CMOS Active Pixel Sensor
for Bio-Medical Applications
M. Esposito1, T. Anaxagoras2,3, O. Diaz1, K. Wells1, N. M. Allinson2
1
University of Surrey, U.K.; 2University of Lincoln, U.K.; 3ISDI Ltd (Image
sensor design and innovation), U.K.
N14-184 A Monolithic 180 Nm CMOS Dosimeter for in Vivo Medical
Applications
E. G. Villani1, M. Crepaldi2, D. DeMarchi2, A. Gabrielli3, A. Khan4, E.
Pikhay5, Y. Roizin5, A. Rozenfeld6, Z. Zhang1
1
Rutherford Appleton Laboratory, UK; 2IIT,Istituto Italiano di Tecnologia,
Politecnico di Torino, Italy; 3University of Bologna and INFN, Italy; 4Brunel
University, UK; 5TowerJazz Semiconductor Ltd, Israel; 6CMRP, University of
Wollongong, Australia
N14-185 A Laboratory PET Scanner with Silicon Detectors Segmented
to 1 mm Detection Cells
A. Studen1, K. Brzezinski2, E. Chesi3, V. Cindro1, N. H. Clinthorne4, B.
Grosicar1, K. Honscheid3, S. Huh4, H. Kagan3, C. Lacasta2, G. Llosa2, M.
Mikuz1, M. Grkovski1, S. Smith3, V. Stankova2, P. Weilhammer3, D. Zontar1
1
Josef Stefan Institute, Slovenia; 2Instituto de Fisica Corpuscular, Spain; 3Ohio
State University, USA; 4University of Michigan, USA
N14-186 Monte Carlo Simulations for the Development a Clinical
Proton CT Scanner
D. Steinberg, S. Macafee, UC Santa Cruz, USA
N14-187 Development and Characterization under Intensity Modulated
Radiotherapy Beam of a Large Area Bidimensional Dosimeter Made
with P-Type Epitaxial Silicon
M. Bruzzi1, M. Scaringella1, C. Talamonti1, M. Casati2, D. Menichelli3, M.
Bucciolini1
1
INFN and University of Firenze, Italy; 2Azienda Ospedaliera Careggi, Italy;
3
IBA Dosimetry GmbH, Germany
N14-188 Ethernet-Based Flash ADC for a Plant PET Detector System
S. Lee, A. G. Weisenberger, J. McKisson, J. E. McKisson, B. J. Kross,
H. Dong, Thomas Jefferson National Accelerator Facility, US; M. F. Smith,
University of Maryland, US; C. R. Howell, C. D. Reid, Duke University, US
N14-189 Calibration of a Prototype Proton CT Scanner
R. F. Hurley, V. A. Bashkirov, Loma Linda University, USA; R. W. Schulte,
A. J. Wroe, A. Ghebremedhin, P. Koss, B. Patyal, Loma Linda University
Medical Center, USA; H. Sadrozinski, University of California, Santa Cruz,
USA; V. Rykalin, G. Coutrakon, Northern Illinois University, USA
N14-190 PhytoPET: Design and Initial Results of Modular PET for
Plant Biology
S. Lee, A. G. Weisenberger, J. McKisson, J. E. McKisson, B. J. Kross,
Thomas Jefferson National Accelerator Facility, US; M. F. Smith, University of
Maryland, US; C. R. Howell, C. D. Reid, Duke University, US
N14-191 Monte Carlo Estimation of Effects of Secondary Particles on
in-Beam OpenPET Imaging
Y. Hirano, E. Yoshida, F. Nishikido, N. Inadama, H. Tashim, H. Ito, T.
Yamaya, National Institute of Radiological Sciences, Japan
N14-192 Development of a Range Counter with SiPM Readout for
Proton CT
A. Zatserklyaniy, V. Feng, R. P. Johnson, J. Lustig-Yaeger, S. Macafee,
T. Plautz, A. Plumb, H. F. F-W. Sadrozinski, D. Steinberg, University of
California Santa Cruz, United States; V. Bashkirov, F. Hurley, R. Schulte,
Loma Linda University Medical Center, United States
N14-193 Tissue Equivalency of Diamond for Proton and Alpha Particles
Typical of Galactic Cosmic Rays
J. Davis1, S. Guatelli1, M. Petasecca1, M. Lerch1, Z. Kuncic2, A. B.
Rosenfeld1
1
University of Wollongong, Australia; 2University of Sydney, Australia
N14-194 SOI Microdosimetry for In-Field and Out-of-Field Hadron
Therapy Treatment Fields
D. A. Prokopovich1, J. Livingstone2, M. Martisikova3, H. Yasuda4, M. L. F.
Lerch2, M. Petasecca2, M. I. Reinhard1, A. B. Rosenfeld2
1
Australian Nuclear Science and Technology Organisation, Australia; 2University
of Wollongong, AUSTRALIA; 3German Cancer Research Center DKFZ,
Germany; 4National Institute of Radiological Sciences, Japan
N14-195 High Resolution Silicon Detector Characterization of the
Valley Dose Between Synchrotron Generated X-Ray Microbeams
M. L. F. Lerch1, M. Petasecca1, A. Cullen1, H. Requardt2, E. Bruer-Krisch2,
A. Bravin2, S. Guatelli1, V. Pervertaylo3, P. E. Simmonds1, A. B. Rozenfeld1
1
University of Wollongong, Australia; 2Eurpoean Synchrotron Radiation Facility,
France; 3SPA BIT, Ukraine
N14-196 Silicon Sensors for Advanced QA in Contemporary Radiotherapy
M. Petasecca1, I. Fuduli1, J. Wong2, N. Hardcastle3, M. Carolan4, P.
Metcalfe1, W. Tome5, M. L. F. Lerch1, A. Rosenfeld1
1
University of Wollongong, Australia; 2Wollongong Hospital, Australia;
3
University of Malaya, Malaysia; 4Peter McCallum Cancer Centre, Australia;
5
University of Wisconsin-Madison, USA
New Concepts in Solid-State Detectors
N14-197 U3DTHIN - Ultra Thin 3d Silicon Detector for Ion Detection
and ITER TOKAMAK
F. Garcia, Helsinki Institute of Physics and Department of Physcal Sciences,
University of Helsinki, Finland; G. Pellegrini, M. Lozano, J. Rodriguez,
C. Guardiola, C. Fleta, D. Quirion, Instituto de Microelectrnica de
Barcelona,(IMB-CNM, CSIC), Spain
N14-198 Reduction of Scribing Damage on a Silicon Device Sidewall
with a XeF2 Etch Step
M. Christophersen1, V. Fadeyev2, B. F. Phlips1, H. F. W. Sadrozinski2
1
U.S. Naval Research Laboratory, USA; 2Santa Cruz Institute for Particle
Physics, USA
144 Tuesday - NSS Poster Presentations N14-199 A Study to Enhance X-Ray Measuring Efficiency of Organic
Photodiode
E. Takada, A. Takada, K. Fujii, Toyama National College of Technology,
Japan; Y. Namito, High Energy Accelerator Research Organization, Japan; T.
Nakamura, Tohoku University, Japan
N14-200 Vertically Integrated CMOS Active Pixel Sensors for Tracking
Applications in HEP Experiments
D. Passeri1,2, L. Servoli2, S. Meroli2, D. Magalotti2, P. Placidi1,2, A. Marras3
1
University of Perugia, Italy; 2Istituto Nazionale di Fisica Nucleare, Sezione di
Perugia, Italy; 3Deutsches Elektronen-Synchrotron, Germany
N14-201 Second Chronopixel Detector Prototype
N. B. Sinev1, C. Baltay2, J. E. Brau1, W. Emmet2, D. Rabinovitz2, D. Strom1
1
University of Oregon, USA; 2Yale University, USA
N14-202 Alpha Response of Graphene-Based Radiation Detectors
E. Cazalas1, I. Childres2, A. Majcher1, Y. P. Chen2, I. Jovanovic1
1
Penn State University, United States; 2Purdue University, United States
N14-203 Ultra Low Noise CCD Readout Techniques for Dark Matter
and Neutrino Detection
E. J. Ramberg, Fermi National Accelerator Laboratory, USA
On behalf of the DAMIC collaboration
N14-204 Layout and Process Improvements to Double-Sided Silicon 3D
Detectors Fabricated at FBK
M. Povoli1,2, G.-F. Dalla Betta1,2, A. Bagolini3, M. Boscardin3, G.
Giacomini3, F. Mattedi3, N. Zorzi3
1
University of Trento, Italy; 2INFN Padova (Gruppo collegato di Trento), Italy;
3
N14-205 Monolithic Active Pixel Matrix with Binary Counters
(MAMBO) ASIC, Using a Nested Well Structure to Decouple the
Detector from the Electronics
F. F. Khalid, G. Deptuch, S. Holm, A. Shenai, R. J. Yarema
Fermi National Accelerator Laboratory, USA
N14-206 New Si Drift Detectors Arrays with Customer-Design, Low
Current (Low Heat, Low Power) Spiral Biasing Adaptor and DoubleMetal Interconnections
Z. Li, W. Chen, Brookhaven National Lab, USA
Semiconductor Tracking and Spectroscopy
Detectors
N14-207 Tuning and Application of High-Efficiency, Low-Background,
and Low-Energy Sensitive Gamma-Ray Spectrometer
A. J. Khan1, T. M. Semkow1,2, D. K. Haines1, C. J. Bradt1, S. E. Beach1, M.
E. Kitto1,2, A. Bari1, J. Colaresi3
1
New York State Department of Health, USA; 2University at Albany SUNY,
USA; 3Canberra Industries, USA
N14-208 Overview of the ATLAS Insertable B-Layer (IBL) Project
C. Troncon, INFN Milano, Italy
N14-209 Analysis of CMOS MAPS Epitaxial Layer
M. Fu, Z. Tang, Dalian University of Technology, P. R. China
N14-210 Final Characterization of the ATLAS IBL Detector Modules
with 241Am During the Construction Phase
B. Mandelli1,2, 1University of Oslo, Norway; 2CERN, Switzerland
On behalf of the ATLAS IBL collaboration
N14-211 Analysis of the Drift Speed of the Silicon Drift Detector for
ALICE Experiment
S. Kushpil, Nuclear Physics Institute ASCR, Czech Republic
On behalf of the ALICE Collaboration
N14-212 Status of the ATLAS Pixel 2013/14 Services and Readout
Upgrade
D. Dobos, CERN, Switzerland
N14-213 An EUDET/AIDA Pixel Beam Telescope for Detector
Development
H. Perrey, DESY, Germany
On behalf of the AIDA Consortium
N14-214 Conceptual Design of a Radial Vane Silicon Tracker for a
New Measurement of the Muon Anomalous Magnetic Moment g-2 and
Electric Dipole Moment at J-PARC
K. Ueno1, H. Iinuma2, M. Iwasaki1, T. Kakurai2, T. Kohriki2, T. Mibe2, O.
Sasaki2, N. Saito2
1
RIKEN, Japan; 2KEK, Japan
N14-215 Test Beam Results with a Portable, High Rate Telescope System
Based on the Alibava System
G. Casse, O. Lodge Lab., University of Liverpool, UK
On behalf of the Alibava collaboration
N14-216 Pixel Sensor Charge Collection Efficiency Tomography
P. Collins1, D. Dobos1, D. Hynds2, J. Jentzsch1, D. Muenstermann1, H.
Pernegger1
1
CERN, Switzerland; 2University of Glasgow, Scotland
N14-217 Mapping the Amplitude and Position Response of DSSSD
with Monochromatic Single Protons
L. Acosta1, F. Amorini1, A. Anzalone1, L. Auditore1,2, C. Boiano1, G.
Cardella1, L. Carraresi3,1, A. Castoldi4,1, A. Chbihi5, E. De Filippo1, L.
Francalanza1,6, E. Geraci6,1, S. Giani’1,6, C. Guazzoni4,1, E. La Guidara1,7,
G. Lanzalone1,8, I. Lombardo1,9, S. Lo Nigro6,1, D. Loria1,2, C. Maiolino1,
I. Martel10, T. Minniti1,2, G. V. Montemurro1,4, A. Pagano1, E. V. Pagano1,6,
M. Papa1, T. Parsani4,1, S. Pirrone1, G. Politi1,6, F. Porto1,6, F. Riccio4, F.
Rizzo1,6, P. Russotto1,6, A. M. Sanchez Benitez10, J. A. Duenas10, R. Berjillos10,
S. Santoro1,2, F. Taccetti1, A. Trifiro’1,2, M. Trimachi1,2, G. Verde1, M.
Vigilante1,9, P. Zambon4,1
1
INFN, Italy; 2Universita’ degli Studi di Messina, Italy; 3Universita degli Studi
di Firenze, Italy; 4Politecnico di Milano, Italy; 5GANIL, France; 6Universita’
degli Studi di Catania, Italy; 7Centro Siciliano di Fisica Nucleare e Struttura
della Materia, Italy; 8Universita’ KORE, Italy; 9Universita’ di Napoli, Italy;
10
Universidad de Huelva, Spain
N14-218 An Electrostatic System for Measurement of Radon in
Buildings
C. Frojdh, A. Frojdh, G. Thungstrom, S. Petersson, Mid Sweden University, Sweden
N14-219 Development of Silicon Strip Sensors and Radiation Hardness
Studies for the PANDA MVD
T. Quagli1, H.-G. Zaunick2, R. Schnell2, D. Deermann3, J. Tummo2
1
Justus-Liebig-Universitaet Giessen, Germany; 2Rheinische Friedrich-WilhelmsUniversitaet Bonn, Germany; 3Forschungszentrum Juelich, Germany
N14-220 Monolithic Active Pixel Silicon Detectors for Future Electron
Ion Colliders: Status and Plans
E. C. Aschenauer1, B. Cole2, B. Di Ruzza1, E. Hughes2, M. Winter3
1
Brookhaven National Laboratory, USA; 2Columbia University, USA; 3Institut
Pluridisciplinaire Hubert Curien & CNRS, France
Trigger and Front-end Systems
N14-221 The Design of High Speed Trigger Multiplexer Module for the
Belle II Cylindrical Drift Chamber Detector
C.-H. Wang, S.-M. Liu, Y.-S. Teng, National United University, Taiwan
N14-222 Multi-Gigabit Wireless Data Transfer at 60 GHz
H. K. Soltveit1, R. Brenner2, A. Schoening1, D. Wiedner1
1
University of Heidelberg, Germany; 2University of Uppsala, Sweden
N14-223 Waveform Sampler Module for J-PARC TREK Experimen
Y. Igarashi, M. Saito, High Energy Accelerator Research Org.(KEK), Japan
N14-224 TIGER - a Fast Trigger Processor for the COMPASS-II Recoil
Proton Detector
S. Schopferer, T. Baumann, M. Buechele, H. Fischer, M. Gorzellik, F.
Herrmann, P. Joerg, K. Koenigsmann, T. Kunz, C. Michalski, C. Schill, T.
Szameitat, University of Freiburg, Germany
146 Tuesday - NSS Poster Presentations N14-225 The ATLAS Trigger Menu: Design and Performance
C. Bernius, Louisiana Tech University, USA
N14-226 Performance of the ATLAS Level-1 Calorimeter Trigger in
High Luminosity Proton-Proton Collisions at the LHC
T. Childers, CERN, Switzerland,
N14-227 FastTracker Performance Using the New Variable Resolution
Associative Memory for Atlas
T. Childers, CERN, Switzerland
N14-228 Instrumentation of a Level-1 Track Trigger in the ATLAS
Experiment for the High Luminosity LHC Operation
T. Childers, CERN, Switzerland, On behalf of the ATLAS collaboration
N14-229 The ATLAS Muon Trigger Performance in Pp Collisions at
Sqrt(s)=8 TeV in Year 2012 Runs
N14-230 Performance and Improvements of the ATLAS Jet Trigger
System
N14-231 The ATLAS Muon Calibration Stream : Design, Performance,
Evolution
N14-232 An Upgraded ATLAS Central Trigger for 2014 LHC
Luminosities.
M. Kaneda, CERN, Switzerland
N14-233 Test Results of the Na62 Liquid Krypton Electromagnetic
Calorimeter Level 0 Trigger Processor
V. Bonaiuto1, L. Federici1, A. Fucci2, G. Paoluzzi2, A. Salamon2, G. Salina2,
E. Santovetti1, F. Sargeni1
1
Universita’ degli Studi di Roma Tor Vergata, Italy; 2INFN Sezione di Roma Tor
Vergata, Italy
N14-234 A PVT Compensated Programmable Time to Digital Converter
in a 60nm FPGA
C. Seaver, K. Beasley, Siemens Healthcare, USA; S. Magoon, University of
Tennessee, USA
N14-235 The Topological Trigger System for the VERITAS Upgrade
B. J. Zitzer, Argonne National Laboratory, United States
On behalf of the VERITAS Collaboration
N14-236 A Hybrid Readout System for the ATLAS TileCal Phase 2
Upgrade Demonstrator
C. Bohm, University of Stockholm, Department of physics, Sweden
On behalf of the on behalf of the ATLAS Tile Calorimeter System
N14-237 Performance Measurements of the Final Timing System for the
European XFEL Project
A. Hidvegi1, P. Gessler2, H. Kay3, V. Petrosyan3, G. Petrosyan3, L. Petrosyan3,
A. Aghababyan3, K. Rehlich3, C. Bohm1
1
Stockholm University, Sweden; 2European X-Ray Free Electron Laser Facility
GmbH, Germany; 3Deutsches Elektronen-Synchrotron (DESY), Germany
N14-238 Evaluation of the Second Version Time Based Readout ASIC
for SSPM Based PET Applications
X. Sun1, K. A. Lan1, Z. Deng2,3, X. Zhu2,3, Y. Liu2,3, Y. Shao1
1
University of Texas MD Anderson Cancer Center, US; 2Tsinghua University,
China; 3Ministry of Education, China
N14-239 The ATLAS Hadronic Tau Trigger
T. Childers, CERN, Switzerland,
Tuesday - RTSD Poster
Presentations
Notes
R06 RTSD Poster 2
Tuesday, Oct. 30 Session Chair: 14:30-16:00 Grand Ballroom North
Jan Franc, Institute of Physics, Charles University, Czech
Republic
The posters of this session are identical to RTSD Poster Session 1. See list
of posters on page xxx.
148 Tuesday - RTSD Poster Presentations Tuesday - RTSD Poster Presentations 149
Notes
150 Tuesday - RTSD Poster Presentations Notes
Tuesday - RTSD Poster Presentations 151
Notes
152 Tuesday - RTSD Poster Presentations Notes
Tuesday - RTSD Poster Presentations 153
07:00
07:30
08:00
MIC Refresher
Course 1
M03: Emission Tomography Instrumentation (PET,SPECT) 1
N25: Radiation Damage Effects I
M04: Image Reconstruction
Methods 1
09:30
N21: Neutron Detectors and
Instrumentation II
N26: Scintillators and Scintillation Detectors II
09:00
M02: MIC Awards and Plenary 2
N22: Photodetectors and Radiation Imaging Detectors I
N27: Experimental Reactor Instrumentation and Measurement
08:30
N18: Semiconductor Tracking
and Spectroscopy Detectors I
N23: Data Acquisition and
Analysis Systems II
N28: Experimental Software
Developments
M01: MIC Plenary 1
N19: Data Acquisition and
Analysis Systems I
N24: High Energy Physics
Instrumentation II
R10: CdTe
N15: Instrumentation for Homeland Security IV: Active Interrogation and Detector Arrays
N20: Nuclear Physics Instrumentation I
R09: Applications 2
Circuits IV
Instrumentation I
R08: CdZnTe 2
10:00
10:30
11:00
11:30
12:00
R07: Semiconductor Films
Wednesday, 31 October
Grand Ballroom
Center
Grand Ballroom
South
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
Ballroom
Exhibit Hall
South
Monorail A+B
Sleeping Beauty
Pavillion
Wednesday - NSS Oral
Presentations
N15 Instrumentation for Homeland Security
IV: Active Interrogation and Detector
Arrays
Wednesday, Oct. 31 08:00-10:00 Magic Kingdom Ballroom 1
Session Chairs: Peter E. Vanier, Brookhaven National Laboratory, USA
James Ely, Pacific Northwest National Laboratory, USA
N15-1 (08:00) Photofission for Active SNM Detection I : Intense Pulsed
12:30
13:00
13:30
NSS Refresher
Course 2
14:00
14:30
15:00
15:30
16:00
16:30
17:00
17:30
18:00
Women in Engineer (WIE)
Session
8MeV Bremsstrahlung Source
C. Hill, J. O’Malley, M. Ellis, P. Mistry, R. Maddock, J. Precious, AWE, UK;
J. C. Zier, S. L. Jackson, A. Hutcheson, L. Mitchell, B. Phlips, NRL, USA
N15-2 (08:15) Photonuclear Physics Modeling in the MCNPX-PoliMi
Code
S. D. Clarke, S. A. Pozzi, University of Michigan, USA; E. Padovani,
Polytechnic of Milan, Italy
N15-3 (08:30) A Microfabricated Electrostatic Field Desorption Ion
Source
K. L. Hertz1, B. B. Johnson2, P. J. Resnick1, C. E. Holland3, P. R.
Schwoebel2, D. L. Chichester4
1
Sandia National Laboratories, USA; 2University of New Mexico, USA; 3SRI
International, USA; 4Idaho National Laboratory, USA
N15-4 (08:45) Development of Analog Readout, Digital Signal
Processing, and Data Analysis Software for Ultra-High Rate HPGe
J. Fast, E. Aguayo Navarrete, A. Evans, D. Rodriguez, M. Taubman, B.
VanDevender, G. Warren, C. Wilen, L. Wood
N15-5 (09:00) Intelligent Radiation Sensor System (IRSS) Advanced
Technology Demonstrator (ATD)
D. A. Cooper, R. J. Ledoux, K. Kamieniecki, S. E. Korbly, J. Thompson, J.
Batcheler, S. Chowdhury, N. Roza, J. Costales, V. Aiyawar
Passport Systems, Inc., USA
N15-6 (09:15) The Impact of Crowd Inspection in Homeland Security
Applications
G. Cardoso, M. Turqueti, Creative Electron, INC, USA
N15-7 (09:30) Urban Terrain Mapping for Standoff Gamma-Ray
Detection Systems
D. H. Chivers1, T. Aucott2, M. Bandstra2, R. Cooper1, T. Hendricks3, K.
McCall3, L. McLean3, M. Quinlan1, B. Quiter1, K. Vetter1,2, A. Zhokor2, A.
Zoglauer2
1
Lawrence Berkeley National Laboratory, USA; 2University of California, USA;
3
Remote Sensing Laboratory, LLC, USA
N15-8 (09:45) Improved Spectroscopic and Isotope Identification
Performance of the GammaTracker Handheld Radioisotope Identifier
C. E. Seifert1, L. E. Erikson1, M. J. Myjak1, D. R. Balvage1, M. T. Batdorf1,
E. M. Becker2, S. T. Brown3, B. J. Burghard1, L. J. Kirihara1, R. P. Lundy1, S.
J. Morris1, J. L. Rohrer1, M. S. Taubman1
1
Pacific Northwest National Laboratory, USA; 2Oregon State University, USA;
3
18:30
19:00
19:30
Conference
Reception
154 154
Wednesday - NSS Oral Presentations 155
N16 Analog and Digital Circuits IV
Session Chairs: Ren-yuan Zhu, California Institute of Technology, USA
Florian W. Erdinger, Heidelberg University, Germany
N16-1 (08:00) Single-Chip Time-to-Digital Converter with 10 ps
Resolution, 160 ns Dynamic Range, and 1% LSB DNL
B. Markovic, D. Tamborini, F. Villa, A. Tosi
Politecnico di Milano, Italy
N16-2 (08:15) A Low Noise and High Dynamic Charge Sensitive
Amplifier-Shaper Associated with Silicon Strip Detector for Compton
Camera
M. Dahoumane, D. Dauvergne, J. Krimmer, H. Mathez, C. Ray, E. Testa, A.
E. Walenta, Y. Zoccarato
IPNL, Universit de Lyon, F-69003 Lyon, France; Universit Lyon 1 and CNRS/
IN2P3, UMR 5822 F-69622, France
N16-3 (08:30) VIP: a Low Noise Readout ASIC for Pixelated CdTe
Gamma-Ray Detectors for Use in Next Generation PET Scanners
J. G. Macias-Montero1, M. Sarraj2, M. Chmeissani1, C. Puigdengoles1, G.
De Lorenzo1, R. Martnez3
1
Institut de Fisica d’Altes Energies (IFAE), Spain; 2Texas Instruments Inc., USA;
3
IMB-CNM (CSIC), Spain
N16-4 (08:45) A 64-Channel ASIC for TOFPET Applications
M. D. Rolo1,2, R. Bugalho1,3, F. Goncalves4, A. Rivetti5, G. Mazza5, J. C.
Silva1, R. Silva1, J. Varela1,3
1
LIP, Portugal; 2UNITO, Italy; 3IST UTL, Portugal; 4INESC-ID, Portugal;
5
INFN - sez. Torino, Italy
N16-5 (09:00) 32 Channels SPAD Array for Single Photon Timing
Applications
C. Scarcella1, S. Bellisai1, A. Della Frera1, A. Ruggeri1, S. Tisa2, A. Tosi1, F.
Zappa1
1
Politecnico di Milano, Italy; 2Micro Photon Devices S.r.l., Italy
N16-6 (09:15) KLauS - a Charge Readout and Fast Discrimination
Readout ASIC for Silicon Photomultipliers
T. Harion, W. Shen, G. Sidlauskas, M. Dorn, K. Briggl, H.-C. SchultzCoulon, Kirchhoff-Institute, Germany
N16-7 (09:30) PETA4 - a 36 Channel Readout System ASIC for SiPMs
M. Ritzert, I. Sacco, P. Fischer, I. Peric
University of Heidelberg, Germany
N16-8 (09:45) TIMPIC-II: the Second Version Time-Based-Readout
ASIC for SSPM Based PET Applications
X. Zhu1,2, Z. Deng1,2, A. K. Lan3, X. Sun3, Y. Liu1,2, Y. Shao3
1
Tsinghua University, China; 2Ministry of Education, China; 3The University of
Texas M.D. Anderson Cancer Center, USA
N17 High Energy Physics Instrumentation I
Session Chairs: James E. Brau, University of Oregon, USA
Joachim Mnich, DESY, Germany
N17-1 (08:00, overview) ATLAS Upgrades Towards the High Luminosity
LHC: Extending the Discovery Potential
U. Parzefall, University of Freiburg, Germany
N17-2 (08:30) Performance of the LHCb Detector During the LHC
Proton Runs 2010-2012
R. Jacobsson, CERN, Switzerland
On behalf of the LHCb collaboration
N17-3 (08:45) The LHCb Detector Upgrade
C. Faerber, University of Heidelberg, Germany
156 Wednesday - NSS Oral Presentations N17-4 (09:00) An Upgraded Timing Counter for the MEG Experiment
P. W. Cattaneo, INFN Pavia, Italy
On behalf of the MEG Timing Counter group
N17-5 (09:15) PANDA Barrel DIRC Prototype Test Beam Results
J. Schwiening, GSI, Germany
On behalf of the PANDA Cherenkov Group
N17-6 (09:30) Development of a RICH Counter with 144-ch Hybrid
Avalanche Photo-Detectors for the Belle II Experiment
S. Iwata1, I. Adachi2, R. Dolenec3, K. Hara2, M. Higuchi4, T. Iijima5, H.
Kakuno1, H. Kawai6, T. Kawasaki7, S. Korpar3,8, P. Krizan9, T. Kumita1, S.
Nishida2, W. Mori10, S. Ogawa10, R. Pestotnik3, Y. Sakashita1, L. Santelj3, A.
Seljak3, T. Sumiyoshi1, H. Takagaki1, M. Tabata6,11, Y. Yusa7, R. Verheyden3
1
Tokyo Metropolitan University, Japan; 2High Energy Accelerator Research
Organization (KEK), Japan; 3J. Stefan Institute, Slovenia; 4Tokyo University of
Science, Japan; 5Nagoya University, Japan; 6Chiba University, Japan; 7Niigata
University, Japan; 8University of Maribor, Slovenia; 9University of Ljubljana,
Slovenia; 10Toho University, Japan; 11Japan Aerospace Exploration Agency
(JAXA), Japan
N17-7 (09:45) The ATLAS Forward Physics Project
C. Royon, IRFU-SPP, CEA Saclay, France
On behalf of the ATLAS Forward Physics collaboration
N18 Semiconductor Tracking and
Spectroscopy Detectors I
Session Chairs: Gianluigi Casse, Dep. of Physics, University of Liverpool,
United Kingdom
Susanne Kuehn, University of Freiburg, Germany
N18-1 (10:30, overview) Tracking Semiconductor Detectors
H. F. F-W. Sadrozinski, Univ. of California Santa Cruz, USA
N18-2 (11:00) Performance of the LHCb VELO
C. Farinelli, NIKHEF, Netherlands
On behalf of the LHCb VELO Group
N18-3 (11:15) Status of the ATLAS Pixel Detector at the LHC and its
Performance after Three Years of Operation
E. Shabalina, University of Goettingen, Germany
N18-4 (11:30) Beam Tests and Performance Studies for the PANDA
Micro-Vertex-Detector
S. Bianco, Helmholtz-Institut fr Strahlen- und Kernphysik, Germany
On behalf of the PANDA Micro-Vertex-Detector Group
N18-5 (11:45) Antihydrogen Identification with Silicon Vertex Detector
in the ALPHA Experiment
J. T. K. McKenna, P. Pusa, D. Wells, D. Seddon, J. Thornhill, J. Sampson,
P. Nolan
University of Liverpool, United Kingdon
N18-6 (12:00) ATLAS Silicon Microstrip Tracker Operation and
Performance
S. D’Auria, University of Glasgow, United Kingdom
N18-7 (12:15) Resistivity Measurements of Interstrip Isolation on
Silicon Devices with Alumina Layers as Effective P-Stops
S. Ely, C. Parker, V. A. Fadeyev, H. F.-W. Sadrozinski, UCSC, USA; M.
Christophersen, B. F. Phlips, NRL, USA
N19 Data Acquisition and Analysis Systems I
Session Chairs: Ryosuke Itoh, KEK, Japan
Christian Bohm, University of Stockholm, Department
of Physics, Sweden
N19-1 (10:30, overview) An Overview over Online Systems at the LHC
B. Jost, CERN, Switzerland
N19-2 (11:00) The sROD Demonstrator for the ATLAS Tile Calorimeter
Upgrade
A. Valero, Instituto de Fisica Corpuscular, Spain
On behalf of the on behalf of the ATLAS Tile Calorimeter System
N19-3 (11:15) The Autonomous, High-Speed, Low-Power Data
Acquisition System for the ARIANNA Antarctic High Energy Neutrino
Detector Array
S. A. Kleinfelder, University of California, U.S.A.
On behalf of the ARIANNA Collaboration
N19-4 (11:30) Readout Electronics for the Forward Silicon Vertex
Detector at PHENIX
S. A. Butsyk, University of New Mexico, USA
N19-5 (11:45) Testing Radiation Tolerance of Optical Transceivers for
the SuperB Experiment
A. Aloisio1, F. Ameli2, V. Bocci2, G. Chiodi2, R. Giordano1
1
Universita’ di Napoli ‘Federico II’ and INFN, Italy; 2INFN Sezione di Roma
1, Italy
N19-6 (12:00) Verification of the Pile-up Recovery Algorithm for the
Front-End Electronics of the PANDA Electromagnetic Calorimeter
G. J. Tambave, Kernfysisch Versneller Instituut (KVI), The Netherlands
On behalf of the PANDA Collaboration
N19-7 (12:15) A New DAQ System Strategy and its Implementation for
the KLOE-2 Experiment.
P. Branchini, INFN, Italy
On behalf of the KLOE2 experiment
N20 Nuclear Physics Instrumentation I
Session Chairs: Seonho Choi, Seoul National University, South Korea
Craig L. Woody, Brookhaven National Lab, USA
N20-1 (10:30) High-Speed Pulse Height Analyzer for Downhole
Spectroscopic Applications
B. Jorion, C. Stoller, Schlumberger, USA
N20-2 (10:45) A Digital Data Acquisition System for the Detectors at
Gammasphere
J. T. Anderson1, M. Albers1, M. Alcorta1, C. Campbell1,2, M. P. Carpenter1,
C. J. Chiara1,3, M. Cromaz2, H. M. David4, D. Doering2, D. T. Doherty4,
C. R. Hoffman1, R. V. F. Janssens1, J. Joseph2, T. L. Khoo1, A. Kreps1,
T. L. Lauritsen1, I. Y. Lee2, C. Lionberger2, C. K. Lister5, T. Madden1,
M. B. Oberling1, A. M. Rogers1, D. Seweryniak1, P. Wilt1, S. Zhu1, S.
Zimmermann2
1
Argonne National Laboratory, USA; 2Lawrence Berkeley National Laboratory,
USA; 3University of Maryland, USA; 4University of Edinburgh, UK; 5University
of Massachusetts Lowell, USA
N20-3 (11:00) A Prototype for a Focussing Disc DIRC Using Passive
Dispersion Mitigation
B. Seitz, University of Glasgow, United Kingdom
On behalf of the PANDA Cherenkov Group
N20-4 (11:15) Design of Nuclear Radiation Smart Probe Based on
Technique of Time-to-Count
Y. Lai, Z. Zen, B. Wang, Institute of Chemical Defense, China; J. Li, Y. Li, Y.
Li, Y. Wang, Tsinghua University, China
158 Wednesday - NSS Oral Presentations N20-5 (11:30) Status and Design of Two-Phase Liquid-Xenon
Compton-Imaging Detector
C. G. Wahl, E. P. Bernard, C. Kachulis, N. A. Larsen, B. Tennyson, S. B.
Cahn, D. N. McKinsey, Yale University, USA; N. E. Destefano, M. Gai,
University of Connecticut, USA
N20-6 (11:45) FARCOS: a Versatile and Modular Femtoscopy Array for
Correlations and Spectroscopy
L. Acosta1, F. Amorini1, A. Anzalone1, L. Auditore1,2, C. Boiano1, G.
Cardella1, A. Castoldi3,1, A. Chbihi4, E. De Filippo1, L. Francalanza1,5, E.
Geraci5,1, S. Giani’1,5, C. Guazzoni3,1, E. La Guidara1,6, G. Lanzalone1,7,
I. Lombardo1,8, S. Lo Nigro5,1, D. Loria1,2, C. Maiolino1, I. Martel9, T.
Minniti1,2, A. Pagano1, E. V. Pagano1,5, M. Papa1, T. Parsani3,1, S. Pirrone1,
G. Politi1,5, F. Porto1,5, F. Riccio3, F. Rizzo1,5, P. Russotto1,5, A. M. SanchezBenitez9, J. A. Duenas Diaz9, R. Berjillos Morente9, S. Santoro1,2, A.
Trifiro’1,2, M. Trimarchi1,2, G. Verde1, M. Vigilante1,8, P. Zambon3,1
1
INFN, Italy; 2Universita’ degli Studi di Messina, Italy; 3Politecnico di Milano,
Italy; 4GANIL, France; 5Universita’ degli Studi di Catania, Italy; 6Centro
Siciliano di Fisica Nucleare e Struttura della Materia, Italy; 7Universita’ KORE,
Italy; 8Universita’ di Napoli, Italy; 9Universidad de Huelva, Spain
N20-7 (12:00) Position-Resolved Positron Annihilation Lifetime
Spectroscopy
F. Fiedler1, W. Anwand1, M. Butterling1,2, T. E. Cowan1,3, W. Enghardt1,4, F.
Fritz1,3, K. Heidel1, M. Kempe1,3, T. Steudtner1,3, A. Wagner1
1
Helmholtz-Zentrum Dresden-Rossendorf, Germany; 2Martin-LutherUniversitaet, Germany; 3TU Dresden, Germany; 4OncoRay, Germany
N20-8 (12:15) Positron Annihilation Momentum Spectroscopy of
Nuclear Materials: Coincident Angular Correlation of Annihilation
Radiation / Doppler Broadening of Annihilation Radiation (ACAR/
DBAR)
S. B. Fagan-Kelly1, S. M. Jimenez1, C. S. Williams2, A. M. Bonavita1, L. W.
Burggraf1
1
Air Force Institute of Technology, USA; 2Defense Threat Reduction Agency, USA
N21 Neutron Detectors and
Instrumentation II
Session Chairs: Ralf Engels, Forschungszentrum Juelich GmbH,
Germany
Zane W. Bell, Oak Ridge National Laboratory, USA
N21-1 (14:00) Performance Characteristics of the OSMOND Neutron
Detector
D. M. Duxbury, J. E. Bateman, T. R. Charlton, R. Dalgliesh, C. J. Kinane,
N. J. Rhodes, E. M. Schooneveld, E. J. Spill
Science and Technology Facilities Council, RAL, UK
N21-2 (14:15) SPRINTER: a New Detector System for the INTER
Neutron Reflectometer
E. J. Spill, D. M. Duxbury, Science and Technology Facilities Council, United
Kingdom; N. J. Rhodes, E. M. Schooneveld, J. R. P. Webster, Science and
Technology Facilities CouncilScience and Technology Facilities Council, UK
N21-3 (14:30) Benchmarking the Spatial Resolution and Detection
Efficiency of a Fast-Neutron Imaging Detector Based on BulkMicromegas TPC
X. Zhang1, P. Colas2, C. Zhang1, H. Shen1, D. Attie2,1, W. Wang1,2, L. An1,
Z. He1, C. Mo1
1
Lanzhou University, China; 2CEA/Irfu Saclay, France
N21-4 (14:45) Performance Test of a Triple GEM Detector at CERN
n_TOF Facility
G. Claps1, F. Murtas1, A. Pietropaolo2, S. Puddu3, C. T. Severino3,4, M. Silari3
1
INFN-LNF, Italy; 2CNR, Italy; 3CERN, Switzerland; 4Bern University,
Switzerland
N21-5 (15:00) Gamma Sensitivity of a ZnS:Ag(6LiF) Wavelength
Shifting Fibre Neutron Detector in Mixed Neutron-Gamma Fields
G. J. Sykora, E. M. Schooneveld, N. J. Rhodes, STFC Rutherford Appleton
Laboratory, United Kingdom; L. van Eijck, Delft University of Technology, The
Netherlands
N21-6 (15:15) A 2D Gas Scintillation Proportional Detector for
Thermal Neutrons
D. Raspino1, I. Defendi2, R. Engels3, F. Francisco4, G. Bruno5, J. Martin2, G.
Kemmerling3, G. Manzin5, L. Margato4, A. Morozov4, H. Niko5, L. Pereira4,
N. J. Rhodes1, F. Sacchetti6, E. M. Schooneveld1, K. Zeitelhack2
1
STFC - Rutherford Appleton Laboratory, UK; 2FRM II, Germany; 3Zentralinst.
fur Elektron., Forschungszentrum Julich GmbH, Germany; 4LIP-Coimbra,
Portugal; 5Institut Laue Langevin, France; 6INFN, Italy
N21-7 (15:30) A High Spatial Resolution Neutron Imager Using Boron
Films and CCD’s
E. Ramberg1, J. Molina2, J. Blostein3, G. Fernandez Moroni4, J. Estrada1
1
Fermi National Accelerator Laboratory, USA; 2Universidad Nacional de
Asuncion, Paraguay; 3Centro Atomico Bariloche, Argentina; 4Universidad
Nacional del Sur, Argentina
N21-8 (15:45) Development of a Cathode for Large Area Neutron
Detectors Based on Boron-10 Converters
I. Stefanescu1, K. Zeitelhack1, C. Hoglund2,3, R. Hall-Wilton2, J. Birch3, L.
Hultman3
1
FRM2, Technische Universitaet Muenchen, Germany; 2European Spallation
Source ESS AB, Sweden; 3Linkoping University, Sweden
N22 Photodetectors and Radiation Imaging
Detectors I
Session Chairs: Peter Krizan, University of Ljubljana, Slovenia
N22-1 (14:00, invited) Recent Progress in Vacuum Based Photodetectors
and Their Applications
S. Korpar1,2
1
University of Maribor, Slovenia; 2J. Stefan Institute, Slovenia
N22-2 (14:30) Timing Resolution Improvement of MPPC for TOF-PET
Imaging
T. Nagano, T. Baba, K. Sato, K. Yamamoto
HAMAMATSU PHOTONICS K.K., Solid State Division, Japan
N22-3 (14:45) Time Jitter of Silicon Photomultipliers
T. Szczesniak, M. Moszynski, M. Grodzicka, M. Szawlowski, D. Wolski
N22-4 (15:00) Simple Methods for Measuring the PDE and the CrossTalk of a SiPM as Well as the Transverse Size of an Avalanche in a Cell
R. Mirzoyan1, M. Knoetig1, E. Popova2, P. Buzhan2, M. Teshima1
1
Max-Planck-Institute for Physics, Germany; 2National Research Nuclear
University MEPhI, Russia
N22-5 (15:15) Delayed Avalanches in Silicon Photo-Multipliers
F. Retiere, TRIUMF, Canada; K. Boone, University of British Columbia, Canada
N22-6 (15:30) Developments of AlGaAs Geiger Photodiodes for
Emerging Scintillation Detectors
X. J. Chen1, E. B. Johnson1, C. Whitney1, C. J. Stapels1, M. Hamming2, T.
Kang2, J. C. Campbell3, W. Sun3, J. F. Christian1
1
Radiation Monitoring Devices, Inc., U.S.A.; 2University of Michigan, U.S.A.;
3
University of Virginia, U.S.A.
N22-7 (15:45) Development of PPDs to Detect Scintillation Light from
Liquid Xenon
T. Iwamoto1, X. Bai1, T. Chiba1, Y. Fujii1, D. Kaneko1, T. Haruyama2, A.
Maki2, S. Mihara2, T. Mori1, H. Natori2, H. Nishiguchi2, W. Ootani1, R.
Sawada1, Y. Uchiyama1
1
The University of Tokyo, Japan; 2High Energy Accelerator Research
Organization, Japan
160 Wednesday - NSS Oral Presentations N23 Data Acquisition and Analysis Systems II
Session Chairs: Guenter Eckerlin, DESY, Germany
Masaharu Nomachi, Osaka University, Japan
N23-1 (14:00) FPGA-Based Serial Links for SuperB: Design Issues Vs.
Radiation Tolerance
A. Aloisio1, V. Bocci2, R. Giordano1, L. Sterpone3, M. Violante3
1
Universita’ di Napoli ‘Federico II’ and INFN, Italy; 2INFN Sezione di Roma 1,
Italy; 3DAUIN, Politecnico di Torino, Italy
N23-2 (14:15) Digital Data Acquisition and Processing for a NeutronGamma-Ray Imaging System
A. Poitrasson-Riviere, M. Flaska, M. C. Hamel, K. Ide, J. K. Polack, S. D.
Clarke, S. A. Pozzi
N23-3 (14:30) High Performance FPGA-Based Scatter/Gather DMA
Interface for PCIe
H. Kavianipour, C. Bohm, Stockholm University, Sweden
N23-4 (14:45) A Wireless Power and Data Acquisition System for Large
Detectors
P. De Lurgio, Z. Djurcic, G. Drake, A. Kreps, H. Sahoo
Argonne National Laboratory, USA
N23-5 (15:00) Control and Data Acquisition System for X-Ray FreeElectron Laser Experiments at SACLA
M. Yamaga, A. Amselem, Y. Furukawa, T. Hirono, Y. Joti, T. Kameshima,
A. Kiyomichi, T. Ohata, T. Sugimoto, JASRI/SPring-8, Japan; R. Tanaka, T.
Hatsui, RIKEN/SPring-8, Japan
N23-6 (15:15) A Study of a Prototype DAQ System with over 10 Gbps
Bandwidth for the SACLA X-Ray Experiments
C. Saji, T. Ohata, T. Sugimoto, R. Tanaka, M. Yamaga
JASRI/SPring-8, Japan
N23-7 (15:30) A Readout System for High-Speed CCD Cameras Based
on Advanced Telecommunications Computing Architecture
P. J. McVittie, J. M. Joseph, D. Contarato, P. Denes, D. Doering, Lawrence
Berkeley National Laboratory, USA; J. Weizeorick, Argonne National
Laboratory, USA
N23-8 (15:45) Likelihood Analysis of Beam Data for Time Of
Propagation Counter
Y. Arita, Nagoya University, Japan
On behalf of the Belle II PID group
N24 High Energy Physics Instrumentation II
Session Chairs: Ingrid-Maria Gregor, DESY, Germany
Cinzia Da Via, University of Manchester /CERN, United
Kingdom
N24-1 (14:00) Research and Development Towards a CMS Tracker for
the HL-LHC
A. Mussgiller, DESY, Germany
N24-2 (14:30) The LHCb VELO Upgrade
P. Collins, CERN, SWITZERLAND
On behalf of the LHCb VELO Upgrade Group
N24-3 (14:45) Advanced Alignment of the ATLAS Tracking System
P. Bruckman de Renstrom, Institute of Nuclear Physics, Poland
N24-4 (15:00) Performance and Phase I Upgrade Plans for the CMS
Pixel Detector
H. Perrey, DESY, Germany
N24-5 (15:15) Results from the Pilot Run of the Pixel Luminosity
Telescopes, a Luminosity Monitor for CMS Based on Single-Crystal
Diamond Pixel Sensors
D. A. Hidas, Rutgers University, USA
On behalf of the CMS PLT Collaboration
N24-6 (15:30) Silicon Strip Detectors for ATLAS at the HL-LHC
Upgrade
S. Diez Cornell, Lawrence Berkeley national Laboratory, USA
On behalf of the The ATLAS Collaboration
N24-7 (15:45) Conceptual Design of the Muon Forward Tracker of the
ALICE Experiment
F. Orsini1, A. Baldisseri1, G. Batigne2, H. Borel1, S. Bouvier2, H. Chanal3, Y.
Degerli1, B. Espagnon4, J. Y. Grossiord5, F. Guilloux1, G. Guilloux2, C. Insa3,
F. Manso3, H. Mathez5, A. Rakotozafindrabe1, C. Renard2, R. Tieulent5, A.
Uras5, Y. Zoccarato5
1
CEA Saclay, France; 2Subatech Nantes, France; 3LPC Clermont, France; 4IPN
Orsay, France; 5IPN Lyon, France
N25 Radiation Damage Effects I
Session Chairs: Doris Eckstein, Deutsches Elektronen-Synchrotron
DESY, Germany
Alexandra Junkes, Brown University, USA
N25-1 (16:30) Silicon Sensors for HL-LHC Tracking Detectors
S. Kuehn, University of Freiburg, Germany
On behalf of the RD50 Collaboration
N25-2 (16:45) Analysis of Edge and Surface TCTs for Irradiated 3D
Silicon Strip Detectors
G. D. Stewart, R. Bates, University of Glasgow, UK; G. Kramberger, M.
Milovanovic, Jozef Stefan Institute, Slovenia; G. Pellegrini, C. Fleta, M.
Lozano, Instituto de Microelectrnica de Barcelona, Spain
N25-3 (17:00) A Charge Collection Study with Dedicated RD50 Charge
Multiplication Sensors
C. Betancourt, K. Jakobs, A. Driewer, T. Barber, S. Wonsak, U. Parzefall, M.
Hauser, S. Kuehn
Albert-Ludwigs-Universitt Freiburg, Germany
N25-4 (17:15) Thin Silicon Detectors for Tracking in High Radiation
Environments
G. Casse, P. Dervan, P. P. Allport, T. Huse, A. Greenall, D. Forshaw, I. Tsurin
Dep. of Physics, University of Liverpool, UK
N25-5 (17:30) Silicon Strip Sensor Simulations
T. Eichhorn, DESY, Germany
N25-6 (17:45) Exploring Various Isolation Techniques for the
Development of Low-Mass, Low-Noise Silicon Tracking Stations for the
CBM Experiment
M. Singla, Goethe University, Germany; S. Chatterji, V. Kleipa, W. F. J.
Mueller, J. M. Heuser, GSI, Germany
N25-7 (18:00) Proton and Neutron Irradiation Tests of Readout
Electronics of the ATLAS Hadronic Endcap Calorimeter
S. Menke, Max Planck Institute for Physics, Germany
On behalf of the ATLAS Liquid Argon Calorimeter Group
N25-8 (18:15) A Study on Radiation Hardness of PWO-II Crystals
F. Yang, R. H. Mao, L. Y. Zhang, R. Y. Zhu
California Institute of Technology, USA
162 Wednesday - NSS Oral Presentations N26 Scintillators and Scintillation
Detectors II
Session Chairs: Pieter Dorenbos, Delft University of Technology,
Netherlands
Paul R. Lecoq, CERN, Switzerland
N26-1 (16:30) Polymer and Glass-Matrix Nanocomposites for
Scintillation Applications
Z. Kang, B. K. Wagner, C. J. Summers, J. Nadler, R. Rosson, B. Kahn
Georgia Institute of Technology, USA
N26-2 (16:45) Quantum Dot Plastic Composites as Scintillators for
High Energy Radiation Detection
S. Palamakumbura1, H. Sabet1, S. Miller1, A. T. Thamban2, H. Menkara2, C.
Summers2, V. Nagarkar1
1
Radiation Monitoring Devices Inc, USA; 2PhophorTech Corporation, USA
N26-3 (17:00) New Cerium-Based Metal-Organic Scintillators
L. A. Boatner1,2, J. S. Neal1,2, J. O. Ramey1,2, B. C. Chakoumakos1,2, R.
Custelcean1,2, E. van Loef3, K. Shah3
1
Oak Ridge National Laboratory, USA; 2ORNL Center for Radiation Detection
Materials and Systems, USA; 3Radiation Monitoring Devices, USA
N26-4 (17:15) Development of Transparent Ceramic GYGAG(Ce)-Based
Gamma Spectrometers
N. Cherepy, Z. Seeley, S. Payne, B. Sturm, O. Drury, S. O’Neal, P. Thelin,
Lawrence Livermore National Laboratory, USA; T. Stefanik, L. Nguyen,
Nanocerox, Inc., USA; J. Kindem, Digirad, Inc., USA
N26-5 (17:30) 2-Inch Size Crystal Growth of Ce:Gd3Al2Ga3O12 with
Various Ce Concentration and Their Scintillation Properties
K. Kamada1, P. Prusa2, M. Nikl2, T. Yanagida3, T. E. Endo1, K. Tsutumi1, Y.
Usuki1, A. Yoshikawa3
1
Furukawa Co., Ltd., Japan; 2Institute of Physics, AS CR,, Czech Republi;
3
N26-6 (17:45) Low Afterglow Co-Doped LYSO:Ce with Significant
Ce4+ Content
S. Blahuta1, B. Viana2, A. Bessiere2, V. Ouspenski1
1
Saint-Gobain Recherche, FRANCE; 2LCMCP - Chimie ParisTech UMR7574,
FRANCE
N26-7 (18:00) Effect of Bi-Codoping on the X-Ray Induced Afterglow
in CsI:Tl
D. Totsuka1,2, T. Yanagida2, Y. Fujimoto2, Y. Yokota2, F. Moretti3, A. Vedda3,
A. Yoshikawa2
1
Nihon Kessho Kogaku CO.,LTD,, Japan; 2Tohoku University, Japan;
3
University of Milano-Bicocca, Italy
N27 Experimental Reactor Instrumentation
and Measurement
Session Chairs: Abdallah Lyoussi, CEA / French Atomic Energy
Commission, France
Adam Bernstein, Lawrence Livermore National
Laboratory, USA
N27-1 (16:30) On Innovative and Advanced Instrumentation and
Measurement Methologies Dedicated/Expected to/in Jules Horowitz
Future European MTR Reactor
A. Lyoussi, CEA, France
N27-2 (16:45) Enhancement of LaBr3 Scintillator and HPXe Gaseous
Detector Spectra for Burnup and Cooling Time Determination of an
ATR Fuel Permanent Scanning System
J. Navarro1, T. A. Ring2, D. W. Nigg1
1
Idaho National Laboratory/USRA, USA; 2University of Utah, USA
N27-3 (17:00) Nuclear Heating Measurements by Calorimetry into
MTR. From Thermal Calibrations under Non Irradiation Conditions to
In-Pile Experiments
C. Reynard-Carette, Aix-Marseille Univ, France
N27-4 (17:15) Towards Far-Field Reactor Monitoring with Antineutrino
Detectors
S. A. Dazeley, A. Bernstein, N. S. Bowden, M. Sweany, LLNL, USA; E.
Brubaker, P. Marleau, D. Reyna, Sandia, USA
N27-5 (17:30) Cosmic Ray Muon Radiography of Reactor Cores Using
Nuclear Emulsion Detector
K. Morishima, N. Naganawa, T. Nakano, M. Nakamura, J. Kawarabayashi,
H. Tomita, T. Iguchi
N27-6 (17:45) TMI and Fukushima Loss-of-Coolant Accidents: Lessons
NOT Learned
A. DeVolpi, retired, Argonne National Laboratory, USA; I. Gomes, I.C.Gomes
Consulting & Investment Inc., USA
N27-7 (18:00) Material Characterisation with the Associated Particle
Technique
B. Perot, CEA Cadarache, France
N27-8 (18:15) Planer Gamma Camera Imaging and Analysis of the
Dynamics of Radiocesium Pollution in Plants Caused by the Fukushima
Daiichi Nuclear Power Plant Accident
N. Kawachi1, Y.-G. Yin1, N. Suzui1, S. Ishii1, H. Watabe2, S. Yamamoto3, S.
Fujimaki1
1
Quantum Beam Science Directorate, Japan Atomic Energy Agency, Japan;
2
Graduate School of Medicine, Osaka University, Japan; 3Graduate School of
Medicine, Nagoya University, Japan
N27-9 (18:30) Promise and Challenge of Nuclear Resonance
Fluorescence in Nuclear Safeguards
B. A. Ludewigt, B. J. Quuiter
N27-10 (18:45) Sensitivity Analysis of Assembly-Level Fuel Verification
with Antineutrino Detectors
A. Erickson, A. Bernstein, N. Bowden
N28-5 (17:45) Precision Analysis of Electron Energy Deposition in
Detectors Simulated by Geant4
M. Batic1, G. Hoff2, M. G. Pia1, G. Weidenspointner3
1
INFN Genova, Italy; 2PUCRS, Brazil; 3MPI Halbleiterlabor, Germany
N28-6 (18:00) A New Radioactive Decay Code for Geant4
S. Hauf1, M. Kuster2, M. Batič3, Z. W. Bell4, D. H. H. Hoffmann1, G.
Hoff5, P. M. Lang1, M. G. Pia3, G. Weidenspointner6,7, A. Zoglauer8
1
di Genova, Italy; 4Oak Ridge National Laboratory, USA; 5PUCRS, Brazil; 6Max
Planck Institute for Extraterrestrial Physics - MPE, Germany; 7Max Planck
Halbleiterlabor, Germany; 8University of California at Berkeley, USA
N28-7 (18:15) The Influence of in-Orbit Activation Buildup on the
ATHENA WFI Detector Background
S. Hauf1, M. Kuster2, D. H. H. Hoffmann1, P. M. Lang1, S. Neff1, M. G.
Pia3, A. Stefanescu4, L. Strder5,4, G. Weidenspointner5,4
1
di Genova, Italy; 4Max Planck Institute for Extraterrestrial Physics - MPE,
Germany; 5Max Planck Halbleiterlabor, Germany
N28-8 (18:30) In-Orbit Activation Study of ASTRO-H X-Ray
Observatory Using Geant4
T. Sato1, M. Asai2, Y. Fukazawa3, K. Hiragi3, H. Kitamura4, M. Kokubun1,
Y. Koseki1, T. Mizuno3, H. Odaka1, M. Ohno3, M. Ohta1, M. Ozaki1, H.
Tajima5, T. Takahashi1, Y. Terada6, Y. Uchihori4, S. Watanabe1, T. Yasuda6
1
Institute of Space and Astronautical Science / JAXA, Japan; 2SLAC National
Accelerator Laboratory, USA; 3Hiroshima University, Japan; 4National Institute
of Radiological Sciences, Japan; 5Nagoya University, Japan; 6Saitama University,
Japan
N28-9 (18:45) Nuclear Resonance Fluorescence in GEANT4:
Development, Validation and Testing
M. N. Lakshmanan1,2, B. P. Harrawood2, G. A. Agasthya1,2, G. Y. Rusev1, A.
J. Kapadia2,1
1
Duke University, USA; 2Duke University Medical Center, USA
N28 Experimental Software Developments
Session Chairs: Gloria Corti, CERN, Switzerland
Zane W. Bell, Oak Ridge National Laboratory, USA
N28-1 (16:30, invited) Phenomenological and Computational Models
of Scintillation Mechanisms: a Material Science Point of View
G. A. Bizarri, Lawrence Berkeley National Laboratory, USA
N28-2 (17:00) Ray Tracing Simulations in Scintillators: a Comparison
Between Slitrani and Geant4
M. Pizzichemi1, E. Auffray2, M. Brown3, R. Chipaux4, G. Cucciati1, N.
Di Vara1,2, P. Lecoq2, M. T. Lucchini1,2, A. Knapitsch2, M. Paganoni1, I.
Papakostantinou3, K. Pauwels2, D. Wahl5
1
University of Milano Bicocca, Italy; 2CERN, Switzerland; 3University College
London, United Kingdom; 4DECEA/DSM/IRFU, CE-Saclay, France; 5Instituto
de Fisica, Universidad Nacional de Ingenieria, Peru
N28-3 (17:15) A Study on Multiplex Proton Imaging Using GEANT4
T. Aso, Nagaoka University of Technology, Japan; K. Kawashima, Toyama
National College of Technology, Japan; T. Nishio, National Cancer Center,
Japan; S. B. Lee, National Cancer Center, Korea; T. Sasaki, High Energy
Accelerator Research Organization, Japan
N28-4 (17:30) Monte Carlo Simulation of Single-Plane Magnetically
Focused Narrow Proton Beams
G. A. McAuley, S. R. Barnes, A. J. Wroe, J. M. Slater
Loma Linda University, USA
164 Wednesday - NSS Oral Presentations Wednesday - NSS Oral Presentations 165
Wednesday - MIC Oral
Presentations
M03-2 (14:15) Depth of Interaction Measurement Using Spectral
M01 MIC Plenary 1
Wednesday, Oct. 31 08:15-10:00 Session Chair: Grand Ballroom Center
Vesna Sossi, University of British Columbia, Canada
M01-1 (08:15) Introductory Remarks
V. Sossi, University of British Columbia, Canada
M01-2 (08:30, invited) Multi-modality Imaging and the Future of
Alzheimer’s Disease
W. Jagust, Public Health and Neuroscience, CA
M01-3 (09:15, invited) Practicing Astromedicine Lessons in Imaging
and Inversion from a Rocket Scientist
J. Matthews, University of British Columbia, Canada
M02 MIC Awards and Plenary 2
Wednesday, Oct. 31 10:30-12:30 Session Chair: Grand Ballroom Center
Alexander K. Converse, University of WisconsinMadison, USA
M02-1 (10:30) Awards
M02-2 (11:30) Performance of a Prototype Small-Animal PET Scanner
Dedicated to Mouse Brain Imaging
Y. Yang1, J. Bec1, J. Zhou1, M. Zhang1, M. S. Judenhofer1, X. Bai1, K. Di1, Y.
Wu1, M. Rodrguez-Villafuerte1, P. Dokhale2, K. S. Shah2, R. Farrell2, J. Qi1,
S. R. Cherry1
1
University of California at Davis, USA; 2Radiation Monitoring Devices Inc., USA
M02-3 (11:45) Design Concept of World’s First Preclinical PET/MR
Insert with Fully Digital Silicon Photomultiplier Technology
B. Weissler1, P. M. Dueppenbecker1, P. Gebhardt2, A. Salomon2, B.
Goldschmidt3, W. Renz4, S. Katharina4, B. Zwaans5, P. K. Marsden2, F.
Kiessling3, V. Schulz1,3
1
Philips Research, Germany; 2King’s College, United Kingdom; 3RWTH
University, Germany; 4Irmato Industrial Solutions, Germany; 5Philips Digital
Photo Counting, Germany
M02-4 (12:00) Joint Reconstruciton of Attenuation and Emission from
PET Data Using MR-Derived Attenuation Prior
G. Wang1, C. Catana2, J. Qi1
1
University of California, Davis, USA; 2MGH, USA
M02-5 (12:15) Event-by-Event Respiratory Motion Correction with
3-Dimensional Internal-External Motion Correlation
C. Chan, X. Jin, E. K. Fung, T. Mulnix, R. E. Carson, C. Liu
Yale University, USA
M03 Emission Tomography Instrumentation
(PET,SPECT) 1
Wednesday, Oct. 31 14:00-16:00 Grand Ballroom Center
Session Chairs: Craig S. Levin, Stanford University, USA
Emilie Roncali, University of California-Davis, USA
M03-1 (14:00) A Prototype Detector for a Novel High-Resolution PET
System: Bazooka PET
R. Park1, B. W. Miller1, A. K. Jha1, L. R. Furenlid1, W. C. J. Hunter2, H. H.
Barrett1
1
University of Arizona, USA; 2University of Washington, USA
166 Wednesday - MIC Oral Presentations Information in a Two-Layer Crystal
E. Roncali, S. R. Cherry
University of California-Davis, USA
M03-3 (14:30) Timing Performance Comparison of P-on-N and N-on-P
Silicon Photomultipliers
R. Vinke1, J. Y. Yeom1, M. Mazzillo2, D. Sanfilippo2, A. Piana2, C. S. Levin1
1
Stanford University, USA; 2STMicroelectronics, Italy
M03-4 (14:45) Respiratory Tracking Using EDR for List-Mode Binning
in Cardiac Emission Tomography: Comparison with MRI Heart Motion
Measurements
A. Konik1, P. Dasari1, J. M. Mitra1, K. L. Johnson1, E. Helfenbein2, S.
Chien2, S. Babaeizadeh2, L. Shao2, J. Dey1, M. A. King1
1
Umass Medical School, US; 2Philips, US
M03-5 (15:00) Development of Time-of-Flight PET Block Detector
Using SiPMs Based on Signal Encoding and Digital TDC Implemented
on FPGA Without ADC
S. I. Kwon, J. S. Lee
Department of Nuclear Medicine, Seoul National University College of
Medicine, Korea
M03-6 (15:15) Use of the Fisher Information Matrix to Optimize the
Acquisition Protocol for a D-SPECT System
N. Fuin, S. Pedemonte, S. Arridge, S. Ourselin, B. H. Hutton
M03-7 (15:30) Adaptive Optimization of Slit Width for a Slit-Slat
Collimator
X. Zheng, S. D. Metzler, University of Pennsylvania, USA
M03-8 (15:45) A Lower-Cost Higher-Resolution Human PET Camera
Development and Feasibility Verification
H. Li, Y. Zhang, H. Baghaei, R. A. Ramirez-Jaramillo, W.-H. Wong
The University of Texas M. D. Anderson Cancer Center, USA
M04 Image Reconstruction Methods 1
Wednesday, Oct. 31 16:30-18:30 Grand Ballroom Center
Session Chairs: Michel Defrise, Dept. of Nuclear Medicine, Vrije
Universiteit Brussel, Belgium
Jinyi Qi, University of California, Davis, USA
M04-1 (16:30) ML-Reconstruction for TOF-PET with Simultaneous
Estimation of the Attenuation Factors
J. L. Nuyts, A. Rezaei, KU Leuven, Belgium; M. Defrise, Vrije Universiteit
Brussel, Belgium
M04-2 (16:45) Low-Count PET Image Reconstruction Using Sinogram
Shifting
G. Wang, J. Qi, University of California, Davis, USA
M04-3 (17:00) Fast Positron Range Calculation in Heterogeneous Media
for 3D PET Reconstruction
L. Szirmay-Kalos, M. Magdics, B. Toth, T. Umenhoffer, Budapest University
of Technology and Economics, Hungary; J. Lantos, G. Patay, Mediso, Hungary
M04-4 (17:15) A Hybrid Image-Space Resolution Model for Fully 3D
Listmode Reconstruction of TOF PET Data
J. Zhou1, H. Ye2, K. Balakrishnan2, W. Wang2, J. Qi1
1
University of California Davis, USA; 2Toshiba Medical Research Institute USA,
Inc., USA
M04-5 (17:30) Spatially Varying Regularization for Motion
Compensated PET Reconstruction
J. Dutta1, G. El Fakhri1, Y. Lin2, R. M. Leahy2, Q. Li1
1
Massachusetts General Hospital, USA; 2University of Southern California, USA
Wednesday - MIC Oral Presentations 167
M04-6 (17:45) Unifying Global and Local Statistical Measures for
Anatomy-Guided Emission Tomography Reconstruction
K. Vunckx1,2, S. R. Arridge2, A. Bousse2, D. Kazantsev2, S. Pedemonte2, B. F.
Hutton2
1
KU Leuven, Belgium; 2University College London, UK
M04-7 (18:00) Reconstruction of Uniform Sensitivity Emission Image
with Partially Known Axial Attenuation Information in PET-CT Scanner
V. Y. Panin1, M. Defrise2, J. Nuyts3, A. Rezaei3, M. E. Casey1
1
Siemens Healthcare, USA; 2Vrije Universitiet Brussel, Belgium; 3K.U.Leuven,
Belgium
M04-8 (18:15) An Algorithm for Modeling Non-Linear System Effects in
Iterative CT Reconstruction
K. J. Little, P. J. La Riviere, University of Chicago, USA
Wednesday - RTSD Oral
Presentations
R07 Semiconductor Films
Wednesday, Oct. 31 08:00-09:40 Session Chair: Paradise Pier Pacific Ballroom AB
Laura Fornaro, Universidad de la República, Uruguay
R07-1 (08:00, invited) MOVPE Growth of Thick Single Crystal
CdZnTe Epitaxial Layers on Si Substrate for Nuclear Radiation Detector
Development
M. Niraula, K. Yasuda, S. Namba, S. Muramatsu, T. Kondo, Y. Wajima, H.
Yamashita, Y. Agata
Nagoya Institute of Technology, Japan
R07-2 (08:20, invited) Fabrication of 4H-SiC Epilayer Surface Barrier
Detectors for Nuclear Radiation Detection
K. C. Mandal, S. K. Chaudhuri, R. M. Krishna, P. G. Muzykov
University of South Carolina, USA
R07-3 (08:40) Detector Grade Lead Monoxide (β-PbO) Micro/Nano
Ribbons with Extreme Aspect Ratio Grown by Vapour Phase
G. Benassi1, N. Zambelli1,2, D. Calestani1, L. Lazzarini1, M. Pavesi2, A.
Zappettini1
1
IMEM-CNR, Italy; 2University of Parma, Italy
R07-4 (08:55) Optimization of Lead Oxide (PbO) Technology for
Application in Direct Conversion Fluoroscopic Detectors
O. Semeniuk1,2, G. DeCrescenzo2, J. Berashevich2, J. Rowlands2, A. Reznik1,2
1
Lakehead University, Canada; 2Thunder Bay Regional Research Institute,
Canada
R07-5 (09:10) X-Ray Beam Monitor Made by Thin-Film CVD Single
Crystal Diamond
M. Angelone1, E. Milani2, M. Marinelli2, M. Pillon1, G. Prestopino1, C.
Verona2, G. Verona-Rinati2, N. Tartoni3, V. Kachkanov3, D. Cannata4, F. Di
Pietrantonio4, M. Benetti4
1
Associazione EURATOM-ENEA sulla Fusione, Italy; 2University Roma Tor
Vergata, Italy; 3Diamond Light Source, UK; 4CNR Istituto di Acustica O.M.
Corbino, Italy
R07-6 (09:25) High Purity MBE Grown AlSb to Characterize Properties
for Room Temperature X-/Gamma-Ray Detection
A. A. Hecht, E. I. Husher, G. Balakrishnan
University of New Mexico, USA
R08 CdZnTe 2
Robert D. McLaren, Consultant, USA
R08-1 (10:30, invited) Flux Dependent Polarisation in High Resistivity
CdZnTe
J. Franc1, V. Dědič1, L. Fajt1, H. Elhadidy2, R. Grill1, P. Sellin3
1
Charles University, Faculty of Mathematics and Physics, Czech Republic; 2Brno
University of Technology, Czech Republic; 3University of Surrey, Great Britain
R08-2 (10:50) Suppressing the Polarization Effect in Hgh Temperature
Conditions for an In/CdTe/Pt Detector
T. Seino, I. Takahashi, T. Ishitsu, K. Yokoi, K. Kobashi, Hitachi, Ltd., Japan
R08-3 (11:05) Control of CdZnTe Surface Leakage Current via Plasma
Processing and Amorphous Layer Deposition
L. F. Voss, A. M. Conway, A. J. Nelson, P. R. Beck, R. T. Graff, R. J.
Nikolic, S. A. Payne, Lawrence Livermore National Lab, USA; A. Burger, Fisk
University, USA; H. Chen, Redlen Technologies, CA
168 Wednesday - MIC Oral Presentations Wednesday - MIC Oral Presentations 169
R08-4 (11:20) Study of the Diffusion of Te-Inclusion and Dopants in
CdZnTe Nuclear Detectors in Post-Growth Annealing
S. U. Egarievwe, A. Adams, T. Harper, R. Pinder, M. L. Drabo, A.
Kassu, Alabama A&M University, U.S.A.; G. Yang, G. S. Camarda, A. E.
Bolotnikov, R. B. James, Brookhaven National Laboratory, U.S.A.
R08-5 (11:35) Reduction of Te Inclusions in CdZnTe Crystals by
Growth Process and Annealing Steps in Order to Improve the Detector
Performance
H. Bensalah1, J. Crocco1, A. Black1, Q. Zheng1, O. Vela2, J. L. Plaza1, E.
Dieguez1
1
Universidad Autonoma de Madrid, Spain; 2CIEMAT, Spain
R08-6 (11:50) Electroless Gold Contact Deposition on CdZnTe
Detectors by Scanning Pipette Technique
N. Zambelli1,2, G. Benassi2, L. Marchini2, D. Calestani2, A. Zappettini2
1
University of Parma, Italy; 2IMEM-CNR, Italy
R08-7 (12:05) High Count Rate Digital CdTe Photon-Conting X-Ray
Detector and Its Application for Photon-Counting CT
T. Aoki1,2, A. Koike1,2, H. Mimura1
1
Shizuoka University, Japan; 2ANSeeN Inc., Japan
R09 Applications 2
Henry Chen, Redlen Technologies, Canada
R09-1 (14:00, invited) Achieving High Position Resolution Using CZT
Drift Strip Detectors
I. Kuvvetli1, C. B. Jrgensen1, A. Zappettini2, G. Benassi2, E. Caroli3, L.
Marchini2, N. Zambelli2, J. B. Stephen3, N. Auricchio3
1
DTU Space National Space Institute, Technical University of Denmark,
Denmark; 2IMEM-CNR, Italy; 3INAF/IASF, Italy
R09-2 (14:20, invited) Long-Term Outdoor Performance Evaluation
of Stacked Coplanar Grid (Cd,Zn)Te Detectors by Spectroscopic
Environmental Radiation Monitoring
M. Dambacher1, A. Zwerger1,2, A. Fauler1,2, C. Disch2, W. Eickhoff3, U.
Stoehlker4, M. Fiederle1,2
1
X-ray Imaging Europe, Germany; 2Freiburger Materialforschungszentrum,
Germany; 3Bundesamt fuer Strahlenschutz, Germany; 4CTBTO, Austria
R09-3 (14:40) Long Term Stability and Depth of Interaction Studies on
Underground Operated CZT-CPG Detectors
D. Gehre, Technische Universitaet Dresden, Germany
On behalf of the COBRA
R09-4 (14:55) Uranium Enrichment Determination with Commercial
CZT Detectors and a Non-Proprietary Analysis Algorithm
T. M. Weber, M. Trujillo, Sandia National Laboratories, USA; J. Cantrell,
Y-12 National Security Complex, USA; D. Decman, T.-F. Wang, Lawrence
Livermore National Laboratory, USA
R09-5 (15:10) Spatially- and Energy-Resolved CZT Detectors to
improve Energy Dispersive X-Ray Diffraction Systems for Security
Application
B. Ghammraoui1, J. Tabary1, C. Paulus1, G. Montemont1, P. Duvauchelle2,
L. Verger1
1
CEA-Leti, MINATEC Campus, France; 2LVA INSA Lyon, France
R09-6 (15:25) Investigation of the Origin of Small Scale Distortions in
Finely Pixilated, Thick CZT Detectors.
B. T. Allen, J. Hong, J. Grindlay, B. Rodrigues, Harvard College Observatory,
USA; S. Barthelmy, R. Baker, NASA Goddard Space Flight Center, USA; F.
Harrison, W. Cook, CALTECH, USA
R09-7 (15:40) Optical Perturbation of the Electric Field in CdTe
Schottky Detectors
A. Cola, I. Farella, A. Valletta, CNR, Italy
170 Wednesday - RTSD Oral Presentations R10 CdTe
Loick Verger, CEA-LETI, France
R10-1 (16:30, invited) X-Ray Imaging Properties of Multi-Chip
Medipix2 MXR Assemblies Bonded to CdTe Sensors at Various Pixel
Pitches
T. Koenig, J. Schulze, M. Zuber, K. Rink, German Cancer Research Center
(DKFZ), Germany; J. Butzer, E. Hamann, A. Cecilia, Karlsruhe Institute of
Technology (KIT), Germany; A. Zwerger, A. Fauler, M. Fiederle, U. Oelfke,
Freiburg Materials Research Center (FMF), Germany
R10-2 (16:50) MACSI: an 8 Cm2 CdTe Detection Plane for TimeResolved Hard X-Ray Imaging with High Spectroscopic Capability
O. Limousin, C. Blondel, M. Donati, L. Dumaye, O. Gevin, A. Goetchy, S.
Herv, D.-D. Huynh, I. Le Mer, F. Lugiez, J. Martignac, A. Meuris, F. Nico,
F. Pinsard, CEA Saclay, France; F. Soufflet, M.-C. Vassal, 3D plus, France
R10-3 (17:05) Probing Defects in a Small Pixellated CdTe Sensor Using
an Inclined Mono Energetic X-Ray Micro Beam
E. Frojdh1, C. Frojdh1, E. N. Gimenez2, D. Krapohl1, D. Manueski3, B.
Norlin1, V. O’Shea3, H. Wilhem2, N. Tartoni2, G. Thungstrom1, R. M. Zain3
1
Mid Sweden University, Sweden; 2Diamond Light Source, United Kingdom;
3
Glasgow University, United Kingdom
R10-4 (17:20) Temporal Changes of Output Signals from CdTe
Radiation Detector Measured by Optical Laser Pulses
T. Ito, Y. Suzuki, A. Koike, H. Mori, Y. Neo, H. Mimura, T. Aoki
Shizuoka University, Japan
R10-5 (17:35) Stability Study of Ohmic and Schottky CdTe Sensors for
X-Ray Photon Counting Pixel- and Strip-Detectors
T. Hirono, H. Toyokawa, M. Kawase, S. Wu, Y. Furukawa, T. Ohata
Japan Synchrotron Research Institule, Japan
R10-6 (17:50) IBIC and Pockels Effect Investigation of Localised
Polarisation in CdTe
D. A. Prokopovich1, M. Ruat2, D. Boardman1, M. I. Reinhard1
1
Australian Nuclear Science and Technology Organisation, Australia; 2European
Synchrotron Radiation Facility, France
R10-7 (18:05) Current Transients in CdTe Radiation Detectors
R. Grill, J. Franc, E. Belas, S. Uxa, V. Dědič, J. Zazvorka, P. Moravec, P.
Hoschl
Charles University, Czech Republic
Wednesday - RTSD Oral Presentations 171
Notes
172 Wednesday - RTSD Oral Presentations Notes
Notes
174 Wednesday - RTSD Oral Presentations Notes
07:00
07:30
N29 Semiconductor Tracking and
Spectroscopy Detectors II
Magic Kingdom Ballroom 1
Session Chairs: Vitaliy A. Fadeyev, UCSC, USA
Erik Heijne, CERN - IEAP/CTU - NIKHEF, Switzerland
N29-1 (08:00) Orthopix: a Novel Compressing Architecture for Pixel
09:30
10:00
10:30
M12: Emission Tomography
Instrumentation (PET,SPECT) 2
08:00-10:00 09:00
M07: Image Processing and
Parametric Imaging
OpenPET Users Group Meeting
Thursday, Nov. 1 08:30
M05: High Resolution &
Preclinical Imaging Instr.,
Techniques and Systems
M08: Simulation and Modeling
of Medical Imaging Systems
N40: New Concepts in
Solid-State Detectors I
08:00
MIC Refresher
Course 2
M06: Imaging in Radiotherapy
N36: Astrophysics and Space
Instrumentation II
11:00
11:30
12:00
12:30
13:00
13:30
14:00
14:30
15:00
15:30
16:00
16:30
Detectors
P. Giubilato, Padova Univ.and CERN, Italy; W. Snoeys, CERN, Switzerland
N29-2 (08:15) Monolithic Pixel Sensors for Fast Particle Trackers in a
Quadruple Well CMOS Technology
S. Zucca1, L. Ratti1, G. Traversi2, S. Bettarini3, F. Morsani4, G. Rizzo3, A.
Gabrielli5, F. Giorgi5
1
University of Pavia and INFN, Italy; 2University of Bergamo and INFN, Italy;
3
University of Pisa and INFN, Italy; 4INFN Pisa, Italy; 5University of Bologna
and INFN, Italy
N29-3 (08:30) Proximity Electrode Signal Readout of High-Purity Ge
Detectors
A. P. Priest, M. Amman, P. N. Luke, K. Vetter, Lawrence Berkeley National
Laboratory, USA; S. Asztalos, K. Sabourov, XIA, LLC, USA
N29-4 (08:45) A Fast Charge Sensitive Amplifier Design for Diamond
Radiation Spectroscopy
M. Fisher-Levine, J. Velthuis, University of Bristol, UK
N29-5 (09:00) Sub-Nanosecond Time of Flight SiC Detectors to Intense
Laser Generated Plasma Radiation
G. Bertuccio1,2, D. Puglisi1,2, D. Margarone3, J. Prokupek3, T. Mocek3, I. J.
Kim4, T. M. Jeong4
1
Politecnico di Milano, Italy; 2National Institute of Nuclear Physics (INFN),
Italy; 3Institute of Physics of the ASCR, Czech Republic; 4Advanced Photonics
Research Institute, Republic of Korea
N29-6 (09:15) Characterizing the New Generation Associated AlphaParticle Detector with High Spatial and Timing Resolution for a D-T
Neutron Generator
X. Zhang1, J. W. Cates1, J. P. Hayward1,2, P. A. Hausladen2
1
University of Tennessee, USA; 2Oak Ridge National Lab, USA
N29-7 (09:30) Performance of Thinned DEPFET Detector Prototypes
Measured at Test Beams
B. Schwenker, Georg August Universitaet Goettingen, Germany
On behalf of the DEPFET Collaboration
N29-8 (09:45) Light High Precision CMOS Pixel Devices Providing
Microsecond Level Timestamping for Future Vertex Detectors
M. Winter, IPHC - IN2P3/CNRS, France
On behalf of the PICSEL team of IPHC-Strasbourg
17:30
Detectors III
18:00
M11: Data Acquisition and
Signal Processing / MultiModality Systems
R14: RTSD Award + CZT
Detectors
17:00
Thursday, Nov. 1 18:30
Scintillation Detectors IV
N33: Radiation Damage
Effects II
Bio-Medical Research
N43: Computing Challenges
N42: Accelerator Technologies
and Beam Line Instrumentation
N29: Semiconductor Tracking
and Spectroscopy Detectors II
N38: Gaseous Detectors III :
LHC upgrades and ILC R&D
NSS Refresher
Course 3
N39: Nuclear Physics
Instrumentation II
N34: Photodetectors and
Radiation Imaging Detectors II
Instrumentation III
R13: CdZnTe 3
M09: POSTER: Data Acquisition
and Signal Processing / Image
Reconstruction Methods 1
M10: POSTER: Simulation and
Modeling of Medical Imaging
Sys. / Multi-Modality Sys.
R12: Alternative Semiconductor
Materials & Neutron Detectors
STIR / SimSET / ASIM
User’s Meeting
N30: Scintillators and Scintillation Detectors III
N32: Trigger and Front-end
Systems I
R11: Alternative Semiconductor Materials
N31: Gaseous Detectors II : New
Techniques
Thursday, 1 November
Grand Ballroom
Center
Grand Ballroom
South
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
Ballroom
Exhibit Hall
North
Exhibit Hall South
Mark Twain
Monorail A+B
Sleeping Beauty
Pavillion
19:00
19:30
GOLD
176 176
Thursday - NSS Oral
Presentations
08:00-09:30 Magic Kingdom Ballroom 2
Session Chairs: William W. Moses, Lawrence Berkeley National
Laboratory, USA
Hee-Joung Kim, Yonsei University, South Korea
N30-1 (08:00) Amplification of the Luminescence Response in Organic
Materials under Ionizing Radiation
M. Michel, L. Rocha, S. Normand
French Alternative Energies and Atomic Energy Commission, France
Thursday - NSS Oral Presentations 177
N30-2 (08:15) Light Collection Process in Multi-Element Scintillation
Detectors
M. Kapusta1, T. Szczesniak2, P. Szupryczynski1, M. Grodzicka2, M.
Schmand1, M. Moszynski2
1
SIEMENS Medical Solution Inc., USA; 2National Center for Nuclear Research,
Poland
N30-3 (08:30) Non-Proportionality Studies Through the Application of
High Isostatic Pressure
M. Gascon1, S. Lam1, R. M. Gaume2, S. Curtarolo3, R. S. Feigelson1
1
Stanford University, USA; 2Univeristy of Central Florida, USA; 3Duke
University, USA
N30-4 (08:45) Scintillation and Light Yield Nonproportionality Studies
down to 5 K
S. Lam, M. Gascon, R. Feigelson, Stanford University, USA
N30-5 (09:00) Measuring the Non Proportional Response of
Scintillators Using a Positron Emission Tomography Scanner
H. E. Rothfuss1,2, J. W. Young1, L. A. Eriksson1,2, S. B. Siegel1, M. E. Casey1,
C. L. Melcher2
1
Siemens, USA; 2University of Tennessee, USA
N30-6 (09:15) Timing Resolution of Single Crystalline ZnO:Ga Films
for Associated Particle Detector Application
J. W. Cates1, J. P. Hayward1,2, X. Zhang1
1
N31 Gaseous Detectors II : New Techniques
Thursday, Nov. 1 08:00-10:00 Magic Kingdom Ballroom 3
Session Chairs: Andy White, University of Texas at Arlington, USA
Ariella Cattai, CERN, Switzerland
N31-1 (08:00, invited) Recent Advances in the Use of Time Projection
Chambers with Integrated Pixels and Their Application in Dark Matter
Searches, Fast Neutron Detection, and Beam Commissioning.
J. A. K. Yamaoka1, M. T. Hedges1, I. Jaegle1, M. D. Rosen1, S. J. Ross1,
I. S. Seong1, T. N. Thorpe1, M. Garcia-Sciveres2, J. A. Kadyk2, K. OlivesMallory2, S. E. Vahsen1
1
University of Hawaii at Manoa, USA; 2Lawrence Berkeley National
Laboratory, USA
N31-2 (08:30) Charge-Focusing Readout of Time Projection Chambers
S. J. Ross, M. T. Hedges, I. Jaegle, M. D. Rosen, I. S. Seong, T. N. Thorpe,
S. E. Vahsen, J. Yamaoka, University of Hawaii, USA; M. Garcia-Sciveres, J.
A. Kadyk, K. Olives-Mallory, Lawrence Berkeley National Lab, USA
N31-3 (08:45) Performance of Glass GEM
T. Fujiwara, M. Uesaka, H. Takahashi
N31-4 (09:00) Studies of Micromegas Chambers Using UV LaserPhotoelectrons
K. Temming, G. Herten, U. Landgraf, W. Mohr, S. Zimmermann
Albert-Ludwigs-Universitaet Freiburg, Germany
N31-5 (09:15) Performance of Gas Electron Multiplier with Deuterium Gas
H. Tokieda1, S. Ota1, T. Hashimoto2, S. Michimasa1, M. Dozono3, H.
Matsubara3, Y. Kikuchi1, T. Gunji1, H. Yamaguchi1, D. M. Kahl1, R.
Akimoto1, H. Hamagaki1, S. Kubono3, T. Uesaka3
1
Center for Nuclear Study, The University of Tokyo, Japan; 2Research Center for
Nuclear Physics, Osaka University, Japan; 3RIKEN (The Institute of Physical and
Chemical Research), Japan
N31-6 (09:30) Development of a Neutrino Tracking Detector Using
GEM Avalanche Light Production in High Density Neon Hydrogen
Mixture
V. Tcherniatine1, Y. Li1,2, V. Jorjadze2, C. Thorn1, R. Galea3, T. Liu2, P.
Rehak1, J. Sondericker2, R. Stroynowski2, W. Willis3, J. Ye2
1
Brookhaven National Laboratory, USA; 2Southern Methodist University, USA;
3
Columbia University, USA
178 Thursday - NSS Oral Presentations N31-7 (09:45) Plasma Panel Sensors for Particle and Beam Detection
P. S. Friedman, Integrated Sensors, LLC, USA; R. Ball, J. W. Chapman, C.
Ferretti, D. S. Levin, C. Weaverdyck, B. Zhou, University of Michigan, USA;
Y. Benhammou, M. B. Moshe, E. Etzion, N. Guttman, Y. Silver, Tel Aviv
University, Israel; J. R. Beene, R. L. Varner, Oak Ridge National Laboratory,
USA; E. H. Bentefour, Ion Beam Applications S.A., Belgium
N32 Trigger and Front-end Systems I
Session Chairs: Patrick J. Le Du, IPNL,IN2P3, France
Tiehui Liu, FNAL, USA
N32-1 (08:00) The ATLAS Trigger Performance and Evolution
N32-2 (08:15) Evolution of the Trigger and Data Acquisition System in
the ATLAS Experiment
N32-3 (08:30) Performance of the CMS Electron and Photon Trigger
A. Thea, ETH, Switzerland
N32-4 (08:45) Trigger-Less Readout of the PANDA Electromagnetic
Calorimeter
M. Kavatsyuk, KVI, University of Groningen, The Netherlands
N32-5 (09:00) DEAP Trigger and Readout Electronics System
F. Retiere, TRIUMF, Canada
On behalf of the DEAP collaboration
N32-6 (09:15) Applications of GPUs to Online Track Reconstruction in
HEP Experiments
S. Amerio1, D. Bastieri2, M. Bauce2, S. Gelain2, W. Ketchum3, Y.-K. Kim4, T.
Liu5, D. Lucchesi2, G. Urso6
1
INFN Padova, Italy; 2University of Padova & INFN, Italy; 3University of
Chicago, USA; 4University of Chicago & Fermilab, USA; 5Fermilab, USA;
6
Orma Software, Italy
N32-7 (09:30) The Scalable Readout System (SRS)
H. Muller, V. S. Martoiu, CERN, Switzerland; A. Tarazona Martinez, J. F.
Toledo Alarcon, UPV Valancia, Spain
N32-8 (09:45) The Trapezoidal Clocking
J. Wu, Fermilab, USA
N33 Radiation Damage Effects II
Session Chairs: Alexandra Junkes, Brown University, USA
Doris Eckstein, Deutsches Elektronen-Synchrotron
DESY, Germany
N33-1 (10:30, invited) Silicon Radiation Damage Overview at the LHC
P. Collins, CERN, Switzerland
On behalf of the Inter-Experiment Working Group on Radiation Damage in
Silicon Detectors
N33-2 (11:00) Radiation Damage Effects in the LHCb Vertex Locator
J. Harrison, University of Manchester, United Kingdom
On behalf of the LHCb VELO Group
N33-3 (11:15) Comparison of the Performance of Irradiated n-in-p
Pixel Sensors of Different Active Thicknesses Irradiated up to a Fluence
of 1e16 neq/cm^2 and Development of the SLID Interconnection
Technique
A. Macchiolo1, L. Andricek2, H.-G. Moser2, R. Nisius1, R. H. Richter2, P.
Weigell1
1
Max-Planck-Institut fuer Physik, Germany; 2MPI Semiconductor Laboratory,
Germany
N33-4 (11:30) New Results of the ATLAS Upgrade Planar Pixel Sensors
R&D Project
D. Muenstermann, CERN, Switzerland
On behalf of the ATLAS Upgrade Planar Pixel Sensors R&D Project
N33-5 (11:45) Towards Radiation Hard Sensor Materials for the CMS
Tracker Upgrade
G. Steinbrueck, University of Hamburg, Germany
On behalf of the CMS Tracker Collaboration
N33-6 (12:00) Gamma-Ray Induced Radiation Damage in Large Size
BGO Crystals for the SuperB Calorimeter
S. Fiore1, I. Dafinei2, R. Faccini1,2, E. Furfaro2, D. Pinci2
1
Sapienza Universita’ di Roma, Italy; 2INFN sezione di Roma, Italy
N33-7 (12:15) Electron Radiation Damage Effects on SWCNT Thin
Films
J. S. Best1, J. W. McClory1, S. A. Francis1, C. D. Cress2, J. C. Petrosky1
1
Air Force Institute of Technology, USA; 2Naval Research Laboratory, USA
Detectors II
Session Chairs: Sergey Barsuk, LAL Orsay, France
Michael Lerch, University of Wollongong, Australia
N34-1 (10:30, invited) Recent Progress in Solid-State Photodetectors
and Their Applications
V. Puill, LAL, France
N34-2 (11:00) Development of Single Photon Avalanche Diodes (SPAD)
Arrays in Teledyne Dalsa High Voltage CMOS 0.8 um for 3D Integrated
Circuit (3DIC)
B.-L. Berube1, V.-P. Rheaume1, A. Corbeil-Therrien1, A. Boisvert1, G.
Carini2, S. Charlebois1, R. Fontaine1, J.-F. Pratte1
1
Universite de Sherbrooke, Canada; 2SLAC National Laboratory, USA
N34-3 (11:15) BackSPAD - Back-Side Illuminated Single-Photon
Avalanche Diodes: Concept and Preliminary Performances
D. Durini, S. Weyers, M. Sthlmeyer, A. Goehlich, W. Brockherde, U.
Paschen, H. Vogt, Fraunhofer IMS, Germany; S. Tisa, Micro Photon Device
S.r.l., Italy; F. Villa, D. Bronzi, A. Tosi, F. Zappa, Politecnico di Milano, Italy
N34-4 (11:30) Multi-Channel Digital SiPMs: Concept and Analysis
S. Mandai, E. Charbon
Technology University of Delft, Netherlands
N34-5 (11:45) Characterization of 2x2ch MPPC Array at Wide
Temperature Range (-40 st C to +22 st C)
M. Grodzicka, M. Moszyński, T. Szczęśniak, W. Czarnacki, M. Szawłowski,
K. Grodzicki, National Centre for Nuclear Research (NCBJ), Poland; J. Baszak,
Hamamatsu Photonics Deutschland GmbH, Germany
N34-6 (12:00) Studies of Silicon Photomultipliers with Bulk Integrated
Quench Resistor Fabricated at MPI Semiconductor Laboratory
C. Jendrysik, L. Andricek, G. Liemann, H.-G. Moser, J. Ninkovic, R.
Richter
Max Planck Institute for Physics, Germany
N34-7 (12:15) The Interpolating SiPM - a Novel Device for Position
Resolved Photon Cluster Detection
P. Fischer
Institute for Computer Engineering, Heidelberg University, Germany
180 Thursday - NSS Oral Presentations N35 High Energy Physics Instrumentation III
Session Chairs: Christophe de la Taille, LAL/IN2P3/CNRS, France
Felix Sefkow, DESY, Germany
N35-1 (10:30) Final Concept and Performance of the Electromagnetic
Calorimeter of the PANDA Detector at FAIR
R. W. Novotny, 2nd Physics Institute, University Giessen, Germany
N35-2 (10:45) Development of W+Si Based Electromagnetic
Calorimeter for the Upgrade of the LHC-ALICE Experiment
T. Gunji, S. Hayashi, H. Hamagaki, Y. Hori, Y. Sekiguchi
Center for Nuclear Study, the University of Tokyo, Japan
N35-3 (11:00) KPiX: a 1024 Channel Readout ASIC for the ILC
J. Brau1, M. Breidenbach2, A. Dragone2, G. Fields3, R. Frey1, D. Freytag2, M.
Freytag2, C. Gallagher1, G. Haller2, R. Herbst2, B. Holbrook3, R. Lander3, A.
Moskaleva3, C. Neher3, T. Nelson2, S. Schier4, B. Schumm4, D. Strom1, M.
Tripathi3, M. Woods3
1
University of Oregon, USA; 2SLAC National Accelerator Laboratory, USA;
3
University of California, Davis, USA; 4Santa Cruz Institute for Particle Physics
and the University of California at Santa Cruz, USA
N35-4 (11:15) Response Evolution of the CMS ECAL and R&D Studies
for Electromagnetic Calorimetry at the High-Luminosity LHC
F. Nessi-Tedaldi, ETH Zurich, Switzerland
On behalf of the CMS ECAL group
N35-5 (11:30) Interactions of Hadrons in the CALICE Silicon Tungsten
Electromagnetic Calorimeter
R. Poeschl, LAL Orsay, France
N35-6 (11:45) Shower Development of Particles with Momenta of 1 to
10 GeV in a Highly Granular Tungsten Analog Hadron Calorimeter
A. Lucaci-Timoce, CERN, SWITZERLAND
N35-7 (12:00) Measurement of the Time Structure of Hadronic Showers
in Steel and Tungsten with Imaging Calorimeters
F. Simon, Max-Planck-Institut fuer Physik, Germany
N35-8 (12:15) The SuperB Muon Detector, Status and Perspectives
W. Baldini, INFN-Ferrara, Italy
On behalf of the SuperB Muon Detector Group
N36 Astrophysics and Space Instrumentation II
Session Chairs: Daniel Haas, SRON Netherlands Institute for Space
Research,
Jean-François Pratte, Université de Sherbrooke, Canada
N36-1 (14:00) POLAR: a Gamma-Ray Burst Polarimeter in Space
S. Orsi, University of Geneva, Switzerland
On behalf of the POLAR Collaboration
N36-2 (14:15) Balloon-Borne Hard X-Ray Polarimetry with PoGOLite
M. Pearce, Kungl Tekniska Hgskolan, KTH, Sweden
On behalf of the PoGOLite Collaboration
N36-3 (14:30) Balloon-Flight Results of a FAst Compton TELescope
(FACTEL)
M. G. Julien, J. M. Ryan, P. F. Bloser, J. S. Legere, C. M. Bancroft, M. L.
McConnell, University of New Hampshire, US; R. M. Kippen, S. Tornga, Los
Alamos National Laboratory, US
N36-4 (14:45) Specification Design and New Results of X-ray
Astronomical SOI Pixel Detector
A. Takeda1,2, Y. Arai2, S. G. Ryu3, S. Nakashima3, T. G. Tsuru3, T. Imamura4,
T. Ohmoto4, A. Iwata4
1
the Graduate University for Advanced Studies (SOKENDAI), Japan; 2High
Energy Accelerator Research Organization (KEK), Japan; 3Kyoto Univ., Japan;
4
A-R-Tec Corp., Japan
N36-5 (15:00) The Large Observatory for X-Ray Timing: the Use of
Large Area Silicon Drift Detectors in Space
J.-W. D. Herder, SRON, Netherlands Institute for Space Research, the
Netherlands; M. Feroci, INAF/IASF-Roma, Itly; A. Vacchi, N. Zampa, G.
Zampa, A. Rashevsky, INFN, Italy
N36-6 (15:15) High-Performance Large-Area Ultra-Thin X-Ray Window
P. T. Torma1, P. Kostamo2, H. Sipila3, M. Mattila4, J. Kostamo4, E. Kostamo4,
H. Lipsanen1
1
Micronova, Aalto University, Finland; 2Oxford Instruments Analytical Oy,
Finland; 3Heikki Sipila Oy, Finland; 4HS Foils Oy, Finland
N36-7 (15:30) Development of a Quasi-Monoenergetic 6 MeV Gamma
Facility
S. F. Nowicki1,2, S. D. Hunter1, J. G. Bodnarik1, M. P. Dion1, A. M.
Parsons1, J. Schweitzer3, S. Son1
1
NASA GSFC, USA; 2University of Michigan, USA; 3University of Connecticut,
USA
N36-8 (15:45) The Sirad Detector to Study Cosmic Rays Inside and
Outside the International Space Station
G. Masciantonio, INFN - sezione Tor Vergata, Italy
N37 Instrumentation for Bio-Medical
Research
Session Chairs: Erika Garutti, University of Hamburg, Germany
N37-1 (14:00) The CaLIPSO Detector Project for Enhanced PET
Imaging.
D. F. Yvon, J.-P. Renault, G. Tauzin, P. Verrecchia, CEA Saclay, France
N37-2 (14:15) Characterization of a Recently Developed SiPM for PET
Applications
F. R. Schneider1, D. Renker1, F. Wiest2, S. Ziegler1
1
Technische Universitaet Muenchen, Germany; 2KETEK GmbH, Germany
N37-3 (14:30) CMOS APS in Pre-Clinical Science: Next Generation
Disruptive Technology for Multi-Modality Imaging
M. Esposito1, A. Bailey1, J. Newcombe1, T. Anaxagoras2, N. M. Allinson2, K.
Wells1
1
University of Surrey, U.K.; 2University of Lincoln, U.K.
N37-4 (14:45) Monitoring of Ion Beam Range by Tracking of Secondary
Ions: First Measurements in a Patient-like Phantom
M. Martisikova1,2, J. Jakubek3, K. Gwosch2, B. Hartmann1,2, J. Telsemeyer1,2,
S. Pospisil3, O. Jaekel1,2,4
1
Heidelberg University Hospital, Germany; 2German Cancer Research Center
- DKFZ, Germany; 3Czech Technical University in Prague, Czech Republic;
4
Heidelberger Ionenstrahl-Therapiezentrum, Germany
N37-5 (15:00) The KENTROS Detector for Identification and Kinetic
Energy Measurements of Nuclear Fragments at Polar Angles Between 5
and 90 Degrees
B. Golosio1,2, 1Universita’ di Sassari, Italy; 2Istituto Nazionale di Fisica
Nucleare, Sezione di Cagliari, Italy
On behalf of the FIRST Collaboration
N37-6 (15:15) A Quality Assurance System for HDR Brachytherapy
A. Espinoza1, M. Petasecca1, B. Beeksma1, D. Cutajar1, S. Corde2, S.
Downes2, M. Jackson3, J. Bucci3, A. B. Rosenfeld1
1
University of Wollongong, Australia; 2Prince of Wales Hospital, Australia; 3St
George Hospital, Australia
182 Thursday - NSS Oral Presentations N37-7 (15:30) Response of Silicon Diodes for Synchrotron Radiation
I. E. Anokhin1, M. Lerch2, M. Petasecca2, A. Rosenfeld2, O. Zinets1
1
Institute for Nuclear Research, Ukraine; 2University of Wollongong,
AUSTRALIA
N37-8 (15:45) A New Space Dosimeter, PS-TEPC: Position-Sensitive
Tissue-Equivalent Proportional Chamber
S. Sasaki, Y. Kishimoto, K. Saito, K. Takahashi, High Energy Accelerator
Research Organization, Japan; T. Doke, Waseda Univ., Japan; K. Miuchi,
Kobe Univ., Japan; T. Fuse, A. Nagamatsu, H. Matsumoto, JAXA, Japan; Y.
Uchihori, NIRS, Japan; K. Terasawa, Keio Univ., Japan
N38 Gaseous Detectors III : LHC upgrades
and ILC R&D
Session Chairs: Paul Colas, CEA/IRFU, France
Marcel Demarteau, Argonne National Laboratory, USA
N38-1 (14:00) Application of Large Scale MPGD Technology to Digital
Hadron Calorimetry
A. P. White, J. Yu, S. Park, M. Sosebee, D. Pray, S. Kahled, B. Givens
University of Texas at Arlington, USA
N38-2 (14:30) Development of Large Area Gas Electron Multiplier
(GEM) Chambers
J. Yu, B. R. Givens, Y. W. Y. Ng, S. A. Khaled, S. Park, D. S. Pray, M.
Sosebee, A. P. White
University of Texas, USA
N38-3 (14:45) High Rate GRPC for Muon Detectors Upgrade at LHC
I. B. Laktineh, IPNL-UCBL-IN2P3, France
N38-4 (15:00) R&D on a TPC for a TeV Linear Collider
C. Brezina, University of Bonn, Germany
On behalf of the LCTPC Collaboration
N38-5 (15:15) Test and Calibration of the Micromegas-TPC Modules
for an ILC Detector
W. Wang, CEA-Saclay, France
On behalf of the LCTPC Collaboration
N38-6 (15:30) Construction and Commissioning of Full-Size MPGDBased Prototypes for CMS High-Eta Muon System
C. Armaingaud
Ecole Nationale Superieure de Physique de Strasbourg, France
N38-7 (15:45) RD51 Collaboration - Micro Pattern Gas Detector
Technologies and Applications
L. Ropelewski, CERN, Switzerland
On behalf of the RD51 Collaboration
N39 Nuclear Physics Instrumentation II
Session Chairs: Jae Yu, University of Texas, USA
Uwe Bratzler, CERN and TMU, Switzerland
N39-1 (14:00, overview) The Calorimeter Systems for the sPHENIX
Experiment at RHIC
C. L. Woody, Brookhaven National Lab, USA
N39-2 (14:30) Innovative Phoswich Concept Detector for the PARIS
Photon Calorimeter
O. Dorvaux1, C. Bonnin1, L. Charles1, M. Ciemala2, A. Czermak2, C.
Finck1, B. Genolini3, G. Hull3, M. Jastrząb2, D. Jenkins4, M. Kmiecik2,
S. Kumar5, A. Maj2, C. Mathieu1, I. Matea3, I. Mazumdar6, P. Mdina1, C.
Mehdi1, V. Nanal6, P. Peaupardin1, J. Peyre3, J. Pouthas3, M. Rousseau1, O.
Roberts4, C. Schmitt7, O. Stezowski3, J.-P. Wieleczko7, T. Zerguerras3, M.
Zieblinski2, S. Brambilla8
Institut Pluridisciplinaire Hubert Curien/University of Strasbourg, France;
IFJ PAN, Poland; 3Institut de Physique Nucleaire, France; 4York University,
United Kingdom; 5Bhabha Atomic Research Centre, India; 6Tata Institute of
Fundamental Research, India; 7Grand Accelerateur National d’Ions Lourds,
France; 8Istituto Nazionale di Fisica Nucleare, Italy
N39-3 (14:45) Design and Function of an Electron Attachment
Spectrometer
G. M. Orchard, A. J. Waker
University of Ontario Institute of Technology, Canada
N39-4 (15:00) Measurements of Electron Diffusion Coefficients in
Liquid Argon for Large LAr Time-Projection Chambers
Y. Li, V. Tcherniatine, C. Thorn, W. Morse, F. Lanni, T. Tsang, T. Rao, S.
Rescia, J. Sondericker, S. Duffin, J. Farrell, A. Hoffman, R. Burns
N39-5 (15:15) The Fission TPC Project
J. Ruz Armendariz, Lawrence Livermore National Laboratory, US
On behalf of the NIFFTE Collaboration
N39-6 (15:30) A Dual-Phase Argon Ionization Chamber with Ultimate
Sensitivity for Detection of Low-Energy Nuclear Recoils
S. Sangiorgio1, A. Bernstein1, J. Coleman2, M. Foxe3, C. Hagmann1, T. H.
Joshi4,1, I. Jovanovic3, K. Kazkaz1, K. Mavrokoridis2, S. V. Pereverzev1, P.
Sorensen1
1
Lawrence Livermore National Laboratory, CA; 2University of Liverpool, UK;
3
The Pennsylvania State University, PA; 4University of California, CA
N39-7 (15:45) Application of a Gd2Si2O7 Scintillator Plate for an
Alpha Particle Monitor
T. Shimaoka1, J. H. Kaneko1, K. Izaki2, Y. Tsubota1, M. Higuchi1, S.
Nishiyama1
1
Hokkaido University, Japan; 2JAEA, Japan
1
2
N40 New Concepts in Solid-State Detectors I
Session Chairs: Marc Winter, CNRS-IPHC-DRS, France
Susanne Kuehn, University of Freiburg, Germany
N40-1 (16:30) High Fill Factor Digital Silicon Photomultiplier
Structures in 130nm CMOS Imaging Technology
R. J. Walker, E. A. G. Webster, R. K. Henderson
The University of Edinburgh, UK
N40-2 (16:45) Toward the Realization of 3D Single Photon Counting
Modules for Radiation Instrumentation
J.-F. Pratte, M.-A. Tetrault, B.-L. Berube, A. Corbeil Therrien, V.-P.
Rheaume, A. Boisvert, E. Desaulniers Lamy, S. A. Charlebois, R. Fontaine
Universite de Sherbrooke, Canada
N40-3 (17:00) Particle Detection with DEPFET Arrays in Gated Mode
R. H. Richter1, L. Andricek1, A. Baehr1, K. Gaertner2, C. Kiesling3, C.
Koffmane1, H. Krueger4, C. Kreidl5, H.-G. Moser1, F. Mueller1, J. Ninkovic1,
I. Peric5, S. Rummel6, J. Scheirich7, B. Schwenker8, F. Wilk8
1
Max-Plank-Institut Halbleiterlabor, Germany; 2WIAS, Germany; 3Max-PlankInstitut fuer Physik, Germany; 4Physikalisches Institut, Germany; 5Institut fr
Technische Informatik, Germany; 6Fakultaet fuer Physik, Germany; 7Institute of
Particle and Nuclear Physics, Czech Republic; 8II. Physikalisches Institut, Germany
N40-4 (17:15) Comparative Timing Performances of S-CVD Diamond
Detectors with Different Particle Beams and Readout Electronics.
N. Randazzo1, S. Aiello1, G. Chiodini1, G. A. P. Cirrone1, G. M. Cuttone1,
M. De Napoli1, V. Giordano1, S. Kwan2, E. Leonora1, F. Longhitano1, D. Lo
Presti1,3, L. Moroni1, C. Pugliatti1,3, R. R. Rivera2, V. Scuderi1, V. Sipala1,4, C.
Stancampiano1, C. Tuve’1,3, L. Upplegger2
1
INFN, Italy; 2FNAL, USA; 3Universita’ di Catania, Italy; 4Universita’ di
Sassari, Italy
N40-5 (17:30) The Tipsy Single Soft Photon Detector and the Trixy
Ultrafast Tracking Detector
H. van der Graaf, Nikhef, The Netherlands
184 Thursday - NSS Oral Presentations N40-6 (17:45) Novel Topologies of Multi-Linear Silicon Drift Detectors
for Position Sensing with Energy Discrimination
A. Castoldi1,2, C. Guazzoni1,2, D. Mezza1,2, R. Hartmann3, L. Strueder4,5,6
1
Politecnico di Milano, Italy; 2INFN, Italy; 3PNSensor GmbH, Germany; 4Max
Planck Institut fur Extraterrestriche Physik, Germany; 5Max Planck Institut
Halbleiterlabor, Germany; 6Universitat Siegen, Germany
N40-7 (18:00) MOS Entrance Window for a Silicon X-Ray Detector
D. Hullinger, Moxtek, Inc., USA
N40-8 (18:15) Gamma Radiation Dosimetry with Al/TeO2/n-Si/Al
MOS Capacitor
S. L. Sharma, T. K. Maity, J. Sarkar, Indian Institute of Technology, Kharagpur,
India; G. Chourasiya, J. C. Vyas, BARC, India
Detectors IV
Session Chairs: Nerine Cherepy, Lawrence Livermore National
Laboratory, USA
Chuck Melcher, University of Tennessee, USA
N41-1 (16:30) Scintillation Properties of Ce Doped Cs2LiLaBr6-xClx
U. Shirwadkar, R. Hawrami, J. Glodo, E. van Loef, K. Shah
Radiation Monitoring Devices, Inc, USA
N41-2 (16:45) Comparison of Different Cs2LiYCl6:Ce Crystals: Energy
Resolution and Pulse Shape Dependences on Temperature
C. Plettner, F. Scherwinski, G. Pausch, R. Lentering, Y. Kong, A. Kreuels,
M. Neuer, J. Stein
FLIR Radiation GmbH, Germany
N41-3 (17:00) Bismuth-Loaded Plastic Scintillators for Gamma
Spectroscopy and Neutron Active Interrogation
N. Cherepy, R. Sanner, T. Tillotson, S. Payne, B. Sturm, D. Slaughter
N41-4 (17:15) Advanced Plastic Scintillators with Pulse Shape
Discrimination
E. V. Van Loef, G. Markosyan, U. Shirwadkar, K. S. Shah
Radiation Monitoring Devices, Inc., USA
N41-5 (17:30) Study and Understanding of n/γ Discrimination
Processes in Organic Plastic Scintillators
P. Blanc1,2, M. Hamel1, L. Rocha1, S. Normand1, R. Pansu1
1
Alternative Energies and Atomic Energy Commission, France; 2Laboratoire de
Photophysique et de Photochimie Supramolculaire et Macromolculaires UMR
8531, France
N41-6 (17:45) Inorganic Single Crystalline Fibers for Dual-Readout
Calorimetry
K. Pauwels1,2, E. Auffray1, C. Dujardin2, K. Lebbou2, M. Lucchini1, D.
Perrodin3, X. Xu2, P. Lecoq1
1
CERN, Switzerland; 2Universite Lyon 1, France; 3Fibercryst, France
N41-7 (18:00) The Scintillation in Gadolinium Doped Lead Fluoride
Crystals
R. Mao, H. Li, G. Ren, X. Chen, Shanghai Institute of Ceramics, Chinese
Academy of Sciences, CHINA; L. Zhang, R.-Y. Zhu, California Institute of
Technology, USA
N41-8 (18:15) A Study of CaMoO4 Crystals for the AMoRE Experiment
J. H. So, Kyungpook National Universty, Korea
On behalf of the AMoRE collaboration
N42 Accelerator Technologies and Beam
Line Instrumentation
Session Chairs: Serge Duarte Pinto, CERN, Switzerland
Marc C. Ross, SLAC National Accelerator Lab, USA
N42-1 (16:30) X-Ray Detection Using SOI Monolithic Sensors at a
Compact High-Brightness X-Ray Source Based on Inverse Compton
Scattering
T. Miyoshi1, Y. Arai1, M. Fukuda1, J. Haba1, H. Hayano1, Y. Honda1, K.
Sakaue2, H. Shimizu1, A. Takeda3, J. Urakawa1, K. Watanabe1
1
HIGH ENERGY ACCELERATOR RESEARCH ORGANIZATION, Japan;
2
Waseda University, Japan; 3The Graduate University for Advanced Studies
(SOKENDAI), Japan
N42-2 (16:45) A Neutron Flux Monitor with Gamma Discrimination
for Reactor Neutron Beam Facility
P. Kandlakunta, P. Mulligan, D. Turkoglu, L. Cao
The Ohio State University, USA
N42-3 (17:00) SLAC Electron Beam Test Facilities from 5 MeV to 23
GeV
C. Hast, SLAC National Accelerator Laborator, USA
N42-4 (17:15) Characterization of a RF-Driven Negative Ion Source for
an Associated Particle Imaging Neutron Generator
A. J. Antolak1, K. N. Leung1,2, D. H. Morse1
1
Sandia National Laboratories, USA; 2University of California, USA
N42-5 (17:30) Characterization of a Photoneutron Source for Intense
Pulsed Active Detection*
J. C. Zier1, R. J. Allen1, J. P. Apruzese2, R. J. Commisso1, D. D.
Hinshelwood1, A. L. Hutcheson1, S. L. Jackson1, L. J. Mitchell1, D.
Mosher2, D. P. Murphy1, D. G. Phipps1, B. F. Phlips1, J. W. Schumer1, S. B.
Swanekamp1, R. S. Woolf3, E. A. Wulf1, F. C. Young2
1
Naval Research Laboratory, USA; 2Independent contractor for NRL through L-3
Services, Inc., USA; 3Research Associate, National Research Council, USA
N42-6 (17:45) ELIMED a New Concept of Hadrontherapy with LaserDriven Beams
P. G. A. Cirrone1, G. Cuttone1, G. Korn2, M. Maggiore1, D. Margarone2, L.
Calabretta1, S. Cavallaro3, L. Celona1, M. Favetta1, S. Gammino1, T. Levato2,
G. Malfa3, L. Manti4,1, J. Prokupek2, M. Renis3, F. Romano1,5, F. Schillaci1,
B. Tomasello3, L. Torrisi1,6, A. Tramontana1
1
Istituto Nazionale di Fisica Nucleare, Italy; 2Institute of Physics of the ASCR
ELI-Beamlines project, Czech Republic; 3University of Catania University of
Catania, Italy; 4University, ItalyManti; 5Museo Storico della Fisica e Centro
Studi e Ricerche, Italy; 6University of Messina, Italy
N43-4 (17:15) A Visualization Application on Mobile Devices for
Geant4-Based Radiotherapy Simulation
A. Kimura, Ashikaga Institute of Technology, Japan; S. Tanaka, K. Hasegawa,
Ritsumeikan University, Japan; T. Sasaki, High Energy Accelerator Research
Organization, Japan
N43-5 (17:30) Managing the Computing-Intensive Image
Reconstruction for the BNL Plant PET Scanner
M. L. Purschke1, M. Budassi2, T. Cao2, J. Fried1, B. Ravindranath3, D.
Schlyer1, S. P. Stoll1, P. Vaska2, C. Woody1
1
Brookhaven National Lab, USA; 2Stony Brook University, USA; 3Washington
University, USA
N43-6 (17:45) Design and Development of the Software and Computing
Framework for the L1/L2 Online PC Farm of the NA62 Experiment at
CERN
J. Kunze1, R. Fantechi2, G. Lamanna3, M. Sozzi4, R. Wanke1
1
Institute of Physics, University of Mainz, Germany; 2Sezione dell’INFN di Pisa,
Italy; 3CERN, Switzerland; 4University and Sezione dell’INFN di Pisa, Italy
N43-7 (18:00) Methods and Computing Challenges of the Realistic
Simulation of Physics Events in the Presence of Pile-up in the ATLAS
Experiment
P. Clark, University of Edinburgh, UK
N43-8 (18:15) The ZEUS Data Preservation Project.
K. Wichmann, DESY, Germany
On behalf of the ZEUS Collaboration
N43-9 (18:30) A Parallel Framework for the SuperB Super Flavor
Factory
S. Longo1, F. Bianchi1, G. Donvito1, B. Santeramo1, V. Ciaschini1, F.
Giacomini1, A. Gianoli2, E. Luppi1, M. Manzali1, L. Tomassetti1, M. Rama1,
G. Russo1, S. Pardi1, D. Del Prete1, R. Stroili3, A. Fella1, A. Perez4, A. Di
Simone5, S. Luitz6, M. Corvo7, P. Franchini1
1
INFN, Italy; 2Universita’ di Ferrara, Italy; 3Universita’ degli Studi di Padova,
Italy; 4Laboratoire de l’Accelerateur Lineaire, France; 5Universita’ degli Studi di
Roma Tor Vergata, Italy; 6SLAC, California; 7CNRS, France
N43 Computing Challenges
Session Chairs: Maria Grazia Pia, INFN Genova, Italy
Lorenzo Moneta, CERN, Switzerland
N43-1 (16:30) Evolving LHC Data Processing Frameworks for Efficient
Exploitation of New CPU Architectures
P. Mato, B. Hegner
CERN, Switzerland
N43-2 (16:45) Chest CT Automatic Analysis for Lung Nodules
Detection Implemented on a GPU Computing System
M. E. Fantacci1,2, F. Bagagli1, N. Camarlinghi1,2, P. Cerello2, A. Retico2
1
Universita’ di Pisa, Italy; 2INFN, Italy
N43-3 (17:00) CMS Storage Federations over Grids and Clouds
D. Bonacorsi, University of Bologna, Italy
186 Thursday - NSS Oral Presentations Thursday - NSS Oral Presentations 187
Thursday - MIC Oral
Presentations
M06-3 (08:45) TOF-PET for Quality Assurance in Proton Therapy: a
M05 High Resolution & Preclinical Imaging
Instrumentation, Techniques and Systems
Thursday, Nov. 1 08:15-10:00 Grand Ballroom Center
Session Chairs: Benjamin M. W. Tsui, Johns Hopkins University, USA
Jae Sung Lee, Seoul National University College of
Medicine, South Korea
M05-1 (08:15) Employing Line-Laser Illumination for 3D Fluorescence
Imaging and Tomography in a Tri-Modal SPECT-CT-OT Imaging
System
L. Cao, J. Peter, German Cancer Research Center, Germany
M05-2 (08:30) pawPET: a High Sensitivity, High Resolution PET
Scanner for Rodent Paws
F. Godinez1, A. J. Chaudhari1, J. Fung1, Y. Yang1, R. Farrell2, S. KunduRaychaudhuri1, S. P. Raychaudhuri1, R. D. Badawi1
1
University of California Davis, USA; 2Radiation Monitoring Devices Inc., USA
M05-3 (08:45) Characterization of a Small-Animal High-Purity
Germanium SPECT System
L. C. Johnson, O. Ovchinnikov, T. E. Peterson, Vanderbilt University, USA
M05-4 (09:00) Comparison of Two Small Animal PET Scanners: Pinhole
Collimation Vs. Electronic Collimation
M. D. Walker1, R. R. Ramakers2,3, S. Blinder1, K. Dinelle1, M.
Shirmohammad1, M. C. Goorden3, F. J. Beekman2,3, V. Sossi1
1
University of British Columbia, Canada; 2MI Labs, The Netherlands; 3Delft
University of Technology, The Netherlands
M05-5 (09:15) Towards a Sub-Millimeter PET Prototype with
Continuous LYSO Crystals and SiPM Matrices
G. Llosa1, P. Barrillon2, J. Barrio1, M. G. Bisogni3, J. Cabello1, A. Del
Guerra3, A. Etxebeste1, J. E. Gillam1, C. Lacasta1, C. de La Taille2, J. F.
Oliver1, M. Rafecas1, C. Solaz1, V. Stankova1
1
Instituto de Fisica Corpuscular (IFIC/CSIC-UVEG), Spain; 2Laboratoire de
l’Accelerateur Lineaire, France; 3Universita di Pisa and INFN Pisa, Italy
M05-6 (09:30) Time-over-Threshold Based Crystal Identification in
Phoswich Detectors
H. Bouziri, K. Koua, L. Arpin, M. W. Ben Attouch, S. Panier, M. Abidi, C.
Paulin, C. Pepin, J.-F. Pratte, R. Lecomte, R. Fontaine,
Université de Sherbrooke, Canada
M05-7 (09:45) Evaluation of Easily Implementable Inter-Crystal Scatter
Recovery Schemes in High-Resolution PET Imaging
J. Clerk-Lamalice, M. Bergeron, C. Thibaudeau, R. Fontaine, R. Lecomte
M06 Imaging in Radiotherapy
Thursday, Nov. 1 Session Chairs: 08:15-10:00 Grand Ballroom South AB
Alberto Del Guerra, University Pisa, Italy
Joel Karp, University of Pennsylvania, USA
M06-1 (08:15) Towards Using a Monolithic Active Pixel Sensor for In-
Vivo Beam Monitoring of Intensity Modulated Radiotherapy
R. F. Page, University of Bristol, UK
On behalf of the BEAMView Collaboration
M06-2 (08:30) A Small Prototype of a Single-Ring OpenPET
T. Yamaya1, E. Yoshida1, S. Kinouchi1,2, Y. Nakajima3, F. Nishikido1, Y.
Hirano1, H. Tashima1, H. Ito1, M. Suga2, H. Haneishi2, S. Sato1, T. Inaniwa1
1
National Institute of Radiological Sciences, Japan; 2Chiba University, Japan;
3
Tokyo Institute of Technology, Japan
188 Thursday - MIC Oral Presentations Clinical Case Study
D. C. Oxley1, A. K. Biegun1,2, A. J. van der Borden3, S. Brandenburg1, P.
Cambraia Lopes2, F. Diblen4, A. van der Schaaf3, S. Vandenberghe4, A. A.
van ‘t Veld3, D. R. Schaart2, P. Dendooven1
1
University Of Groningen, The Netherlands; 2Delft University of Technology, The
Netherlands; 3University Medical Center Groningen, The Netherlands; 4Ghent
University, Belgium
M06-4 (09:00) Measurement-Based Kilo-Voltage Beam Characterization
and Dose Quantification for Radiotherapy Image Guidance
K. McMillan, A. Michailian, D. Ruan
University of California, Los Angeles, USA
M06-5 (09:15) Comparison Study of RPC and Crystal Based PET
Systems for Hadron Therapy Monitoring
F. Diblen1, H. Rohling2, I. Torres-Espallardo3, P. Solevi3, J. Gillam3, S.
Espana1, S. Vandenberghe1, D. Watts4, F. Fiedler5, M. Rafecas3,6
1
Ghent University-IBBT-IBiTech, Belgium; 2OncoRay, Technische Universität
Dresden, Germany; 3IFIC (Universitat de València/CSIC), Spain; 4TERA
Foundation, Italy; 5Helmholtz-Zentrum Dresden-Rossendorf, Germany;
6
Universitat de Valencia, Spain
M06-6 (09:30) PRIMA Proton Imaging for Clinical Application
C. Talamonti1,2, M. Bruzzi2,3, M. Bucciolini1,2, G. A. P. Cirrone2, C.
Civinini2, G. Cuttone2, D. Lo Presti4,2, S. Pallotta1,2, N. Randazzo2, M.
Scaringella3, V. Sipala2,5, C. Stancampiano4,2, M. Zani1,2
1
University of Florence, Italy; 2Istituto Nazionale di Fisica Nucleare, Italy;
3
Univerisity of Florence, Italy; 4Universit degli Studi di Catania, Italy; 5Universit
degli Studi di Sassari, Italy
M06-7 (09:45) Experimental Verification of a Semiautomatic Evaluation
Tool for Particle Therapy PET
S. Helmbrecht1, W. Enghardt1,2, K. Laube1, F. Fiedler2
1
TU Dresden, Germany; 2Helmholtz-Zentrum Dresden-Rossendorf, Germany
M07 Image Processing and Parametric
Imaging
Session Chairs: Andrew J. Reader, McGill University, Canada
Dimitris Visvikis, U650 INSERM, France
M07-1 (10:30) Kinetic Parameter Estimation in Dynamic PET with a
Sparsity-Regularized Mixture Model
Y. Lin1, J. P. Haldar1, Q. Li2, R. M. Leahy1
1
University of Southern California, USA; 2Massachusetts General Hospital, USA
M07-2 (10:45) Rapid Multi-Tracer PET Using Reduced Parameter Space
Kinetic Modeling
D. J. Kadrmas, M. B. Oktay, University of Utah, USA
M07-3 (11:00) Fourth-Order Anisotropic Diffusion of Dynamic PET
Images
C. Tauber, UMRS INSERM U930 - Universite de Tours, France; P. Spiteri,
IRIT-ENSEEIHT UMR 5505 - Universite de Toulouse, France; S. Stute, I.
Buvat, IMNC, IN2P3, UMR 8165 CNRS - Paris 7 and Paris 11, France
M07-4 (11:15) PET Myocardial Blood Flow from Dynamic PET and
Independent Component Analysis
A. Karpikov1, H. Tagare2, T. Mulnix1, C. Liu1, R. E. Carson1
1
Yale University, PET Center, USA; 2Yale University, USA
M07-5 (11:30) Novel Parametric PET Image Quantification Using
Texture and Shape Analysis
A. Rahmim1, J. Coughlin1, M. Gonzalez2, C. J. Endres1, Y. Zhou1, D. F.
Wong1, R. L. Wahl1, V. Sossi2, M. G. Pomper1
1
Johns Hopkins University, USA; 2University of British Columbia, Canada
Thursday - MIC Oral Presentations 189
M07-6 (11:45) Bilateral Filter for Image Derived Input Function in
MR-BrainPET
N. A. da Silva1, M. Gaens2, U. Pietrzyk2, P. Almeida1, H. Herzog2
1
University of Lisbon, Faculty of Sciences, Portugal; 2Institute of Neuroscience
and Medicine, Germany
M07-7 (12:00) Fully-Automated Segmentation of the Striatum in the
PET/MR Images Using Data Fusion
I. S. Klyuzhin, M. Gonzalez, V. Sossi
University of British Columbia, Canada
M07-8 (12:15) Realtime Markerless Rigid Body Head Motion Tracking
Using the Microsoft Kinect
P. J. Noonan1,2, J. Howard2, T. F. Cootes1, W. A. Hallett2, R. Hinz1
1
University of Manchester, UK; 2Imanova Imaging Centre, UK
M08 Simulation and Modeling of Medical
Imaging Systems
Thursday, Nov. 1 10:30-12:30 Grand Ballroom South AB
Session Chairs: Glenn Wells, University of Ottawa Heart Institute,
Canada
Irène F. Buvat, IMNC CNRS, France
M08-1 (10:30) Hybrid GATE: a GPU/CPU Implementation for Imaging
and Therapy Applications
J. Bert1, H. Perez-Ponce2, S. Jan3, Z. El Bitar4, P. Gueth5, V. Cuplov3, H.
Chekatt4, D. Benoit6, D. Sarrut5, Y. Boursier2, D. Brasse4, I. Buvat6, C.
Morel2, D. Visvikis1
1
LaTIM, France; 2CPPM, France; 3CEA, France; 4Institut Pluridisciplinaire
Hubert Curien, France; 5CREATIS, France; 6IMNC, France
M08-2 (10:45) An Integrated Simulation and Reconstruction
Environment for PET Imaging
P. E. Kinahan1, R. L. Harrison1, B. Elston1, C. Comtat2, C. Tsoumpas3, T. K.
Lewellen1, K. Thielemans4
1
University of Washington, USA; 2CEA, SHFJ, France; 3King’s College London,
UK; 4Algorithms and Software Consulting Ltd, UK
M08-3 (11:00) Subsampled Fisher Information Matrix for Efficient
Estimation of the Uncertainty in Emission Tomography
N. Fuin, S. Pedemonte, S. Arridge, S. Ourselin, B. H. Hutton
M08-4 (11:15) Design Study of a Whole-Body PET Scanner with
Improved Spatial and Timing Resolution
A. Shore, S. Surti, J. S. Karp
M08-5 (11:30) 4D Mathematical Observer Models for the Task-Based
Evaluation of Gated Myocardial Perfusion SPECT Images
T.-S. Lee, E. C. Frey, B. M. W. Tsui
Johns Hopkins University, USA
M08-6 (11:45) Comparison of TOF and Non-TOF Iterative
Reconstruction at Low Statistics
V. Westerwoud, M. Conti, L. Eriksson
Siemens Healthcare, USA
M08-7 (12:00) Enhanced Model of Quantum Efficiency for the Optical
Simulation of Photodetectors
C. Ocsovaine Steinbach, F. Ujhelyi, E. Lorincz
Budapest University of Technology and Economics, Hungary
M08-8 (12:15) Imaging Performance of DOI Measurable PET Systems
for Breast Imaging: Monte Carlo Simulation Studies
J. Wu1, X. Sun2, K. Lou2, Y. Xia1, T. Ma1, Y. Shao2
1
Tsinghua University, China; 2University of Texas MD Anderson Cancer Center,
USA
190 Thursday - MIC Oral Presentations M11 Data Acquisition and Signal Processing
/ Multi-Modality Systems
Session Chairs: Martin S. Judenhofer, University of California, Davis,
USA
William W. Moses, Lawrence Berkeley National
Laboratory, USA
M11-1 (16:30) Self Calibration of Time Walk Error in a Multi-Trigger
PET Detector
C. J. Bircher, Y. Shao, X. Sun, A. Lan
University of Texas MD Anderson Cancer Center, USA
M11-2 (16:45) Matched Filter for Event Identification and Processing
in PET
Y. Valenciaga, D. L. Prout, Z. Gu, R. Taschereau, A. F. Chatziioannou
UCLA, USA
M11-3 (17:00) PET DAQ System for Compressed Sensing Detector
Modules
E. K. Kim, P. D. Olcott, K. J. Hong, C. S. Levin
Stanford University, USA
M11-4 (17:15) Comparison Between DRS4 Chip-Based Boards and a 2
GS/s-ADC for a Flexible PET Electronics
D. A. Stricker-Shaver1, S. Ritt2, B. J. Pichler1
1
University of Tuebingen, Germany; 2Paul Scherrer Institute, Villigen,
Switzerland, Switzerland
M11-5 (17:30) SiPM Based Preclinical PET/MR Insert: Timing and
Gain Calibration, MR Image Quality and First in Vivo Experiments
C. W. Lerche1, J. MacKewn2, B. Weissler1, P. Gebhardt2, T. Solf1, B.
Goldschmidt3, A. Salomon2, P. K. Marsden2, V. Schulz1,3
1
Philips Innovative Technologies, Netherlands; 2Kings College, UK; 3RWTHUniversity Aachen, Germany
M11-6 (17:45) Design Considerations for a Partial-Ring, Multi-Modal
Compatible, Whole-Body TOF PET Scanner: Flexible PET
T. Kobayashi, K. Kitamura, Shimadzu corporation, Japan
M11-7 (18:00) PET Performance Measurements of a Next Generation
Dedicated Small Animal PET/MR Scanner
C.-C. Liu1, M. Hossain1, K. Lankes2, I. Bezrukov1,3, H. F. Wehrl1, A. Kolb1,
M. S. Judenhofer4, B. J. Pichler1
1
Eberhard Karls University of Tuebingen, Germany; 2Bruker Biospin MRI,
Germany; 3Max-Planck-Institute, Germany; 4University of California, USA
M11-8 (18:15) A Generic PET/MRI Respiratory Motion Correction
Approach Using a Generalized Reconstruction by Inversion of Coupled
Systems (GRICS) Approach
H. J. Fayad1, F. Odille2, J. Felblinger2, D. Visvikis1
1
INSERM UMR1101, LaTIM, France; 2INSERM U947, France
M12 Emission Tomography Instrumentation
(PET,SPECT) 2
Thursday, Nov. 1 16:30-18:30 Grand Ballroom South AB
Session Chairs: Christopher J. Thompson, Montreal Neurological
Institute (now retired), Canada
Hao Peng, Medical Physics, McMaster University, Canada
M12-1 (16:30) First Evaluations of the Neighbor Logic of the digital
SiPM tile
D. Schug1,2, P. M. Dueppenbecker2,3, P. Gebhardt2,3, B. Weissler2, B.
Zwaans4, F. Kiessling1, V. Schulz1,2
1
RWTH Aachen University Hospital,, Germany; 2Philips Technologie GmbH
Innovative Technologies, Germany; 3King’s College London, United Kingdom;
4
Philips Digital Photo Counting, Germany
Thursday - MIC Oral Presentations 191
M12-2 (16:45) Performance Evaluation of a Prototype PET Scanner
Using Digital SiPMs
P. Rodrigues1, A. Trindade1, B. Zwaans2, O. Muelhens2, R. Dorscheid2, A.
Thon1, C. Degenhardt2, T. Frach2
1
Philips Research Europe, The Netherlands; 2Philips Digital Photon Counting,
Germany
M12-3 (17:00) Performance of Digital Silicon Photomultiplier for Time
of Flight PET Scanners
R. Marcinkowski, S. Espana, S. Vandenberghe
Ghent University-IBBT-IBiTech, Belgium
M12-4 (17:15) A New Modular and Scalable Detector for a Time-ofFlight PET Scanner
K. C. Burr, H. Du, J. Wang, G.-C. J. Wang, Z. Wang, D. Gagnon
Toshiba Medical Research Institute USA, USA
M12-5 (17:30) Feasibility Study of an Axially Extendable Multiplex
Cylinder PET
E. Yoshida, Y. Hirano, H. Tashima, N. Inadama, F. Nishikido, H.
Murayama, H. Ito, T. Yamaya
National Institute of Radiological Sciences, Japan
M12-6 (17:45) System Design Considerations for Collimation in a Small
Animal PET Scanner
Y. Li, S. Matej, J. S. Karp, S. D. Metzler
M12-7 (18:00) Collimator Optimization in Myocardial Perfusion
SPECT
M. Ghaly, J. M. Links, E. C. Frey
M12-8 (18:15) Development of Intra-Operative PET Probe for MultiModal Endoscope
K. Shimazoe, T. Ilya, H. Takahashi, H. Liao, I. Sakuma
Thursday - RTSD Oral
Presentations
R11 Alternative Semiconductor Materials
Thursday, Nov. 1 Session Chair: 08:30-09:50 Pacific Pier Pacific Ballroom AB
Andrea Zappettini, IMEM-CNR, Italy
R11-1 (08:30, invited) Current State of the Technology and
Characterization of the (Cd,Mn)Te Crystals (for X-ray and Gamma-Ray
Detectors) in the Institute of Physics, Polish Academy of Sciences in
Warsaw
A. Mycielski, D. M. Kochanowska, M. Witkowska-Baran, B. Witkowska,
W. Kaliszek, A. Szadkowski, A. Suchocki, A. Kamińska, P. Nowakowski, A.
Reszka, B. Kowalski, R. Jakieła
Institute of Physics, Polish Academy of Sciences, Poland
R11-2 (08:50) Cadmium Magnesium Telluride (Cd1-xMgxTe) for
Room-Temperature X- and Gamma-Ray Detector Applications
A. Hossain1, V. Yakimovich2, A. E. Bolotnikov1, G. S. Camarda1, Y. Cui1, K.
Kim1, G. Yang1, R. Herpst2, R. B. James1
1
Brookhaven National Laboratory, USA; 2International Crystal Laboratories,
USA
R11-3 (09:05) Spectroscopic Performance of Recent TlBr Detectors
W. Koehler, C. Thrall, Z. He, University of Michigan, USA; H. Kim, L.
Cirignano, K. Shah, Radiation Monitoring Devices, Inc., USA
R11-4 (09:20) Effects of Metal Impurities from Contacts on TlBr
Radiation Detectors
V. Lordi, C. Rocha-Leao
Lawrence Livermore National Lab, USA
R11-5 (09:35) Measurement of Charge Transport Properties of TlBr
Crystals Using a Digital Signal Processing Technique
T. Tada1, K. Hitomi1, T. Onodera2, T. Shoji2, Y. Xu1, S.-Y. Kim1, K. Ishii3
1
Cyclotron and Radioisotope Center, Tohoku University, Japan; 2Department
of Electronics and Intelligent Systems, Tohoku Institute of technology, Japan;
3
Department of Quantum Science and Energy Engineering, Graduate School of
Engineering, Tohoku University, Japan
R12 Alternative Semiconductor Materials &
Neutron Detectors
Douglas S. McGregor, Kansas State University, USA
R12-1 (10:30, invited) Silicon Carbide Detectors for Radiation
Spectroscopy of Plasmas
G. Bertuccio, D. Puglisi, Politecnico di Milano - INFN, Italy; L. Torrisi,
University of Messina, Italy; D. Margarone, Institute of Physics of the ASCR,
Czech Republic
R12-2 (10:50) Crystal Growth of Mercury Brome Iodide (HgBrxI2-X )
Beyond the Phase Transition
A. Gueorguiev, Y. Ogoridnik, A. Churilov, A. Kargar, H. Kim, M.
Squillante, K. Shah
RMD Inc., USA
R12-3 (11:05) Room Temperature X-Ray and Gamma Ray Response of
Graphene Radiation Sensors Configured as Field Effect Transistors on
SiC, CdTe, and AlGaAs/GaAs Substrates
O. Koybasi1, I. Childres2, E. Cazalas3, I. Jovanovic3, Y. Chen2
1
Massachusetts General Hospital / Harvard Medical School, USA; 2Purdue
University, USA; 3Penssylvania State University, USA
192 Thursday - MIC Oral Presentations Thursday - RTSD Oral Presentations 193
R14-2 (17:00) Performance of a CZT Spectroscopic Imager with 3D
R12-4 (11:20) Strategies and Trends from Informatic Materials Selection
of Semiconducting Radiation Detection Materials
K. F. Ferris, Pacific Northwest National Laboratory, USA; D. M. Jones,
Proximate Technologies, LLC., USA
R12-5 (11:35) PbGa2Se4 Semiconductor for Gamma-Ray Detection
A. Kargar, J. Tower, H. Hong, L. Cirignano, H. Kim, K. Shah, RMD Inc.,
USA; P. R. Beck, A. M. Conway, O. B. Drury, L. F. Voss, R. T. Graff, A. J.
Nelson, R. J. Nikolic, S. A. Payne, Lawrence Livermore National Laboratory,
USA; V. Badikov, Mid-IR Ltd., Russia
R12-6 (11:50) Advances on a High Efficiency Self-Powered Solid State
Neutron Detection
R. Dahal, K.-C. Huang, J. Clinton, J.-Q. Lu, Y. Danon, I. Bhat
Rensselaer Polytechnic Institute, USA
R12-7 (12:05) Portable Neutron Energy SPectrometer Utilizing
Microstructured Semiconductor Neutron Detectors
B. W. Cooper, D. S. McGregor, S. L. Bellinger, S. R. Bolding, J. K. Shultis,
Kansas State University, USA; A. Caruso, University of Missouri-Kansas City,
USA; W. H. Miller, Missouri University, USA; T. J. Sobering, Electronics
Design Laboratory, USA
Capabilities
N. Auricchio1, E. Caroli1, C. Budtz-Jorgensen2, S. Del Sordo1, I. Kuvvetli2,
L. Milano3, J. B. Stephen1, G. Benassi4, A. Zappettini4
1
INAF, Italy; 2DTU Space, Denmark; 3University of Ferrara, Italy; 4CNR, Italy
R14-3 (17:15) Performance Analysis of Pixelated CdZnTe Detectors
Using Coincident Interactions in a High-Purity Germanium Detector
Y. A. Boucher, Z. He, University of Michigan, USA
R14-4 (17:30) Study on Event Timing Readout of Pixelated CdZnTe
Detectors
W. R. Kaye, H. Yang, F. Zhang, S. T. Brown, Z. He
R14-5 (17:45) Drift Time Dependent CPG Pulse Height Correction
C. Disch1, A. Fauler1,2, A. Zwerger1,2, M. Dambacher2, M. Fiederle1,2
1
Freiburger Materialforschungszentrum, Germany; 2X-Ray Imaging Europe,
Germany
R14-6 (18:00) Doping of (Cd,Zn)Te During Vapour Growth by MPTVT
M. Bugar, J. T. Mullins, M. Ayoub, I. Radley, Kromek Ltd., U.K.; R. B.
James, Brookhaven National Laboratory, U.S.A.
R13 CdZnTe 3
Thursday, Nov. 1 Session Chair: 14:00-15:40 Pacific Pier Pacific Ballroom
Giuseppe S. Camarda, Brookhaven National Lab, USA
R13-1 (14:00, invited) Growth of Spectrscopy-Grade CdZnTe by the
Vertical Zone Melting Technique
S. Motakef, P. Becla, S. Swider, K. Becla, M. Overholt
CapeSym, Inc., USA
R13-2 (14:20, invited) Optimal Donor Doping of Cd(Zn)Te DetectorGrade Crystals
P. M. Fochuk1, I. Nakonechnyi1, R. Grill2, O. Kopach1, Y. Nykoniuk1, O.
Panchuk1, V. Komar3, A. Rybka4, V. Kutnij4, A. E. Bolotnikov5, R. James5
1
Chernivtsi National University, Ukraine; 2Charles University, Czech Republic;
3
Institute for Single Crystals, Ukraine; 4Kharkiv Institute of Physics and
Technology, Ukraine; 5Brookhaven National Laboratory, USA
R13-3 (14:40) New Studies on Zinc Segregation Phenomena in Vertical
Bridgman Grown CdZnTe Crystals
A. Zappettini1, L. Marchini1, G. Benassi1, N. Zambelli1,2, D. Calestani1
1
IMEM-CNR, Italy; 2University of Parma, Italy
R13-4 (14:55) Performance of High Mobility Detector-Grade CZT
Crystals as Gamma-Ray Detectors
K. C. Mandal, R. M. Krishna, S. K. Chaudhuri, Univ. of South Carolina, USA
R13-5 (15:10) Behaviour of MTPVT Grown CdZnTe Detectors under
High Count Rate X-Ray Irradiation
A. Cherlin, M. Ayoub, J. N. E. McGrath, P. D. Scott, N. R. Laver, I. Radley
Kromek, U.K.
R13-6 (15:25) Complementary Materials Characterisation Techniques
Applied to the Metal-Semiconductor Interface of CdZnTe
S. J. Bell1,2, P. Seller1, M. C. Veale1, M. D. Wilson1, A. Schneider1, P. J.
Sellin2, M. A. Baker2
1
Rutherford Appleton Laboratory, UK; 2University of Surrey, UK
R14 RTSD Award + CZT Detectors
Ralph James, Brookhaven National Laboratory, USA
R14-1 (16:30, invited) The Past and Future of 3-Dimensional Position-
Sensitive CdZnTe Detector Technology
Z. He, The University of Michigan, USA
On behalf of the PRIMA collaboration
194 Thursday - RTSD Oral Presentations Thursday - RTSD Oral Presentations 195
Thursday - MIC Poster
Presentations
M09-12 Metal Artifact Reduction with DCT-Domain Gap-Filling
M09 POSTER: Data Acquisition and Signal
Processing / Image reconstruction methods 1
Thursday, Nov. 1 14:00-16:00 Exhibit Hall North
Session Chairs: Neal Clinthorne, University of Michigan, United States
Ramsey D. Badawi, UC Davis Medical Center, United
States
M09-1 Enhancement of Spatial Resolution in Iterative CT
Reconstruction by Using Sinogram Preprocessing Filters
L. Fu, C. Kerkil, B. De Man
GE Global Research, United States
M09-2 Lung Attenuation Coefficient Estimation Using Maximum
Likelihood Reconstruction of Attenuation and Activity for PET/MR
Attenuation Correction
Y. Berker1,2, A. Salomon2,3, F. Kiessling1, V. Schulz1,2
1
RWTH Aachen University Hospital, Germany; 2Philips Technologie GmbH
Innovative Technologies, Research Laboratories, Germany; 3Kings College
London, United Kingdom
M09-3 Use of Scattered Coincidences for Emission-Based Estimation of
Attenuation Map in PET
Y. Berker1,2, F. Kiessling1, V. Schulz1,2
1
RWTH Aachen University Hospital, Germany; 2Philips Technologie GmbH
Innovative Technologies, Research Laboratories, Germany
M09-4 Fully Four Dimensional Image Reconstruction for a Stationary
Small Animal SPECT System
J. Xu, B. M. Tsui, Johns Hopkins University, USA
M09-5 Higher Order Scattering Estimation for PET
M. Magdics1, L. Szirmay-Kalos1, B. Toth1, T. Bukki2, B. Csebfalvi1
1
Budapest University of Technology and Economics, Hungary; 2Mediso, Hungary
M09-6 CT Reconstruction from Few-Views by Anisotropic Total
Variation Minimization
M. Debatin1, P. Zygmanski2, D. Stsepankou1, J. Hesser1
1
Experimental Radiation Oncology, Germany; 2Dana Farber Cancer Institute,
U.S.A.
M09-7 Improved Statistics Based Positioning Scheme for Continuous
Thick Crystal PET Detectors
W. Yonggang, C. Xinyi, L. Deng
M09-8 Three-Material Decomposition and Tomographic Reconstruction
from Small Number of DXA Projections
A. S. Khaled, T. J. Beck, Johns Hopkins University, USA
M09-9 Fast Dynamic Reconstruction Algorithm with Joint Bilateral
Filtering for Perfusion C-Arm CT
M. T. Manhart1, M. Kowarschik2, A. Fieselmann1,3, Y. Deuerling-Zheng2, J.
Hornegger1,3
1
University of Erlangen-Nuremberg, Germany; 2Siemens AG, Germany;
3
Erlangen Graduate School in Advanced Optical Technologies (SAOT), Germany
M09-10 Ray-by-Ray Noise Weighting in a Filtered Backprojection
Algorithm
G. L. Zeng, University of Utah, USA; A. Zamyatin, Toshiba Medical Research
Institute USA, Inc., USA
M09-11 An Image Reconstruction That Preserves the Regional
Physiological Variation of Radioactivity Concentration
J. Forma, J. Niemi, U. Ruotsalainen
Tampere University of Technology, Finland
196 Thursday - MIC Poster Presentations Method
U. Tuna, U. Ruotsalainen
M09-13 Median Solution and Noise Sorting, a Reconstruction
Algorithm for Emission Tomography with Large Hole Collimator
C. Jeanguillaume1, I. Bouali1, I. Maros2, J. Faurie1
1
Universit d’Angers, France; 2University Pannonia, Hungary
M09-14 Three Dimensional Computerized Tomography Image
Reconstruction: A Unique Concept of Using Light Field Rendering
S. Singh, Corporate Technology, Siemens, India, India
M09-15 Reconstruction of PET Data Acquired with the BrainPET Using
STIR
L. L. Caldeira1,2, C. Weirich3, P. Almeida1, H. Herzog3
1
Instituto de Biofisica e Engenharia Biomedica, Portugal; 2Siemens Healtcare
Portugal, Portugal; 3Institute of Neuroscience and Medicine, Germany
M09-16 Analytic Reconstruction of the Attenuation from 3D Time-ofFlight PET Data
A. Rezaei, J. Nuyts, K.U.Leuven, Belgium; M. Defrise, Vrije Universitiet
Brussel, Belgium
M09-17 GISTA Reconstructs Faster with a Restart Strategy
C. Cloquet1, I. Loris2, C. Verhoeven2, M. Defrise1
1
Vrije Universiteit Brussel, Belgium; 2Universit Libre de Bruxelles, Belgium
M09-18 An Innovative Method for Parallelization of CT Reconstruction
R. Brancaccio1,2, M. Bettuzzi1,2, M. P. Morigi1,2, F. Casali1,2, G. Levi1,2
1
University of Bologna, Italy; 2INFN, Italy
M09-19 Adaptive Triangular Mesh Image Representation for X-Ray
Tomographic Reconstruction
M. A. Quinto1, D. Houzet2, F. Buyens1
1
CEA, France; 2INP-Grenoble, France
M09-20 Evaluation of HYPR De-Noising with MAP Reconstruction in
Small Animal PET Imaging
J.-C. (. Cheng, R. Laforest
Washington University in St. Louis School of Medicine, USA
M09-21 Zipline: a Fast Update Scheme for Reconstruction with
Separable System Models
T. Benson, Georgia Tech Research Institute, United States; L. Fu, B. De Man,
GE Global Research, United States
M09-22 Detector Response Correction for 3D PET Using Bayesian
Modeling of the Location of Interaction
A. Sitek, Brigham and Women’s Hospital and Harvard Medical School, USA;
A. Andreyev, University of British Columbia and Vancouver Coastal Health
Research Institute, Canada
M09-23 Impact of Tracer Distribution, Count Level, Iterations and PostSmoothing on PET Quantification Using a Variously Weighted Least
Squares Algorithm
E. Letourneau1, J. Verhaeghe2, A. J. Reader1
1
Montreal Neurological Institute, Canada; 2Molecular Imaging Center, Belgium
M09-24 An Anatomically Weighted Higher Order Total Variation
Regularization with Bregman Iteration for 3D Emission Tomography
D. Kazantsev1, A. Bousse2, S. Pedemonte1, B. F. Hutton2, S. Ourselin1, S. R.
Arridge1
1
Department of Medical Physics and Bioengineering, UK; 2Institute of Nuclear
Medicine, UK
M09-25 Accelerated Barrier Optimization Compressed Sensing
(ABOCS) Reconstruction: Performance Evaluation for Cone-Beam CT
T. Niu, L. Zhu, Georgia Institute of Technolgy, US
M09-26 Dual-Energy CT Reconstruction Based on Dictionary Learning
and Total Variation Constraint
L. Li, P. Jiao, Z. Chen, L. Zhang
Department of Engineering Physics,Tsinghua University, China
Thursday - MIC Poster Presentations 197
M09-27 A Reweighted Total Variation Minimization Method for Few
View CT Reconstruction in the Instant CT
M. Chang1,2, L. Li1,2, Z. Chen1,2, Y. Xiao1,2, L. Zhang1,2, G. Wang3
1
Tsinghua University, China; 2Ministry of Education, China; 3Virginia Tech
University, USA
M09-28 Motion Registration and Correction Based Iterative
Reconstruction Method for Instant CT
M. Chang1,2, L. Li1,2, Z. Chen1,2, Y. Xiao1,2, L. Zhang1,2, G. Wang3
1
Tsinghua University, China; 2Ministry of Education, China; 3Virginia Tech,
USA
M09-29 Deconvolution for Limited-View Streak Artifacts Removal:
Improvements over an Existing Approach
C. Mory1,2, V. Auvray2, B. Zhang2, M. Grass3, D. Schaefer3, F. Peyrin1, S.
Rit1, P. Douek4, L. Boussel4
1
Universite de Lyon, CREATIS ; CNRS UMR5220 ; Inserm U1044 ; INSALyon ; Universite Lyon 1, France; 2Philips Research Medisys, France; 3Philips
Research, Germany; 4Universite de Lyon, CREATIS ; CNRS UMR5220 ; Inserm
U1044 ; INSA-Lyon ; Universite Lyon 1 ; Hospices Civils de Lyon, France
M09-30 Rebinning of Conical Projection Data in Compton Imaging
M. N. Lee, S.-J. Lee, Paichai University, S. Korea
M09-31 GPU-Accelerated Exact Strip Integrals for 2-D Iterative
Reconstruction in Emission Tomography
V.-G. Nguyen, S.-J. Lee, Paichai University, S. Korea
M09-32 A First-Order Primal-Dual Reconstruction Algorithm for FewView SPECT
P. A. Wolf1, J. H. Jorgensen2, T. G. Schmidt1, E. Y. Sidky3
1
Marquette University, United States; 2Technical University of Denmark,
Denmark; 3University of Chicago, United States
M09-33 Evaluation of Reconstructed Images on the Micro-CT System
Using Total Variation Minimization
D.-H. Kim, H.-J. Kim, C.-L. Lee, P.-H. Jeon, S.-J. Park, Y.-S. Kim
Yonsei University, Republic of Korea
M09-34 A Web-Based Resource for Lesion Detection Assessment: the
Utah PET Lesion Detection Database
M. B. Oktay, D. J. Kadrmas, University of Utah, USA
M09-35 Multi-Segments Limited-Angle Image Reconstruction via
BM3D Filter
X. Li1,2, Z. Chen1,2, Y. Xing1,2
1
Department of Engineering Physics, Tsinghua University, China; 2Key
Laboratory of Particle & Radiation Imaging (Tsinghua University), Ministry of
Education, China
M09-36 Using a Flexible Detector Response Design for System Matrix
Computation in Small Animal SPECT
Z. El Bitar1,2, R. Boutchko2, N. T. Vandehey2, R. H. Huesman2, G. T.
Gullberg2
1
Institut Pluridisciplinaire Hubert Curien, France; 2Lawrence Berkeley National
Laboratory, USA
M09-37 Running Prior for Patient Motion Correction in Low-Dose
3D+Time Interventional Flat Detector CT
B. Flach1, J. Kuntz2, M. Brehm1, S. Bartling2,3, M. Kachelrieß1,2
1
University of Erlangen-Nürnberg, Germany; 2German Cancer Research Center,
Germany; 3University Medical Center Mannheim, Germany
M09-38 A Tempo-Angular Subset Selection in TOF-PET Image
Reconstruction Using OSEM
C.-Y. Lin1, P.-C. Huang1, M.-C. Lin2, C.-H. Hsu1
1
National Tsing Hua University, Taiwan; 2National Health Research Institutes,
Taiwan
M09-39 3D PET Image Reconstruction Using Statistical Shape Prior
and Level Set Method
J. Cheng-Liao, J. Qi
University of California, Davis, United States
198 Thursday - MIC Poster Presentations M09-40 List-mode TOF PET reconstruciton by estimating event
coordinates
C.-M. Kao, H. Kim, The University of Chicago, USA
M09-41 Tensor-Based Low Rank Multi-Energy CT Reconstruction from
Few-View Projection Data
D. Jiang, L. Li, Z. Chen, Department of Engineering Physics,Tsinghua
University, China; G. Wang, VT-WFU School of Biomedical Engineering and
Sciences, USA; H. Gao, Department of Mathematics, University of California,
USA
M09-42 Multi-Energy CT Reconstruction Based on Low Rank and
Sparsity with the Split-Bregman Method (MLRSS)
J. Chu, L. Li, Z. Chen, Department of Engineering Physics,Tsinghua
University, China; G. Wang, VT-WFU School of Biomedical Engineering and
Sciences, USA; H. Gao, Department of Mathematics, University of California,
USA
M09-43 Efficient 2D Filtering for Cone-Beam VOI Reconstruction
Y. Xia1, A. Maier2, F. Dennerlein2, H. G. Hofmann1, J. Hornegger1
1
Friedrich-Alexander-University Erlangen-Nuremberg, Germany; 2Siemens AG,
Germany
M09-44 Dose Limitations for the Estimation of Functional Cardiac
Parameters in Rodents
S. Sawall, M. Knaup, A. Hess, Friedrich-Alexander-University (FAU)
Erlangen-Nürnberg, Germany; M. Kachelrieß, German Cancer Research Center
(DKFZ), Germany
M09-45 Full 3D PET Reconstruction for COMPET
D. Volgyes, E. Bolle, K.-E. Hines, M. Rissi
University of Oslo, Norway
M09-46 Implementation and Analysis of List-Mode Based Algorithms
Using Tubes of Responses
L. Moliner1, C. Correcher2, A. J. Gonzalez1, P. Conde1, L. Hernandez1,
A. Orero1, M. J. Rodriguez1, F. Sanchez1, A. Soriano1, L. F. Vidal1, J. M.
Benlloch1
1
I3M, Institute of Instrumentation for Molecular Imaging, Spain; 2Oncovision,
Spain
M09-47 Cardiac Perfusion Imaging of Small Rodents Using Cone-Beam
Micro-CT
S. Sawall1, J. Kuntz2, M. Socher2, S. Bartling2, M. Knaup1, M. Kachelrieß2
1
Friedrich-Alexander-University (FAU) Erlangen-Nürnberg, Germany; 2German
Cancer Research Center (DKFZ), Germany
M09-48 Time-Activity Curve Based Sinogram Decomposition for Streak
Artifacts Reduction in Dynamic PET Reconstruction
X. Cheng1, J. Liu2, J. Vogel1, Z. Liu1, N. Navab1, S. I. Ziegler1, K. Shi1
1
Technical University Munich, Germany; 2Siemens Corporate Research (SCR),
U.S.
M09-49 Performance Evaluation of CPU-GPU Dual Using for PixelDriven-Method Reconstruction
G. Y. Kim, S. M. Kim, J. S. Lee
Seoul National University College of Medicine, Rep. of Korea
M09-50 A Novel Partial Volume Effects Correction Technique
Integrating Deconvolution Associated with Denoising Within the PET
Image Reconstruction Process
T. Merlin1, A. Le Pogam2, P. Fernandez1, D. Visvikis2, F. Lamare1
1
Hopital de Bordeaux, France; 2Universite de Bretagne Occidentale, France
M09-51 Reconstruction of Dose Distribution in in-Beam PET for
Carbon Therapy
K. Kim, J. Bae, S. Bae, K. Lee, Korea University, South Korea; Y. Chung,
Yonsei University, South Korea; J. Joung, Nucare Medical Systems, South Korea
M09-52 Bunched Sparse-View CT Using a Moving Multi-Slit Collimator
M. Park, T. Lee, S. Cho
Korea Advanced Istitute of Science and Technology, Korea
M09-53 Integration of Advanced 3D SPECT Reconstruction into the
STIR Framework
B. Marti Fuster1,2, C. Falcon2,3, C. Tsoumpas4, L. Livieratos4, P. Aguiar5, A.
Cot1,2, D. Ros1,2, K. Thielemans4,6
1
University of Barcelona, SPAIN; 2Biomedical Research Networking center
in Bioengineering, Biomaterials and Nanomedicine (CIBER-BBN), SPAIN;
3
August Pi i Sunyer Biomedical Research Institute (IDIBAPS), SPAIN; 4King’s
College London, UK; 5IDIS Research Institute, SPAIN; 6Algorithms & Software
Consulting, UK
M09-54 On Lesion Detectability by Means of 300ps-FWHM TOF
Whole-Body RPC-PET: an Experiment-Based Simulation Study
P. Martins1,2, M. Couceiro1,3, N. C. Ferreira4,5, R. Ferreira Marques1,2, P.
Fonte1,3, L. Mendes4, P. Crespo1
1
Portugal; 2University of Coimbra, Portugal; 3ISEC - Instituto Superior de
Engenharia de Coimbra, Portugal; 4IBILI - Institute of Biomedical Research in
Light and Image, Portugal; 5ICNAS - Instituto de Ciências Nucleares Aplicadas
à Saúde, Portugal
M09-55 Uniform Resolution List Mode Reconstruction for the HRRT
Y. Jian, R. Carson, Yale University, USA
M09-56 Effects of Discrete Versus Continuous Prior Image in SparseView CT
S. Abbas, S. Cho, KAIST, South Korea
M09-57 Multiplicative Iterative Algorithms for Transmission Image
Reconstruction with Polychromatic Sources
L. M. Popescu, Food and Drug Administration, USA
M09-58 Distributed-Shared Memory Computed Tomography
F. de la Fuente, F. Torres, F. R. Rannou
University of Santiago of Chile, Chile
M09-59 A Comparison Study of Low-Dose CT Image Reconstruction
Strategies by Adapted Weighted Total Variation Regularization
Y. Liu1, J. Ma2, H. Zhang1, J. Wang3, Z. Liang1
1
Stony Brook University, USA; 2Southern Medical University, China; 3The
University of Texas Southwestern Medical Center at Dallas, USA
M09-60 FPGA-Based Time-to-Digital Converter for Time-of-Flight PET
detector
K. J. Hong, E. Kim, J. Y. Yeom, C. S. Levin, Stanford University, USA
M09-61 A Silicon Photomultiplier Signal Readout Using Transmissionline and Waveform Sampling for Positron Emission Tomography
H. Kim1, C.-T. Chen1, H. Frisch2, A. Ronzhin3, E. Ramberg3, S. Los3, P.
Murat3, S. Majewski4, C.-M. Kao1
1
University of Chicago, U.S; 2Enrico Fermi Institude, U.S; 3Fermi National
Accelerator Laboratory, U.S; 4West Virginia University, U.S
M09-62 A Study on the Optimal Sampling Speed of DRS4-based
Waveform Digitizer for Time-of-flight Positron Emission Tomography
Application
H. Kim1, C.-T. Chen1, W. W. Moses2, W.-S. Choong2, H. Frisch3, C.-M.
Kao1
1
University of Chicago, U.S; 2Lawrence Berkeley National Laboratory, U.S;
3
Enrico Fermi Institute, U.S
M09-63 Improved Compressed Sensing Multiplexing PET Readout
G. Chinn1,2, P. D. Olcott1,2, C. S. Levin1,2
1
Stanford School of Medicine, USA; 2MIPS, USA
M09-64 PET Data Acquisition (DAQ) System Having Scalability for the
Number of Detectors
M. Nakazawa, J. Ohi, T. Furumiya, T. Tsuda, M. Furuta, M. Sato, K.
Kitamura
Technology Research Laboratory, Shimadzu Corporation, Kyoto, Japan, Japan
M09-65 FPGA-Based Singles and Coincidence Processing Pipeline for
Integrated Digital PET/MR Detectors
P. Gebhardt1,2, B. Weissler3,2, M. Zinke3, F. Kiessling2, V. Schulz3,2
1
Kings’ College London, United Kingdom; 2RWTH Aachen University, Germany;
3
Philips Technologie GmbH Innovative Technologies, Germany
200 Thursday - MIC Poster Presentations M09-66 Signal Seperation in Magnetic Particle Imaging
M. Graeser, T. Knopp, M. Grttner, T. F. Sattel, T. M. Buzug
University of Luebeck, Germany
M09-67 Level-Crossing ADC Readout Architecture for Positron
Emission Tomography
F. W. Y. Lau, H. H. Choi, M. A. Horowitz, C. S. Levin
M09-68 Reconstruction of Gated Dynamic Cardiac SPECT Data Using
Spatiotemporal Basis Functions
G. T. Gullberg1,2, F. Alhassen2, U. Shrestha2, E. H. Botvinick2, Y. Seo2
1
Lawrence Berkeley National Laboratory, USA; 2University of California San
Francisco, USA
M09-69 A Mathematical Formulation of the Single-Pinhole Transform
and Optimal Sampling Lattices
A. Ihsani, T. H. Farncombe, McMaster University, Canada
M09-70 Spectra Analysis Automation for Hemochromatosis Using
Neutron-Stimulated Emission Data
Q. Magana, Spectralysis LLC, United States; A. Kapadia, G. Agasthya, Duke
University Medical Center, United States
M09-71 Efficient Optimization Based on Local Shift-Invariance for
Adaptive SPECT Systems
L. R. V. Pato, S. Vandenberghe, R. Van Holen
M09-72 Filtered Sampling for PET
M. Magdics, L. Szirmay-Kalos, B. Toth, T. Umenhoffer
M09-73 Towards Software-Based Real-Time Singles and Coincidences
Processing of Detector Raw Data from a Digital PET System
B. Goldschmidt1,2, C. W. Lerche2, T. Solf2, A. Salomon3, F. Kiessling1, V.
Schulz1,2
1
RWTH Aachen University, Germany; 2Philips Research Europe, Germany;
3
Kings College London, U.K.
M09-74 Position Dependent Attenuation Artifacts with a Multi-Pinhole
Dedicated Cardiac Camera
R. G. Wells, University of Ottawa Heart Institute, Canada
M09-75 Evaluation of Two PET Motion Correction Techniques for
Simultaneous Real-Time PET-MR Acquisitions Using an MR-Derived
Motion Model
C. Tsoumpas, S. Agarwal, P. K. Marsden, A. P. King
King’s College London, United Kingdom
M09-76 One-Pair Measurement System for Efficient Imaging
Performance Evaluation of Prototype DOI-PET Detectors
H. Tashima, E. Yoshida, Y. Hirano, F. Nishikido, N. Inadama, H.
Murayama, H. Ito, T. Yamaya
National Institute of Radiological Siences, Japan
M09-77 A Real Time Motion Correction Technique for a Small-Field
Gamma-Camera System
M. Zioga1, M. Mikeli1, A.-N. Rapsomanikis1, E. Stiliaris1,2
1
Systems & Applications, Greece
M09-78 A Fast Tracker Data Acquisition System for pCT
R. P. Johnson, J. DeWitt, D. Steinberg, S. Macafee
Univeristy of California, Santa Cruz, USA
M09-79 A Novel Capacitive Charge-Division Readout for PositionSensitive Solid-State Photomultiplier Array
J. Du1, J. Schmall1, Y. Yang1, K. Di1, P. Dokhale2, K. Shah2, S. R. Cherry1
1
University of CaliforniaDavis, USA; 2Radiation Monitoring Devices Inc., USA
M09-80 An Adaptive Method for Triggering, Event Validation and Pulse
Pile-up Recovery in PET
Z. Gu, D. L. Prout, A. F. Chatziioannou, UCLA, United States
M09-81 A Digital Pulse Library for the Optimization of Signal
Processing in PET
Z. Gu, D. L. Prout, Y. Valenciaga, A. F. Chatziioannou, UCLA, United States
M09-82 Efficient Estimation of Cardiac Time-Activity Curves (TAC)
from a Two-Camera SPECT System Using Compressed Sensing with
Projective Subspace Denoising
D. Lamba1, M. Ghaly1,2, P. Greene1, J. Hossain2, E. C. Frey2
1
Johns Hopkins University, USA; 2Johns Hopkins School of Medicine, USA
M09-83 Design and Implementation of Scalable DAQ Software for a
High-Resolution PET Camera
U. Yoruk, A. Vandenbroucke, P. D. Reynolds, C. S. Levin
M09-84 A Coincidence Detection Unit Using Shift Register for PET
S. Kim1, Y. Choi1, J. H. Jung1, Y. Huh1,2, J. Jung1, K. B. Kim1
1
Sogang University, Korea; 2SungkyunKwan University, Korea
M09-85 A Low-Utilization FPGA-Based in-Line 250Million Events per
Second Event-Pairing Processing Module for Use in Time-of-Flight PET
Applications
G. J. Mann, O. Ivanov, W. Wang, D. Gagnon
Toshiba Medical Research Institute, USA
M09-86 Comparison of Stress-First and Rest-First Techniques for
Single-Scan Cardiac PET
D. J. Kadrmas, University of Utah, USA; A. Sitek, Brigham & Women’s
Hospital, USA
M10 POSTER: Simulation and Modeling of
Medical Imaging Systems / Multi-Modality
Systems
Thursday, Nov. 1 14:00-16:00 Exhibit Hall North
Session Chairs: Sara St. James, Brigham and Women’s Hospital, USA
Stephen J. Glick, Univ. of Massachusetts Medical School,
USA
M10-1 Initial Validation of a Complete GATE Model of the Siemens
Inveon Trimodal Imaging System
S. Lee1, J. Gregor1, D. R. Osborne1,2
1
University of Tennessee, USA; 2Siemens Medical Solutions, USA
M10-2 Initial Assessment of the Monte-Carlo Simulation of SPECT
Recording with the New Region-Centric CZT DSPECT Camera
L. Imbert1,2,3,4, P.-Y. Marie3,4, E. Galbrun1, S. Poussier3, D. Wolf1, G.
Karcher3,4, A. Noel3,4
1
CRAN-CNRS UMR 7039, France; 2Centre Alexis Vautrin, France; 3Centre
Hospitalier Universitaire Nancy, France; 4GIE NancycloTEP, France
M10-3 Validation of a Simulation Toolbox for Optimization of TOF
High-Resolution PET Detector Modules
S. Cooke1, J. Griesmer1, T. Laurence1, P. Rodrigues2, T. Solf3, A. Trindade2, S.
Wang1, H. Wieczorek2
1
Philips Healthcare, U.S.A.; 2Philips Research Europe, The Netherlands; 3Philips
Technologie GmbH, Germany
M10-4 Validation of GATE Monte Carlo Simulations of the Philips
Gemini TF and TruFlight Select PET/CT Scanners Based on NEMA
NU2 Standards
J. Griesmer1, T. Laurence1, M. A. Miller1, M. Narayanan1, A. E. Perkins1, P.
Rodrigues2, L. Shao1, T. Solf3, A. Trindade1, C.-H. Tung1, H. Wieczorek2, B.
Zhang1
1
Philips Healthcare, U.S.A; 2Philips Research Europe, The Netherlands; 3Philips
Technologie GmbH, Germany
M10-5 New Functionalities of SINDBAD Simulation Software for
Spectral X-Ray Imaging Using Energy Resolving Detectors
V. Rebuffel, J. Tabary, P. Hugonnard, E. Popa, A. Brambilla, L. Verger
CEA-Leti, MINATEC Campus, France
M10-6 Enhanced Model of Quantum Efficiency for the Optical
Simulation of Photodetectors
C. Ocsovaine Steinbach, F. Ujhelyi, E. Lorincz
202 Thursday - MIC Poster Presentations M10-7 Study of Imaging 142Pr Microspheres Using the Gamma
Emission Spectrum in a Clinical Setting
C. D. Pelletier, J. W. Jung
East Carolina University, United States
M10-8 Obtaining Patient-Specific Dose Estimates in Nuclear Medicine
Studies
S. M. McNeil1, T. H. Farncombe1,2
1
McMaster University, Canada; 2Hamilton Health Sciences, Canada
M10-9 Monte Carlo Nuclear Models Evaluation and Improvements
for Real-Time Prompt Gamma-Ray Monitoring in Proton and Carbon
Therapy
G. Dedes1,2, D. Dauvergne1, M. De Rydt1,3, N. Freud2, J. Krimmer1, J. M.
Letang2, M. Pinto1, C. Ray1, E. Testa1
1
IPNL, Universite de Lyon, F-69003 Lyon, France; Universite Lyon 1 and
CNRS/IN2P3, UMR 5822 F-69622 Villeurbanne, France, France; 2CREATIS,
Universite de Lyon, F-69622 Lyon, France; Universite Lyon 1 and CNRS UMR
5220; INSERM U1044; INSA-Lyon; Centre Leon Berard, France, France;
3
Instituut voor Kern- en Stralingsfysica, K.U.Leuven, Celestijnenlaan 200D,
B-3001 Leuven, Belgium
M10-10 Enhancing the Efficiency of a Field Free Line Scanning Device
for Magnetic Particle Imaging
M. Erbe, T. F. Sattel, T. Knopp, T. M. Buzug
Institute of Medical Engineering, University of Lübeck, Germany
M10-11 Simulation of the Effects of Multiplexing in Multi-Pinhole
SPECT Using Stacked Si-HPGe Detectors
L. C. Johnson, S. Shokouhi, T. E. Peterson
Vanderbilt University, USA
M10-12 X-Ray Imaging Using Photon-Counting Pixel Detectors:
Fundamental Spatial Resolution Due to X-Ray Interaction
J. C. Han1, H. K. Kim1, H. Youn1, J. P. Marchal2, S. Yun1,3, J. Tanguay3, I. A.
Cunningham3
1
M10-13 Fundamental Limitations in Energy-Absorption Response
Functions of X-Ray Photon-Counting Pixel Detectors
H. Youn1, J. P. Marchal2, H. K. Kim1, S. Yun1,3, J. Tanguay3, I. A.
Cunningham3
1
M10-14 FDG and PIB Biomarker PET Analysis for the Alzheimer’s
Disease Detection Using Association Rules
R. M. Chaves Rodriguez, J. Ramirez Perez De Inestrosa, J. M. Gorriz Saez, I.
Alvarez Illan, D. Salas Gonzalez
University of Granada, Spain
M10-15 Analytic Radial and Tangential Resolution Formulas: Applicable
to the Whole FOV for Cylindrical DOI-PET
Y. Xia, T. Ma, J. Wu, S. Wang, Y. Liu, Y. Jin
M10-16 Design and Fabrication of Endoscope-Type Compton Camera
and Its Real Time Imaging System
Y. Nakamura, K. Shimazoe, H. Takahashi
M10-17 Development of an in-Situ Radiotracer Concentration
Measurement System Using Compact Pixilated LuAG-APD Gamma-Ray
Detector Module
A. H. Malik, K. Shimazoe, H. Takahashi
School of Engineering, The University of Tokyo, Japan
M10-18 Optical Simulation of a 9×9 LYSO Block Detector with PQS
Technology Using GATE
P. Fan1,2, J. Chen3, Q. Wei1,2, T. Xu1,2, Y. Xia1,2, S. Wang1,2, Y. Liu1,2
1
Tsinghua University, China; 2Ministry of Education, China; 3National Institute
of Metrology, China
M10-19 Stationary SPECT with Multi-Layer Multiple-Pinhole-Arrays
W. Ren1, I. Valastyán1,2, M. Colarieti Tosti1
1
School of Technology and Health, Royal Institute of Technology, Sweden;
2
M10-20 Modular miniPET: a Comparison between 10 and 12 Detector
Modules
A. Turco1, I. Valastyán1,2, M. Colarieti Tosti1
1
School of Technology and Health, Royal Institute of Technology, Sweden;
2
M10-21 Simulation Study of Real-Time Tumor Tracking by OpenPET
Using the 4D XCAT Phantom with a Realistic 18F-FDG Distribution
H. Tashima1, E. Yoshida1, T. Shinaji2, Y. Hirano1, S. Kinouchi2, F.
Nishikido1, M. Suga2, H. Haneishi2, H. Ito1, T. Yamaya1
1
National Institute of Radiological Siences, Japan; 2Chiba University, Japan
M10-22 Modeling of 3D Gamma Interaction Position in a Monolithic
Scintillator Block with a Row-Colunm Summing Readout
D. A. B. Bonifacio1,2, M. Moralles3
1
Institute of Radioprotection and Dosimetry (IRD/CNEN), Brazil; 2Institute of
Physics (IF-USP), Brazil; 3Nuclear And Energy Research Institute, Brazil
M10-23 Optical Imaging Simulation Using GATE
V. Cuplov, Commissariat a l’Energie Atomique, France
On behalf of the OpenGATE collaboration
M10-24 Analytic Response Functions in Compound Semiconductor
Detectors
S. Yun1,2, H. K. Kim1, H. Youn1, J. Tanguay2, I. A. Cunningham2
1
Pusan National University, South Korea; 2Robarts Research Institute, Canada
M10-25 Attenuation-Based Dynamic CT Beam-Shaping Filtration in
Dependence of Fan and Projection Angle: Evaluation of a New Method
for Radiation Exposure Reduction by Monte-Carlo Simulation of Spatial
Dose Distribution
W. Stiller, S. Veloza, H.-U. Kauczor
University Hospital Heidelberg, Germany
M10-26 Accurate Analytical Modeling and Implementation of Detector
Response for Fully 3D Simulation and Reconstruction of an MRI
Compatible PET Insert with a Dual-Layer Offset Crystal Design
X. Zhang1, V. Sossi2, G. Stortz2, C. J. Thompson3, F. Rtiere4, P. Kozlowski2,
A. L. Goertzen1
1
University of Manitoba, Canada; 2University of British Columbia, Canada;
3
Montreal Neurological Institute, Canada; 4TRIUMF, Canada
M10-27 PS Detector Based on the Scintillation Crystal with High
Internal Light Scattering for the Small FOV Gamma Camera
V. Y. Pedash
Institute for scintillation materials NAS of Ukraine, Ukraine
M10-28 A Dynamic Phantom to Assess the Effect of Motion in Cardiac
PET Studies
L. Presotto1,2, V. Bettinardi2,3, P. Petta3, M. C. Gilardi3,4,1
1
University of Milano Bicocca, Italy; 2San Raffaele Scientific Institute, Italy;
3
CNR, Italy; 4Tecnomed Foundation, Italy
M10-29 A Method for Measuring Time-of-Flight Resolution of Positron
Emission Tomography Scanner
X. Niu, H. Ye, D. Gagnon, W. Wang
Toshiba Medical Research Institute USA, Inc., USA
M10-30 Development of a Collimator Representation in the TITAN
Transport Code for SPECT Simulation
K. K. Royston, A. Haghighat, Virginia Tech, USA
M10-31 Variation of PET Scatter Distribution with Measured Depth-ofInteraction
R. L. Harrison, W. C. J. Hunter, L. R. MacDonald, T. K. Lewellen
M10-32 Scatter Fraction, Count Rates, and Noise Equivalent Count
Rate of an RPC-PET TOF System: Simulation Study Following the
NEMA NU2 2001 Standards
M. Couceiro1,2, P. Crespo1, R. F. Marques1,3, P. Fonte1,2
204 Thursday - MIC Poster Presentations LIP - Laboratório de Instrumentação e Física Experimental de Partículas,
Portugal; 2ISEC - Instituto Superior de Engenharia de Coimbra, Portugal;
3
FCTUC - Faculdade de Ciências e Tecnologia, Universidade de Coimbra,
Portugal
M10-33 Digitization and Visibility Issues in Flat Detector CT: A
Simulation Study
M. Knaup, L. Ritschl, University of Erlangen-Nuremberg, Germany; M.
Kachelriess, German Cancer Research Center (DKFZ), Germany
M10-34 Simulation with GATE of Liquid Xenon Time Projection
Chamber and a Proposed Cylindrical 3γ Camera
A. F. Mohamad Hadi, J.-P. Cussonneau, D. Thers, W.-T. Chen, J. Donnard,
S. Duval, T. Oger, E. Morteau, O. Lemaire, L. L. Scotto, H. Delagrange
SUBATECH, France
M10-35 Image Resolution Effects in Maximum-Likelihood TOF PET
Reconstruction: Study of Reconstruction and Object Influences
M. Ispiryan, S. Matej, University of Pennsylvania, USA
M10-36 Optimization and Evaluation of Compensation Methods and
Reconstruction Parameters for Tc-99m MIBI Parathyroid SPECT
T. Ekjeen1,2, C. Tocharoenchai1, P. Pusuwan3, G. S. K. Fung2, M. Ghaly2, Y.
Du2, E. C. Frey2
1
Mahidol University, Thailand; 2Johns Hopkins University, USA; 3Siriraj
Hospital, Thailand
M10-37 Analysis of the Imaging Performance of a Small Animal PET
Scanner at Low Contrast
I. Lajtos1, S. A. Kis1, M. Emri1, G. Opposits1, F. Nagy2, N. Potari1, L.
Balkay1
1
University of Debrecen, Institute of Nuclear Medicine, Hungary; 2Institute of
Nuclear Research of the Hungarian Academy of Sciences, Hungary
M10-38 Simulation Studies with SiPM Arrays and LYSO Crystal Matrix
Analyzing a New Readout Scheme
A. K. Krizsan1, S. A. Kis1, J. Gal2, G. Hegyesi2, L. Balkay1
1
Institute of Nuclear Medicine, University of Debrecen, Hungary; 2ATOMKI,
Hungary
M10-39 Validation of SimSET Monte Carlo Simulations of the Siemens
Biograph mCT PET Scanner
J. K. Poon1, M. Dalhbom2, J. Qi1, S. R. Cherry1, R. D. Badawi1
1
University of California, Davis, USA; 2University of California, Los Angeles,
USA
M10-40 Optimization of Energy Window and Multiple Event
Acceptance Policy for PETbox4 a High Sensitivity Preclinical Imaging
Tomograph
Z. Gu1, Q. Bao1, R. Taschereau1,2, H. Wang1, N. Vu2, A. F. Chatziioannou1,2
1
UCLA, United States; 2Sofie Biosciences Inc., United States
M10-41 Validation of Compound Poisson Noise Model for Computed
Tomography with Energy-Integrating Detector
A. A. Zamyatin, Y. Fan, K. Schultz, Toshiba Medical Research Institute USA,
USA; S. Nakanishi, Toshiba Medical Systems Corporation, Japan
M10-42 Estimation of NEC, Scatter Fraction, and Sensitivity of a
New MR Compatible Small Animal PET Insert Based on Monte-Carlo
Simulation
G. Stortz1, A. L. Goertzen2, F. Retiere3, X. Zhang2, M. Walker1, P.
Kozlowski1, C. J. Thompson4, V. Sossi1
1
University of British Columbia, Canada; 2University of Manitoba, Canada;
3
TRIUMF, Canada; 4Montreal Neurological Institute, Canada
M10-43 Feasibility Study of a Cost-Effective PET Insert for
Simultaneous PET/MRI Imaging for Breast Cancer
Y. Liang, H. Peng, McMaster University, Canada
M10-44 Signal Characteristics Study of Continuous-Scintillator CCDBased Single Photon Counting (SPC) Detector
Q. Wei1, A. Jain2, C. Ionita2, X. Deng2, T. Dai1, T. Ma1, Y. Liu1, D. R.
Bednarek2, S. Rudin2, R. Yao2
1
Tsinghua University, China; 2State University of New York at Buffalo, USA
1
M10-45 A Fast Monte Carlo-Based Forward Projector with Complete
Physics Modeling of Y-90 Bremsstrahlung
S. C. Moore1,2, M.-A. Park1,2, M. Cervo1, S. P. Mueller3
1
Brigham & Women’s Hospital, USA; 2Harvard Medical School, USA;
3
Universitaetsklinikum Essen, Germany
M10-46 Optimal Experimentation for Nuclear Medicine Imaging
System Design
D. Talat1, S. Balta Beylergil2, A. Guvenis1
1
Bogazici University, Turkey; 2Technische Universitaet Berlin, Germany
M10-47 Polyenergetic CT Sinogram Generator
C. Thibaudeau, J.-F. Pratte, R. Fontaine, R. Lecomte
M10-48 Optimization of Imaging Protocol for 18F-Flurpiridaz PET
Imaging Using the Dynamic 4D XCAT Phantom and Monte Carlo
Simulations
K. Wiyaporn1,2, C. Tocharoenchai1, P. Pusuwan3, G. S. K. Fung2, T. Feng2,
M. J. Park2, T. Higuchi4, B. M. W. Tsui2
1
Mahidol University, Thailand; 2Johns Hopkins University, US; 3Siriraj
Hospital, Thailand; 4University Hospital Wrzburg, Germany
M10-49 Optimization of Detector Surface for Multi-Pinhole Cardiac
SPECT: a NCAT Study
S. Agarwal, J. Dey
University of Massachusetts Medical School, USA
M10-50 Simulations Investigating the Impact of Depth-of-Interaction in
Nuclear Breast Imaging with a Dedicated Germanium Gamma Camera
D. L. Campbell, T. E. Peterson, Vanderbilt University, USA
M10-51 Validation of PET-SORTEO Monte Carlo Simulations for the
Geometry of the Inveon PET Preclinical Scanner
F. Boisson1, W. Lehnert2, D. Zahra1, M.-C. Gregoire1, A. Reilhac1
1
LifeSciences, Australia; 2University of Sydney, Australia
M10-52 FastMIST: a Fast Molecular Imaging SimulaTor
W. J. Ryder, G. I. Angelis, R. Bashar, R. Fulton, S. Meikle
University of Sydney, Australia
M10-53 Misaligned Gantry Analysis in Cone-Beam Computed
Tomography System
C. Seo, B. K. Cha, R. K. Kim, D. Huh, T.-B. Lee, K. Yang, S. Jeon, Y.
Huh, Korea Electrotechnology Research Institute, South Korea; K. Lee, Korea
University, South Korea
M10-54 Hybrid segmentation-atlas method for PET-MRI attenuation
correction
A. Tanigawa1, T. Yamaya2, H. Kawaguchi2, Y. Hirano2, T. Shiraishi2, K.
Tanimoto2, E. Yoshida2, T. Obata2, M. Suga1
1
Chiba University, Japan; 2National Institute of Radiological Sciences, Japan
M10-55 Design of a Compact Ultra High Resolution Small Animal
SPECT-CT Based on a CdTe Detector
H. J. Ryu, Y. J. Lee, Y. N. Choi, H. M. Cho, S. W. Lee, H. J. Kim
Yonsei University, South Korea
M10-56 Bundle Adjustment for Marker-Based Rigid MR-X-Ray
Registration
P. Fischer1, T. Pohl2, A. Brost1, J. Hornegger1
1
Germany
M10-57 Evaluation of the Effect of Magnetic Field on the PET Spatial
Resolution and Contrast Recovery Using Clinical PET Scanners and
EGS Simulations
J.-C. (. Cheng, R. Laforest
Washington University in St. Louis School of Medicine, USA
M10-58 Development of a Small Animal SPECT and CT Dual Function
Imager with a Micro-Columnar CsI(Tl) and CCD Based Detector
X. Deng1, T. Dai2, C. N. Ionita1, A. Jain1, A. Panse1, D. R. Bednarek1, S.
Rudin1, R. Yao1
1
State University of New York at Buffalo, United States; 2Tsinghua University,
China
206 Thursday - MIC Poster Presentations M10-59 Investigation of Photon Cross-Talk in Simultaneous SPECT-CT
Imaging
S. Chen, H. Liu, T. Ma, S. Wang, Y. Liu
M10-60 TOPEM: a PET TOF Endorectal Probe, Compatible with MRI
for Diagnosis and Follow up of Prostate Cancer
F. Garibaldi1, L. Cosentino2, S. Colilli1, F. Cusanno3, R. De Leo4, P.
Finocchiaro2, M. Foresta4, F. Giuliani1, F. Loddo4, M. Lucentini1, F. Meddi3,
E. Monno5, A. Pappalardo2, R. Perrino6, F. Santavenere1, C. Tamma4, A.
Ranieri4
1
INFN Roma1 and gruppo collegato ISS, Italy; 2INFN LNS, Italy; 3Technische
Inversitaet, Germany; 4INFN Bari, Italy; 5Uiversity of Rome, Italy; 6INFN
Lecce, Italy
M10-61 Prototype Integrated System of DOI- PET and the RF-Coil
Specialized for Simultaneous PET-MRI Measurements
F. Nishikido1, T. Obata1, N. Inadama1, E. Yoshida1, H. Tashima1, M. Suga2,
H. Murayama1, T. Yamaya1
1
National Institute of Radiological Sciences, Japan; 2Chiba University, Japan
M10-62 ClearPEM-Sonic: Performance Results and Clinical Phase One
Trial
M. Pizzichemi1, B. Frisch2, E. Auffray2, R. Bugalho3, L. Cao4, G. Cucciati1,
N. Di Vara1, F. Farina5, N. Felix6, A. Ghezzi1, V. Juhan7, D. Jun8, P.
Lasaygues9, P. Lecoq2, S. Mensah9, O. Mundler7, J. Neves3, M. Paganoni1, J.
Peter4, P. Siles7, J. C. Silva3, R. Silva3, S. Tavernier8, L. Tessonnier7, J. Varela3,
A. Carr10
1
University of Milano Bicocca, Italy; 2CERN, Switzerland; 3Laboratrio
de Instrumentao e Fsica Experimental de Particulas, Portugal; 4DKFZ,
Germany; 5Consortium GARR, Italy; 6SuperSonic Imagine, France; 7Assistance
Publique Hopitaux de Marseille, France; 8Vrije Universiteit Brussels, Belgium;
9
Laboratoire de Mecanique et Acoustique, France; 10Ecole Suprieure des Ingnieurs
de Luminy, France
M10-63 Intraoperative Beta-Gamma Probe for Real-Time Multi-Modal
Laparoscopic Surgery
K. Shimazoe, H. Takahashi, H. Liao, I. Sakuma, Y. Seto
M10-64 First Results from the BNL/Penn PET-MRI System for Whole
Body Rodent Imaging at 9.4T
M. Budassi1, M. L. Purschke2, J. Fried2, T. Cao1, S. Stoll2, E. Gualtieri3, J. S.
Karp3, P. O’Connor2, D. J. Schlyer2, C. L. Woody2, P. Vaska2
1
Stony Brook University, USA; 2Brookhaven National Laboratory, USA;
3
M10-65 Integrated PET/SPECT System for Breast Imaging with
CdZnTe: Computational Assessment
M. E. Myronakis, M. Zvelebil, D. G. Darambara
Institute of Cancer Research, UK
M10-66 An MR-Compatible Singles Detection and Processing Unit for
Simultaneous Preclinical PET/MR
B. Weissler1, P. Gebhardt2, M. Zinke1, F. Kiessling3, V. Schulz1,3
1
Philips Research, Germany; 2King’s College, United Kingdom; 3RWTH
University, Germany
M10-67 Deformable Registration for Breast PET-CT and MR Images
Based on Perturbation Weighted Feature Information
M. Ko1, H. Lee1, K.-M. Kim2, S.-K. Joo1, K. Lee1
1
Korea University, Korea; 2Korea Institute of Radiological & Medical Sciences,
Korea
M10-68 Evaluation of PET Image Quality and Distortions in
Simultaneous Clinical PET/MR
S. H. Keller1, A. E. Hansen1, T. Beyer1,2, F. L. Andersen1, T. L. Klausen1, J.
Loefgren1, S. Holm1
1
Copenhagen University Hospital, Rigshospitalet, Denmark; 2cmi-experts,
Switzerland
M10-69 SiPM-PET with a Short Optical Fiber Bundle for Extremity and
Small Animal PET-MR Imaging
S. J. Hong1, H. G. Kang1, G. B. Ko2, I. C. Song3, J. T. Rhee4, J. S. Lee2
1
Eulji University, Korea; 2Seoul National University College of Medicine, Korea;
3
Seoul National University Hospital, Korea; 4Konkuk University, Korea
M10-70 MR-Based Correction of PET/CT Artifacts Caused by Dental
Implants
G. Delso, S. D. Wollenweber, S. Ambwani, F. Wiesinger, GE Healthcare,
USA; P. Veit-Haibach, Universittsspital Zurich, CH
M10-71 Development of Breast and Tumour Models for Simulation
of Novel Multimodal PEM-UWB Technique for Detection and
Classification of Breast Tumours
R. C. Conceicao1, M. OHalloran2, R. Capote1, N. Matela1, H. Ferreira1, M.
Glavin2, E. Jones2, P. Almeida1
1
Instituto de Biofisica e Engenharia Biomedica, Portugal; 2Electrical & Electronic
Engineering, Ireland
M10-72 Determination of Potential Influences of PET Activity on
SPECT Measurements
J. G. Mannheim, B. J. Pichler
Eberhard Karls University of Tuebingen, Germany
M10-73 Truncation Completion of MR-Based PET Attenuation Maps
Using Time-of-Flight Non-Attenuation-Corrected PET Images
H. Qian, R. M. Manjeshwar, GE Global Research, United States; S. Ambwani,
S. D. Wollenweber, GE Healthcare, United States
M10-74 PET Performance Evaluation of a Pre-Clinical SiPM Based MRCompatible PET Scanner
J. E. Mackewn1, C. Lerche2, A. Salomon2, K. Sunassee1, R. Ayres2, C.
Tsoumpas1, G. Soultanidis1, T. Schaeffter1, P. Marsden1, V. Schulz1,2,3
1
King’s College London, UK; 2Philips Research Europe, Germany; 3University
Aachen, Germany
M10-75 Sparse Reconstruction of Transmission Scan in PET/MRI
K. Shi, X. Cheng, N. Navab, S. I. Ziegler
Technical University Munich, Germany
M10-76 Adaptation of the Brain PET Ring to Operate as an Insert in the
3Tesla MRI
S. Majewski, J. Brefczynski-Lewis, J. Lewis, B. Hou, A. Stolin, C. Bauer, K.
Tallaksen, R. Raylman, P. Martone
West Virginia University, USA
M10-77 Reference Database Driven Statistical Analysis of Automated
Frameless CT-MRI Registration Developed for Radiosurgical
Investigations
G. Opposits1, S. A. Kis1, T. Spisak1, E. Berenyi1, B. Szucs2, L. Bognar1, J. G.
Dobai1, E. Takacs3, L. Gulyas3, M. Emri1
1
University of Debrecen, Medical and Health Science Center, Hungary;
2
Scanomed Ltd., Hungary; 3Gamma Radiosurgery Centre Ltd., Hungary
M10-78 Development of a MR Compatible Brain PET II Using 4-Side
Tileable GAPD Arrays
J. H. Jung1, Y. Choi1, J. Jung1, S. Kim1, H. K. Lim1, K. C. Im1, H.-J. Choe1,
Y. Huh1,2, K. B. Kim1, C. H. Oh3, K. M. Kim4, J. G. Kim4, H.-W. Park3
1
Sogang University, Korea; 2Sungkyunkwan University School of Medicine,
korea; 3Korea Advanced Institute of Science and Technology, korea; 4Korea
Institute of Radiological and Medical Science, korea
M10-79 Initial Evaluation of a Multi-Pinhole Stationary SPECT Insert
for Simultaneous Small Animal SPECT-MR Imaging
B. M. W. Tsui, J. Xu, A. Rittenbach, A.-M. El-Sharkawy, W. A. Edelstein,
Johns Hopkins University, USA; K. Parnham, J. W. Hugg, Gamma Medica,
Inc., USA
M10-80 Feasibility Studies of Simultaneous PET and SPECT DualTracer Imaging with a Stationary Multi-Pinhole Collimator Inserted to
Animal PET Detector
J. Wu, T. Ma, H. Liu, Y. Xia, S. Chen, S. Wang, Y. Liu, J. Cheng
208 Thursday - MIC Poster Presentations Notes
Notes
Notes
07:00
07:30
08:30
09:00
09:30
10:00
M13: New Detector
Materials/Technologies for
Medical Imaging
M14: Data Correction
and Quantitative Imaging
Techniques 1
N44: New Concepts in SolidState Detectors II
NR1: NSS/RTSD Joint Session
N46: HEP Software
N45: Photodetectors and
Radiation Imaging Detectors III
08:00
MIC Refresher
Course 3
Friday, 2 November
Grand Ballroom
Center
Grand Ballroom
South
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
Grand Ballroom
North
Exhibit Hall North
Studio 51,
California Adventure
10:30
11:00
11:30
12:00
NP3: NSS Closing Session
R15: Pixeldetectors
M15: POSTER: Data
Corrections and Quantitative
Imaging Techniques
M16: POSTER: Emission
Tomography Instrumentation
1 / New Detector Materials
and Technologies for Medical
Imaging
12:30
13:00
13:30
14:00
14:30
R16: Contacts
and Defects
15:00
He-1
15:30
16:00
M17: POSTER: Image Reconstruction Methods 2 / IntraOperative Probes and Portable
Imaging Systems
Tomography
16:30
17:00
17:30
18:00
M19: Image Reconstruction
Methods 2
18:30
M20: Other Medical Imaging
Technologies (CT, MR, Optical,
Ultrasound, etc.)
He-2
19:00
MIC Dinner
214 214
Friday - NSS Oral Presentations
N44 New Concepts in Solid-State Detectors II
Friday, Nov. 2 08:00-10:00 Magic Kingdom Ballroom 1
Session Chairs: Grzegorz Deptuch, Fermilab, USA
Gabriella A. Carini, SLAC National Accelerator
Laboratory, USA
N44-1 (08:00) 3D Integration Technique of SOI Image Sensors
T. Miyoshi, Y. Arai, High Energy Accelerator Research Organization, Japan; P.
Denes, Lawrence Berkeley National Laboratory, USA; H. Kasai, N. Kuriyama,
N. Miura, Lapis Semiconductor Miyagi Co., Ltd., Japan; M. Motoyoshi,
Tohoku-MicroTec Co., Ltd., Japan; Y. Nagatomo, M. Okihara, Lapis
Semiconductor Co., Ltd., Japan; A. Takeda, Graduate University for Advanced
Studies, Japan
N44-2 (08:15) Development of In-Pixel Multi-Gain Amplifiers with
Charge-Division Structure for High Peak Signal Measurement in XFEL
Applications
M. Omodani1, T. Kudo2, K. Kobayashi2, T. Imamura3, T. Ohmoto3, A.
Iwata3, A. Kiyomichi1, S. Ono2, Y. Kirihara2, M. Okihara4, T. Hatsui1,2
1
Japan Synchrotron Radiation Research Institute, Japan; 2RIKEN, Japan; 3A-RTec Corp., Japan; 4LAPIS Semiconductor Co., Ltd., Japan
N44-3 (08:30) Improvement of Specificity of Charge Collection in
Planar Pixelated SOI Detectors for Medical Applications
M. L. F. Lerch1, J. Livingstone1, D. A. Prokopovich2, M. Petasecca1, S.
Guatelli1, M. I. Reinhard2, V. Perevertaylo3, A. B. Rosenfeld1
1
University of Wollongong, Australia; 2Australian Nuclear Science and
Technology Organisation, Australia; 3SPA-BIT, Ukraine
N44-4 (08:45) A Digital Monolithic Active Pixel Sensor Chip in a
Quadruple-Well CIS Process
Y. Degerli1, G. Bertolone2, G. Claus2, A. Dorokhov2, W. Dulinski2, M.
Goffe2, C. Hu-Guo2, K. Jaaskelainen2, F. Morel2, F. Orsini1, M. Specht2, M.
Winter2
1
CEA - Saclay, France; 2IN2P3, France
N44-5 (09:00) A 2.5 μm Pitch CMOS Active Pixel Sensor in 65 nm
Technology
D. Contarato, P. Denes, D. Doering, J. Joseph, B. Krieger, S. Schindler
N44-6 (09:15) CMOS MAPS in a Homogeneous 3D Process for
Charged Particle Tracking
A. Manazza1, L. Gaioni2, M. Manghisoni2, L. Ratti1, V. Re2, G. Traversi2, S.
Bettarini3, F. Morsani4, G. Rizzo2
1
University of Pavia and INFN, Italy; 2University of Bergamo and INFN, Italy;
3
University of Pisa and INFN, Italy; 4INFN, Italy
N44-7 (09:30) 3D-S: a Fast, High Resolution, Low Mass, 3D Silicon
Detector with Embedded Cooling and Internal Charge Multiplication
Capability
C. Da Via1, G. Dalla Betta2, C.-H. Lai1, M. Povoli2, S. Watts1, M.
Boscardin3, J. Hasi4, I. Haughton1, A. Kok5, G. Pellegrini6, C. Kenney4, S.
Paerker7, G. Darbo8, S. Grinstein9, P. Grenier4
1
University of Manchester /CERN, UK; 2University of Trento, Italy; 3FBK, Italy;
4
SLAC, USA; 5SINTEF, Norway; 6CNM, Spain; 7The University of Hawaii,
USA; 8INFN, Italy; 9Universitat Autonoma de Barcelona, Spain
N44-8 (09:45) Quantitative Radiolabeled Biomolecule Detection Using
a Functionalized CMOS Sensor
R. H. Griffin1, O. Mozenson2, M. Beking1, G. Lopinski2, M. DeRosa1, G.
Tarr1
1
Carleton University, Canada; 2National Research Council, Canada
Friday - NSS Oral Presentations 215
Detectors III
Session Chairs: Chikara Fukunaga, Tokyo Metropolitan University, Japan
Samo Korpar, University of Maribor, Slovenia
N45-1 (08:00) The NA62 RICH Detector
A. Cassese, Universita’ degli Studi di Firenze and INFN, sezione di Firenze,
Italy
On behalf of the NA62 RICH Working Group: CERN, INFN Firenze,
INFN Perugia
N45-2 (08:15) A APD Readout for a EL Detector Based on Xenon
T. Lux, O. Ballester, J. Illa, G. Jover Maas, C. Martn, F. Sanchez, IFAE,
Spain; J. Rico, IFAE/ICREA, Spain; R. Santorelli, CIEMAT, Spain
N45-3 (08:30) Large Dynamic Range Silicon Photomultiplieres for the
CERN CMS Experiment
T. Ganka1, F. Wiest2, P. Iskra2, C. Dietzinger1, W. Hansch1
1
Universitaet der Bundeswehr Munich, Institute for Physics, Germany; 2KETEK
GmbH, Germany
N45-4 (08:45) Improved SiPM Device Performance by Indroduction of
a New Manufacturing Technology
F. Wiest, P. Iskra, N. Miyakawa, W. Gebauer, KETEK GmbH, Germany; C.
Dietzinger, T. Ganka, Universitaet der Bundeswehr Muenchen, Germany
N45-5 (09:00) Mitigation of Anomalous APD Signals in the CMS ECAL
K. Theofilatos, ETH Zurich, Switzerland
N45-6 (09:15) 3-D Compton Image Reconstruction with a Gridless
Point Cloud
A. Haefner1, D. Gunter2, L. Mihailescu2, J. Maltz2, K. Vetter1,2
1
University of California at Berkeley, USA; 2Lawrence Berkeley National Lab,
USA
N45-7 (09:30) X-Ray Detection by Means of Organic Photodiode with
nA/cm2 Dark Current
A. Iacchetti1,2, M. Binda2, D. Natali1,2, G. Azzellino1,2, L. Beverina3, C.
Fiorini2, R. Peloso2, M. Sampietro1,2
1
Politecnico di Milano, Italy; 2Italian Institute of Technology, Italy; 3University of
Milano-Bicocca, Italy
N45-8 (09:45) New Development of Silicon Drift Detectors for GammaRay Spectroscopy
L. Bombelli1,2, C. Fiorini1,2, R. Peloso1,2, R. Quaglia1,2, P. Bellutti3, M.
Boscardin3, F. Ficorella3, G. Giacomini3, A. Picciotto3, C. Piemonte3, N.
Zorzi3
1
Politecnico di Milano, Italy; 2INFN Sez. Milano, Italy; 3Fondazione Bruno
Kessler - FBK, Italy
N46-4 (08:45) How the Monte Carlo Production of a Wide Variety of
Different Samples Is Centrally Handled in the LHCb Experiment.
G. Corti, European Organization for Nuclear Research (CERN), Switzerland
N46-5 (09:00) LCIO 2.0: an Experiment-Independent Event Data
Model and Persistency Format for HEP
N. Graf1, T. Johnson1, F. Gaede2, J. McCormick1, J. Engels2, S. Aplin2
1
SLAC National Accelerator Laboratory, USA; 2DESY, Germany
N46-6 (09:15) CMS Computing Experience at LHC
D. Bonacorsi, University of Bologna, Italy
N46-7 (09:30) Simulation Studies for a New ATLAS Inner Detector for
the High-Luminosity LHC
N. A. Styles, DESY, Germany
N46-8 (09:45) Code and Papers: Computing Publication Patterns in the
LHC Era
T. Basaglia, CERN, Switzerland; Z. W. Bell, ORNL, USA; P. V.
Dressendorfer, IEEE, USA; M. G. Pia, INFN Genova, Italy
NP3 Closing Session NP3
Friday, Nov. 2 10:30-12:00 Grand Ballroom Center
Session Chairs: Maxim P. Titov, CEA Saclay, IRFU/SPP, France
NP3-1 (10:30, invited) Project X: Technology, Perspectives and
Applications
S. Holmes, Fermi National Accelerator Laboratory, USA
NP3-2 (11:15, invited) Plenary Talk
TBD
NP3-3 (12:00) Closing Remarks
M. Titov, CEA Saclay, France, I.-M. Gregor, DESY, Germany
N46 HEP Software
Session Chairs: Douglas Wright, Lawrence Livermore National
Laboratory, USA
Gabriela Hoff, Pontifical Catholic University in Rio
Grande do Sul, Brazil
N46-1 (08:00, invited) The Online Software for the LHC Experiments
G. Lehmann Miotto, CERN, Switzerland
N46-2 (08:15) Role-Based Access Approach for Controlling Who Can
Do What in the CERN Accelerator Complex
P. Charrue, W. Sliwinski, I. Yastrebov, CERN, Switzerland
N46-3 (08:30) ATLAS Fast Simulation: Atlfast-II and ISF (Integrated
Simulation Framework)
P. Clark, University of Edinburgh, UK
216 Friday - NSS Oral Presentations Friday - NSS Oral Presentations 217
Friday - MIC Oral Presentations
M13 New Detector Materials/Technologies
for Medical Imaging
Session Chairs: Christian Morel, CPPM, Aix-Marseille II University,
France
Paul Vaska, Brookhaven National Laboratory, USA
M13-1 (08:15) A Single Photon Avalanche Photodiode and Time to
Digital Converter Implemented in Standard CMOS Technology for PET
Applications
D. Palubiak, E. Nemati, H. Peng, J. Deen
McMaster University, Canada
M13-2 (08:30) Timing Performance of Fast Timing Silicon
Photomultipliers
J.-Y. Yeom1, N. Pavlov2, S. Bellis2, K. ONeill2, C. Jackson2, C. Levin1
1
Stanford University, USA; 2SensL Technologies Ltd., Ireland
M13-3 (08:45) Microcolumnar Ba2CsI5:Eu Sensor for High-Resolution
X-Ray CT
H. B. Bhandari, L. Ovechkina, V. Gelfandbein, S. R. Miller, B. Singh, V. V.
Nagarkar
RMD, Inc., USA
M13-4 (09:00) DOI Determination Using Signal Rise Time - a
Technique for Improving Both Timing and Spatial Resolution in TOF
PET Detectors
R. I. Wiener, M. Kaul, S. Surti, J. S. Karp
M13-5 (09:15) X’tal Cube Detector Composed of a Stack of Scintillator
Plates Segmented by Laser Processing
N. Inadama1, T. Moriya2, Y. Hirano1, F. Nishikido1, H. Murayama1, E.
Yoshida1, H. Tashima1, M. Nitta3,1, H. Ito1, T. Yamaya1
1
National Institute of Radiological Sciences, Japan; 2Hamamatsu Photonics K.K.,
Japan; 3Chiba University, Japan
M13-6 (09:30) Three-Dimensional Position Sensitive CdTe Detector
Unit for High Resolution Human PET Scanner
Y. Kikuchi, K. Ishii, S. Takyu, A. Terakawa, S. Matsuyama, T. Kanamaru, A.
Mohammednur, H. Yamazaki
M13-7 (09:45) A Short Drift GEM Tracking Detector for Measuring
Escaped Positrons in PET
T. Cao1, B. Azmoun2, S. Stoll2, M. L. Purschke2, P. Vaska1, C. L. Woody2
1
Stony Brook University, USA; 2Brookhaven National Lab, USA
M14 Data Correction and Quantitative
Imaging Techniques 1
Friday, Nov. 2 08:15-10:00 Grand Ballroom South AB
Session Chairs: Frederic Noo, University of Utah, Dept of Radiology,
USA
Roger Fulton, University of Sydney,
M14-1 (08:15) 4D PET Iterative Deconvolution in Wavelet Space with
Basis Function-Based Regularization for Quantitative Dynamic PET
Imaging
A. Reilhac1, G. Angelis2, C. Wimberley1,2, F. Boisson1, S. R. Meikle2, M.-C.
Gregoire1
1
ANSTO, Australia; 2Brain and Mind Research Institute, Australia
218 Friday - MIC Oral Presentations M14-2 (08:30) Low Dose Interpolated Average CT for PET/CT
Attenuation Correction Using an Active Breathing Controller (ABC)
T. Sun1, H. T. Wu2, Y. N. Wu3, G. S. P. Mok1
1
University of Macau, China; 2National Yang Ming University, Taiwan; 3Taipei
Veterans General Hospital, Taiwan
M14-3 (08:45) Robust Primary Modulation-Based Scatter Estimation
for Cone-Beam CT
L. Ritschl, Institute of Medical Physics (IMP), University of Erlangen-Nürnberg,
Germany; R. Fahrig, Stanford University, USA; M. Kachelrieß, German
Cancer Research Center(DKFZ), Germany
M14-4 (09:00) Multi-Modal Rigid and Non-Rigid Registration for
Attenuation Correction in Cardiac SPECT/CT Using Emission to CT
Conversion
J. Dey, A. Konik, M. A. King
University of Massachusetts Medical School, USA
M14-5 (09:15) Dynamic Assessment of Head Motion Compensation for
the HRRT
X. Jin, T. Mulnix, J.-D. Gallezot, R. E. Carson
M14-6 (09:30) Development and Characterization of a Non-Rigid PVA
Cryogel Phantom for Simultaneous PET-MR Acquisitions
G. M. Soultanidis, J. E. Mackewn, C. Tsoumpas, P. Halsted, P. K. Marsden
M14-7 (09:45) A Hand Phantom for the Quantitative Assessment of
Nuclear Medicine-Based Extremity Imaging
F. Godinez, A. Ferrero, R. D. Badawi, A. J. Chaudhari
University of California Davis, USA
M19 Image Reconstruction Methods 2
Session Chairs: Samuel Matej, University of Pennsylvania, USA
Kris Thielemans, Algorithms and Software Consulting,
United Kingdom
M19-1 (16:30) List-Mode Reconstruction for the Biograph mCT PET/
CT with a Probabilistic Line-of-Response Positioning Technique and
Motion Correction
X. Jin, C. Chan, T. Mulnix, C. Liu, R. E. Carson
M19-2 (16:45) Optimizing MAP reconstruction of 3D TOF PET
R. Ren1, B. Bai1, Q. Li2, R. M. Leahy1
1
University of Souther California, US; 2Havard University, US
M19-3 (17:00) Application of Adaptive Kinetic Modelling for Bias
Propagation Reduction in Direct 4D Image Reconstruction
F. A. Kotasidis1,2, J. C. Matthews2, A. J. Reader3, G. I. Angelis4, H. Zaidi1
1
University of Geneva, Switzerland; 2University of Manchester, United Kingdom;
3
McGill University, Canada; 4University of Sydney, Australia
M19-4 (17:15) Penalized Maximum-Likelihood Image Reconstruction
for 3D Breast Lesion Detection
L. Yang, J. Zhou, J. Qi
University of California Davis, USA
M19-5 (17:30) Convergent Iterative Algorithms for Joint Reconstruction
of Activity and Attenuation from Time-of-Flight PET Data
S. Ahn, H. Qian, R. M. Manjeshwar, GE Global Research, USA
M19-6 (17:45) EM Reconstruction of Dual Isotope PET with Staggered
Injections and Prompt Gamma Positron Emitters
A. Andreyev1, A. Sitek2,3, A. Celler1
1
University of British Columbia, Canada; 2Brigham and Women’s Hospital,
USA; 3Harvard Medical School, USA
Friday - MIC Oral Presentations 219
M19-7 (18:00) Design of a Spatially-Variable-Focusing Collimator for
Small-Animal SPECT
D. Benoit1, J. Bonte1, M. Leabad2, S. Maitrejean2, F. Mathy3, G.
Montemont3, I. Buvat1
1
QIM IMNC-IN2P3/CNRS, FRANCE; 2Biospace Lab company, FRANCE;
3
CEA-LETI, FRANCE
M19-8 (18:15) 4-D Motion Field Estimation by Combined Multiple
Heart Phase Registration (CMHPR) for Cardiac C-Arm Data
K. Mueller1, C. Rohkohl2, G. Lauritsch2, C. Schwemmer1, H. Heidbuechel3,
S. De Buck3, D. Nuyens3, Y. Kyriakou2, C. Koehler2, J. Hornegger1
1
Germany; 3University of Leuven, Belgium
M20 Other Medical Imaging Technologies
(CT, MR, Optical, Ultrasound, etc.)
Friday, Nov. 2 16:30-18:30 Grand Ballroom South AB
Session Chairs: Jovan G. Brankov, Illinois Institute of Technology, USA
Paul E. Kinahan, University of Washington, USA
M20-1 (16:30) Basis element decomposition with spectral microCT
using multi-layered, multi-colored scintillators
D. S. Rigie1, D. Modgil1, P. Vargas1, S. Wang2, P. J. La Riviere1
1
University of Chicago, USA; 2Argonne National Lab, USA
M20-2 (16:45) A Preliminary Investigation of CT-Dose Reduction for
SPECT/CBCT Attenuation Correction
J. Bian1, J. Wang2, X. Han1, E. Y. Sidky1, L. Shao2, X. Pan1
1
The University of Chicago, US; 2Philips Healthcare, US
M20-3 (17:00) Dose Reduction for High-Contrast Abdominal CT to the
Pediatric and Adult with Spectral Optimization: a Phantom Study
P.-H. Jeon, C.-L. Lee, D.-H. Kim, H.-J. Kim
Yonsei university, Republic of Korea
M20-4 (17:15) Low Dose Perfusion CT
D. J. Heuscher, J. Zhang, F. Noo
University of Utah, USA
M20-5 (17:30) Asymmetric-Filter Cone-Beam Dual-Energy Computed
Tomography
Y. Yamazaki, N. Toda, Aichi Prefectural University, Japan
M20-6 (17:45) Task Based Characterization of Spectral CT Performance
via the Hotelling Observer
D. S. Rigie, P. J. La Riviere
University of Chicago, USA
M20-7 (18:00) Non-Invasive Image-Guided Brain Access with Gradient
Propulsion of Magnetic Nanoparticles
I. N. Weinberg1, A. Nacev2, A. Sarwar2, O. Rodriguez3, C. Albanese3, B.
Shapiro2, P. Y. Stepanov1, D. Beylin1, M. Urdaneta1, R. Probst2, S. T. Fricke4
1
Weinberg Medical Physics, USA; 2University of Maryland, USA; 3Georgetown
University, USA; 4Children’s National Medical Center, USA
M20-8 (18:15) The Investigation of Radionuclides 18F, 64Cu, 198Au,
32P, and 76Br as Tracers for Cherenkov Light Imaging
S. A. Komarov1, T. Aweda1, C. Cutler2, Y. Liu1, Y.-C. Tai1
1
Washington University in St.Louis, USA; 2University of Missouri Research
Reactor, USA
Friday - RTSD Oral Presentations
R15 Pixel detectors
Friday, Nov. 2 Session Chair: 10:30-12:25 Magic Kingdom Ballroom 2
Christer Frojdh, Mid Sweden University, Sweden
R15-1 (10:30, invited) Characterization of CdTe Semiconductor
Material Using Timepix Readout Chip
Z. Vykydal1, A. Fauler2, M. Fiederle2, J. Jakubek1, M. Jakubek1, S. Pospisil1,
J. Zemlicka1, A. Zwerger2
1
Czech Technical University in Prague, Czech Republic; 2Albert-LudwigsUniversität, Germany
R15-2 (10:50, invited) A CdTe-CMOS Hybrid for Energy, Position and
Time Identification
C. P. Lambropoulos1, G. Theodoratos1, D. S. Hatzistratis1, M. Zervakis1, I.
Kazas2, S. Vlassis3, D. Loukas2
1
Technological Educational Institute of Chalkida, Greece; 2National Center of
Scientific Research Demokritos, Greece; 3University of Patras, Greece
R15-3 (11:10) Pixelated CdZnTe for Imaging in Medicine: Overall
Performance Assessment Using an Advanced Computational Modeling
Framework
M. E. Myronakis, M. Zvelebil, D. G. Darambara
Institute of Cancer Research, UK
R15-4 (11:25) Development of GaAs Pixel Detectors Using Medipix
Electronic
M. Fiederle1, A. Fauler1, E. Hamann2, M. Pichotka1, A. Tyazhev3, O.
Tolbanov3, G. Shelkov4, H. Graafsma5
1
Freiburger Materialforschungszentrum, Germany; 2Karlsruher Institute of
Technology, Germany; 3Tomsk State University, Russia; 4Joint Institute for
Nuclear Research, Russia; 5DESY, Germany
R15-5 (11:40) Charge Transport and Signal Formation in Pixellated
Cadmium Telluride Detectors
D. Krapohl1, C. Frojdh1, E. Frojdh1, E. Gimenez2, D. Maneuski3, H.-E.
Nilsson1, V. O’Shea3, N. Tartoni2, G. Thungstrom1, H. Wilhelm2, R. M. Zain3
1
Mid Sweden University, Sweden; 2Diamond Light Source, United Kingdom;
3
Glasgow University, United Kingdom
R15-6 (11:55) A New Four-Side Abuttable ASIC for High-Resolution
Multi-Energy CT Imaging Detector Arrays
M. Clajus1, S. Snyder1, D. Castruita1, S. J. Glick2, A. Makeev2, K. Saha2, R.
Stinnett1, A. Volkovskii1, F. Walker1
1
NOVA R&D, Inc., USA; 2University of Massachusetts Medical School, USA
R15-7 (12:10) Development of CdZnTe Detector for Low Energy X-Ray
Photon Counting Imaging
H. Chen, U. El-hanany, J. Kumar, G. Prekas, S. Taherian, A. Densmore, L.
Gusak, P. Lu, G. Macaloney, G. Bindley, Redlen Technologies, Canada
R16 Contacts and Defects
Friday, Nov. 2 Session Chair: 14:00-14:45 Magic Kingdom Ballroom 2
Ian Radley, Kromek, USA
R16-1 (14:00) Experimental 3D Contacts for CZT Detectors
M. Turqueti, A. Soriano, B. Cardoso, Creative Electron, USA
R16-2 (14:15) Observations of a Deep-Donor Recharge and Its
Influence on Trapping in Detector-Grade CdZnTe
V. Babentsov, F. Sizov, Institute of Semiconductor Physics, Ukraine; J. Franc,
Charles University, Czech Republic; R. B. James, Brookhaven National
Laboratory, USA
220 Friday - MIC Oral Presentations Friday - RTSD Oral Presentations 221
R16-3 (14:30) Point Defects Characterization in Intrinsic and Doped
CdTe and CDSE Detectors
R. Gul, A. E. Bolotnikov, K. H. Kim, A. Hossain, G. S. Camarda, G. Yang,
Y. Cui, R. B. James, Brookhaven National Lab., USA
Friday - Joint Oral Presentations
NR01 NSS/RTSD Joint Session
Session Chairs: Jan S. Iwanczyk, DxRay, Inc., USA
NR01-1 (08:00, invited) Development of a 4cm2 Small Pixel CdTe
Spectroscopic Detector
M. C. Veale1, S. Bell1, A. Schneider1, P. Seller1, M. D. Wilson1, J.
Scuffham2,3, P. J. Sellin2, R. J. Cernik4, C. Egan4, S. Jacques4, J. Kalliopuska5,
H. Pohjonen5, H. Andersson6, S. Nenonen6
1
STFC Rutherford Appleton Laboratory, UK; 2University of Surrey, UK; 3Royal
Surrey County Hospital NHS Foundation Trust, UK; 4University of Manchester,
UK; 5VTT, Finland; 6Oxford Instruments Analytical, Finland
NR01-2 (08:15) Scribe-Cleave-Passivate (SCP) Slim Edge Technology
for Silicon Sensors
V. A. Fadeyev, UCSC, USA
NR01-3 (08:30) Effect of Dislocation Walls on Charge Carrier
Mobilitylifetime Product in Single Crystal CdTe
C. Buis1, A. Lohstroh2, G. Marrakchi3, C. Jeynes2, L. Verger1, E. Gros
daillon1
1
CEA/LETI/MINATEC Campus, France; 2University of Surrey Ion Beam
Centre, England; 3Université de Saint-Etienne, Jean Monnet, France
NR01-4 (08:45) Liquidmetal Micro-Droplet Arrays Based Bonding
M. Kocsis, M. Ruat
European Synchrotron Radiation Facility, France
NR01-5 (09:00) Results of a Multi Project Wafer Process of Edgeless
Silicon Pixel Detectors
J. J. Kalliopuska, X. Wu, T. Virolainen, VTT, Finland; J. Jakubek, Institute of
Experimental and Applied, Czech Republic
NR01-6 (09:15) A Study of Amorphous Semiconductor Contact
Behavior on High-Purity Germanium Detectors
Q. Looker1,2, M. Amman2, K. Vetter1,2
1
UC Berkeley, USA; 2Lawrence Berkeley National Laboratory, USA
NR01-7 (09:30) Structural Defects in CdTe: a Microscale Study with
Collimated Synchrotron Beam
M. Ruat, C. Ponchut, ESRF, FRANCE
NR01-8 (09:45) Polaris CdZnTe Gamma-Ray Imaging Spectrometers
Using BNL ASICs
Z. He, F. Zhang, W. R. Kaye, W. Wang, Y. Boucher, J. M. Jaworski, J. D.
Mann, J. E. Berry, S. J. Kaye
The University of Michigan, USA
222 Friday - RTSD Oral Presentations Friday - Joint Oral Presentations 223
Friday - Workshop Oral
Presentations
Perspectives on 3He Replacements for
Neutron Detection
He-2 Perspectives on He-3 Replacements for
Neutron Detection II
Friday, Nov. 2 16:30-18:45, Magic Kingdom Ballroom 3
Germany
Richard Kouzes, Pacific Northwest National Laboratory,
USA
He-2-1 (16:00) Thermal Neutron Detection System Based on ZnS/LiF
He-1 Perspectives on He-3 Replacements for
Neutron Detection I
Friday, Nov. 2 14:00-16:00, Magic Kingdom Ballroom 3
Germany
Richard Kouzes, Pacific Northwest National Laboratory,
USA
He-1-1 (14:02) Detectors for the European Spallation Source
R. J. Hall-Wilton1, C. Hoglund1,2, K. Kanaki1, A. Khaplanov1,3, O. Kirstein1,
T. Kittelmann1, B. Nilsson1,4, J. Scherzinger1,5
1
European Spallation Source ESS AB, Sweden; 2Linkoping University, Sweden;
3
Institut Laue-Langevin, France; 4Maxlab, Sweden; 5Lund University, Sweden
He-1-2 (14:17) Neutron Detector for the Instruments of CSNS
Z. Sun, Y. Chen, Y. Zhao, J. Zhou, B. Tang, G. Yang, H. Xu, Y. Wang, Z.
Yang
Institute of High Energy Physics, Chinese Academy of Sciences, China
He-1-3 (14:32) Development of the Boron-10 Multi-Grid Detector for
Large Area Instruments in Neutron Scattering Science
J. Birch1, J.-C. Buffet2, J. Correa2, R. Hall-Wilton3, C. Hoglund3, B.
Guerard2, A. Khaplanov3, F. Piscitelli2, P. Van Esch2
1
Linkping University, Sweden; 2ILL, France; 3ESS, Sweden
He-1-4 (14:47) The Development of Scintillation Detectors to Replace
3He Detector Technology in Neutron Scattering Applications
N. J. Rhodes, STFC, United Kingdom
On behalf of the International Collaboration on Neutron Detectors /
Scintillation Detector Working Group /
He-1-5 (15:02) Linear-Position-Sensitive Twin Tubes with 10BF3 for
Cold Neutron TOF-Spectrometer
T. Wilpert, S. Alimov, C. Schulz, C. Rethfeldt
Helmholtz-Zentrum Berlin, Germany
He-1-6 (15:17) A Large Inelastic Scattering Instrument Based on
10B4C-Coated Straw Detectors
J. L. Lacy, L. Sun, A. Athanasiades, C. S. Martin, G. J. Vazquez, Z.
Sobolewski
Proportional Technologies, Inc., U.S.A.
He-1-7 (15:32) Validating MCNPX Models of Boron-10-Lined
Detectors
A. T. Lintereur, J. H. Ely, R. T. Kouzes, E. R. Siciliano
He-1-8 (15:47) 6Li Isotope Availability, Handling, Forming, and
Processing Capability at the Y-12 National Security Complex
W. T. Rogerson, Jr., S. W. Brown, E. M. Parker
Y-12 National Security Complex, USA
224 Friday - Workshop Oral Presentations Scintillator
Z. W. Bell, D. E. Hornback, Oak Ridge National Laboratory, USA; H.
Workman, C. Kline, J. C. Collins, PartTec, Ltd., USA
He-2-2 (16:15) Neutron Detectors with Scintillators Using ZnS:Ag
Phosphor: Development Summary
M. Katagiri, Ibaraki University, Japan
He-2-3 (16:30) Low Background Fast Neutron Detection
G. Davatz1,2, R. Chandra1, H. Friederich1,2, U. Gendotti1, L. Goeltl1, D.
Murer1,2
1
Arktis Radiation Detectors Ltd, Switzerland; 2ETH Zurich, Switzerland
He-2-4 (16:45) Fast Neutron Detections with Cs2NaYCl6
J. Glodo, U. Shirwadkar, R. Hawrami, L. S. Pandian, K. S. Shah
He-2-5 (17:00) Investigation on Thermal Neutron Detectors Based on
the Gas Elctron Multiplier Technology
A. Pietropaolo, CNR-IFP, Italy; F. Murtas, G. Claps, L. Quintieri, INFNLNF, Italy; G. Celentano, ENEA Centro Ricerche Frascati, Italy; D. Raspino,
STFC ISIS Facility, United Kingdom
He-2-6 (17:15) Broad Spectrum Neutron Scintillation Detectors
A. Cole, J. McMillan, University of Sheffield, United Kingdom; E. Marsden,
TATA steel, United Kingdom
He-2-7 (17:30) High Intrinsic Efficiency Solid State Neutron Detector
and Spectrometer
E. R. Myers1, T. M. Oakes2, S. L. Bellinger3, W. H. Miller2, T. J. Sobering3,
D. Huddleston3, P. R. Scott1, B. W. Cooper3, B. F. Phlips4, M. S. Strickman4,
L. A. Jackson4, K. Mattson4, W. N. Johnson4, J. W. Schumer4, R. J.
Commisso4, S. L. Jackson4, J. C. Zier4, R. G. Fronk3, P. B. Ugorowski3, J. K.
Shultis3, D. S. McGregor3, A. N. Caruso1
1
University of Missouri - Kansas City, USA; 2University of Missouri - Columbia,
USA; 3Kansas State University, USA; 4Naval Research Laboratory, USA
He-2-8 (17:45) Neutron Response with Different Sized Eu Doped
LiCaAlF6 Crystals
N. Kawaguchi1, T. Yanagida2, Y. Fujimoto2, A. Yamazaki3, K. Watanabe3, K.
Fukuda1, Y. Futami2, S. Kurosawa2, Y. Yokota2, A. Yoshikawa2
1
Tokuyama corp., Japan; 2Tohoku Univ., Japan; 3Nagoya Univ., Japan
Friday - Workshop Oral Presentations 225
Friday - MIC Poster Presentations
M15 POSTER: Data Corrections and
Quantitative Imaging Techniques
Friday, Nov. 2 10:30-12:30 Grand Ballroom North
Session Chairs: Magdalena Rafecas, Instituto de Fisica Corpuscular
(IFIC), Universidad de Valencia - CSIC, Spain
Arman Rahmim, Johns Hopkins University, USA
M15-1 Application of Novel Calibration Scheme Based on Traceable
Point-Like 22Na Sources to Various Types of PET Scanners
T. Hasegawa1, K. Oda2, Y. Wada3, Y. Sato4, T. Yamada5, M. Matsumoto5, H.
Murayama6, T. Takeda1, T. Sasaki7, K. Kikuchi8, Y. Abe8, H. Miyatake8, K.
Miwa9, K. Akimoto9, K. Wagatsuma9
1
Allied Health Sciences, Kitasato University, Japan; 2Tokyo Metropolitan
Institute of Gerontology (TMIG), Japan; 3RIKEN Center for Molecular Imaging
Research Science, Japan; 4National Institute of Advanced Industrial Science
and Technology (AIST), Japan; 5Japan Radioisotope Association (JRIA), Japan;
6
National Institute for Radiological Sciences (NIRS), Japan; 7Cyclotron Center,
Iwate Medical University, Japan; 8Kitasato University Hospital, Japan; 9Cancer
Institute Hospital, Japan
M15-2 An Examination of the Effect of Registration Error on PET-FDG
Evaluation of Chemotherapy Response in Sarcoma
E. Wolsztynski, F. O’Sullivan, S. Roy, J. O’Sullivan, University College Cork,
Ireland; J. F. Eary, University of Washington, USA
M15-3 Enhancing Clinical Utility of Respiratory-Gated PET/CT Using
Patient Respiratory Trace Classification
S. R. Bowen1, L. A. Pierce1, A. M. Alessio1, C. Liu2, P. E. Kinahan1
1
University of Washington, USA; 2Yale University, USA
M15-4 Acute Stress Studies in Rats by 18FDG PET and SPM
F. Gallivanone1, G. Di Girgoli2, C. Salvatore3, S. Valtorta1, M. C. Gilardi1, R.
M. Moresco3, I. Castiglioni1
1
CNR, Italy; 2Tecnomed Foundation, Italy; 3University of Milano-Bicocca, Italy
M15-5 An Investigation into Attenuation Artefacts Created by Cochlear
Implants in Positron Emission Tomography
J. C. Matthews1, D. Balfour1, M. Vallance1, J. Anton-Rodriguez1, K. Green1,2
1
University of Manchester, UK; 2Central Manchester Foundation Trust, UK
M15-6 Geometric Jitter Compensation in Cone-Beam CT Through
Registration of Directly and Indirectly Filtered Projections
F. Dennerlein, A. Jerebko, T. Mertelmeier
Siemens AG, Healthcare Sector, Germany
M15-7 Temperature Dependence of the LabPET Small-Animal PET
Scanner
V. Keereman, C. Vanhove, R. Van Holen, S. Vandenberghe
MEDISIP - Department of Electronics and Information Systems, Belgium
M15-8 Automatic Generation of Reconstruction Limits for Myocardial
Perfusion SPECT Processing
S. Dwivedi, A. J. Da Silva, J. Ye, L. Shao
Philips Healthcare, USA
M15-9 A Comparison of the Options for Brain Partial Volume
Correction Using PET/MRI
B. A. Thomas1, K. Erlandsson1, A. Reilhac2, A. Bousse1, D. Kazantsev1, S.
Pedemonte1, K. Vunckx3, S. Arridge1, S. Ourselin1, B. Hutton1
1
University College London, UK; 2Australian Nuclear Science and Technology
Organization, Australia; 3K.U. Leuven, Belgium
M15-10 Low-Dose Quantitative Cone-Beam CT Imaging in Radiation
Therapy
T. Niu, L. Zhu, Georgia Institute of Technology, USA
226 Friday - MIC Poster Presentations M15-11 On-Line Spatio-Temporal Independent Component Analysis
for Motion Correction in Renal DCE-MRI
S. Kiani1, I. Gordon2, D. Windridge1, K. Wells1
1
University of Surrey, United Kingdom; 2University College London, United
Kingdom
M15-12 Handling of Bad Pixels on Pixelated Solid State Detectors
C. Bai, R. Conwell, H. Babla, J. Kindem, M. Gurley
Digirad Corporation, USA
M15-13 Experimental Evaluation and Image Reconstruction Based
Optimization of the Spatially Variant PSF on the Ingenuity TF PETMR
Scanner
F. A. Kotasidis1,2, S. Heinzer3, H. Zaidi1
1
University of Geneva, Switzerland; 2University of Manchester, UK; 3Philips AG
Healthcare, Switzerland
M15-14 Isotope Dependent System Matrices for High Resolution PET
Imaging
F. A. Kotasidis1,2, G. I. Angelis3, J. Anton-Rodriguez2, J. C. Matthews2, A. J.
Reader4, M. Green2, H. Zaidi1
1
3
University of Sydney, Australia; 4McGill University, Canada
M15-15 Metric for Fast Automated Relative Assessment of Motion
Correction Methods for Dynamic PET Imaging
S. Hafezian1, J. Cottitto1, A. J. Reader1, J. Verhaeghe1,2
1
Mcgill University, Canada; 2University of Antwerp, Belgium
M15-16 Generation of Normalization Maps for Pixelated Pinhole
SPECT Detectors by Scanning a Uniform Cylinder Phantom
B. Feng, D. W. Austin, Siemens Medical Solutions USA, USA
M15-17 Optimization of a Model Corrected Blood Input Function from
Dynamic FDG-PET Images of Small Animal Heart in vivo
M. Zhong, B. K. Kundu, University of Virginia, US
M15-18 Calibration of X-Ray Photon-Counting Pixel Detectors Using
Laboratory Polychromatic X-Ray Beams
H. Youn, O. Joe, S. Kam, H. R. Park, J. C. Han, S. Y. Jang, H. K. Kim
Pusan National University, South Korea
M15-19 A Novel MRI Based Attenuation Correction Method for SPECT
B. K. Navalpakkam1, M. Cachovan1, H. H. Quick2, J. Hornegger1, T.
Kuwert3
1
Pattern Recognition Lab, FAU Erlangen-Nuremberg, Germany; 2Institute of
Medical Physics, FAU Erlangen-Nuremberg, Germany; 3Nuclear Medicine
Clinic, University Hospital FAU Erlangen-Nuremberg, Germany
M15-20 Calibration-Based Image Noise Reduction for Energy-Sensitive
Photon Counting X-ray Detectors
D.-G. Kang, S. Kang, Y. Sung
Samsung Advanced Institute of Technology, Republic of Korea
M15-21 The Effect of Non-rigid Mis-registration in Sequential
Quantitative SPECT for Targeted Radionuclide Therapy a Simulation
Study
G. S. P. Mok, E. C. I. Ao, University of Macau, China; N. Song, Yeshiva
University, USA; E. C. Frey, Johns Hopkins University, USA
M15-22 System-Response-Based Flat-Field Correction of Photon
Counting X-Ray Detector
S. Kang, D.-G. Kang, Y. Sung
Samsung Advanced Institute of Technology, Republic of Korea
M15-23 Recursive Bayesian Estimation for Respiratory Motion
Correction in Nuclear Medicine Imaging
R. L. Smith, A. A. A. Rahni, J. Jones, K. Wells
University of Surrey, England, UK
M15-24 Reducing Scanning Time to 50% for 111In-Pentetreotide
SPECT When Using Model-Based Compensation
D. Holmberg1, T. Sundstrom1, K. Riklund1, J. Axelsson1, M. Ljungberg2, A.
Larsson1
1
Umea University, Sweden; 2Lund University, Sweden
Friday - MIC Poster Presentations 227
M15-25 A Method for Scatter Estimation and Correction in Poly-
Energetic X-Ray Cone-Beam Computed Tomography
J.-S. Lee, J.-C. Chen
National Yang-Ming University, Taiwan
M15-26 Evaluation of Whole-Body MR-Based Attenuation Correction
in Bone and Soft Tissue Lesions
I. Bezrukov1,2, F. Mantlik1,2, H. Schmidt1, N. F. Schwenzer1, C. Brendle1, B.
Schoelkopf2, B. J. Pichler1
1
Eberhard Karls University of Tuebingen, Germany; 2Max Planck Institute for
Intelligent Systems, Germany
M15-27 Statistical Decision Making in Emission Tomography Using
Emission-Count Posteriors
A. Sitek1, J. S. Karp2, E. Gualtieri2, S. McQuaid3, M.-A. Park1, M. Foley
Kijewski1, S. C. Moore1
1
Brigham and Women’s Hospital and Harvard Medical School, USA; 2University
of Pennsylvania, USA; 3Royal Surrey County Hospital, England
M15-28 Benefits of 3D Scatter Correction for the HRRT - a Large Axial
FOV PET Scanner
M. Sibomana, Sibomana Consulting, Belgium; S. H. Keller, Rigshospitalet
(Copenhagen University Hospital), Denmark; S. Stute, C. Comtat, CEA,
France
M15-29 Random Correction Method for Positron Emission
Mammography Using Delayed Coincidence Data
L. Cao1, R. Bugalho2, C. Ortigao2, J. Varela2, J. Peter1
1
German Cancer Research Center, Germany; 2Laboratory of Instrumentation and
Experimental Particles Physics, Portugal
M15-30 SinoCor: Inter-Frame and Intra-Frame Motion Correction Tool
D. Mitra, D. Eiland, M. Abdalah, Florida Institute of Technology, USA; R.
Butchko, G. T. Gullberg, Lawrence Berkeley National Lab, USA
M15-31 A Method to Reduce Bias in Iterative Scatter Correction
Estimate for PET
I. Hong, M. Conti, Z. Burbar, Siemens HealthCare, USA
M15-32 CT Data Completion Based on Prior Scans
T. Heußer1, M. Brehm2, S. Sawall2, M. Kachelrieß1
1
German Cancer Research Center (DKFZ), Germany; 2Friedrich-AlexanderUniversity (FAU) Erlangen-Nürnberg, Germany
M15-33 Bone Segmentation of UTE MR Images by Probabilistic Neural
Network for Attenuation Correction in PET/MR
A. Santos Ribeiro1, E. Rota Kops2, H. Herzog2, P. Almeida1,3
1
University of Lisbon, Portugal; 2Research Center Juelich, Germany; 3Institute of
Biophysics and Biomedical Engineering, Portugal
M15-34 Linear Quantification Correction for Myocardial Perfusion
Imaging from X-Ray Coronary Angiography
J. Yao1, T. Sakaguchi2, O. Yousuf3, J. C. Trost3, J. A. C. Lima3, T. Ichihara4,
R. T. George3
1
Toshiba Medical Research Institute USA, Inc., USA; 2Toshiba Medical Systems
Corporation, Japan; 3The Johns Hopkins University, USA; 4Fujita Health
University, Japan
M15-35 Pipeline for Motion Correction in Dual Gated PET
F. Gigengack1,2, L. Ruthotto3, T. Koesters1,2, X. Jiang2, J. Modersitzki3, M.
Burger4, C. H. Wolters5, K. P. Schaefers1
1
European Institute for Molecular Imaging (EIMI), University of Muenster,
Germany; 2Department of Mathematics and Computer Science, University of
Muenster, Germany; 3Institute of Mathematics and Image Computing (MIC),
University of Luebeck,, Germany; 4Institute for Computational and Applied
Mathematics, University of Muenster, Germany; 5Institute for Biomagnetism and
Biosignalanalysis, University of Muenster, Germany
M15-36 List-Mode Reconstruction for the FOCUS-220 with Motion
Correction and Spatially-Variant Probability Density Functions:
Application to Awake Monkey Imaging
X. Jin1, Y. Jian1, T. Mulnix1, C. M. Sandiego1, R. Yao2, R. E. Carson1
1
Yale University, USA; 2University at Buffalo, SUNY, USA
228 Friday - MIC Poster Presentations M15-37 Real-Time Tissue Characterisation During Mammography: the
X-Ray Biopsy Project
Y. Zheng1, A. C. Konstantinidis1, D. Philip2, T. Fearn1, T. Anaxagoras3,4, J. A.
Griffiths1, N. Allinson3, R. D. Speller1
1
University College London, U.K.; 2Queen Mary University of London, U.K.;
3
University College Lincoln, U.K.; 4ISDI Ltd (Image Sensor Design and
Innovation), U.K.
M15-38 A Study of Count-Rate Dependent Normalization Effect in
3D-PET Data
X. Niu, Y. Dong, H. Ye, W. Wang
M15-39 Singles Prompts Randoms: Estimation of Spurious Data Rates
in PET
J. F. Oliver, M. Rafecas
IFIC, CSIC/Universitat de Valencia, Spain
M15-40 Scatter Estimation Scaling to Acquired Data with All Count Use
Based on Discrete Consistency Conditions
V. Y. Panin, Siemens Healthcare, 37932
M15-41 PET Random Reduction with FOV-Dependent Coincidence
Window and Tangential TOF-Mask
W. Wang, X. Niu, H. Ye, D. Gagnon
Toshiba Medical Research Institute USA, USA
M15-42 Collimator Optimization for In-111 SPECT Using Performance
on a Detection/Localization Task
Y. Lu, L. Chen, G. Gindi, Stony Brook University, USA
M15-43 Atlas-Based Segmentation Using Passive Contours
F. Gigengack1,2, L. Ruthotto3, T. Koesters1,2, X. Jiang2, J. Modersitzki3, M.
Burger4, S. Hermann1, K. P. Schaefers1
1
Muenster, Germany; 3Institute of Mathematics and Image Computing (MIC),
University of Luebeck, Germany; 4Institute for Computational and Applied
Mathematics, University of Muenster, Germany
M15-44 Quantification of Myocardial Blood Flow Using Dynamic
Rubidium-82 Imaging on a Low-Cost BGO PET-CT System
R. A. deKemp, R. Klein, J. Renaud, R. S. Beanlands
University of Ottawa Heart Institute, Canada
M15-45 Localization ROC Analysis of the Impact of Respiratory Motion
Correction on Lesion Detection in PET: A Simulation Study Based on
Real MR Dynamic Data
I. Polycarpou, C. Tsoumpas, P. K. Marsden
M15-46 Estimation of Mean Lung Attenuation for Use in Generating
PET Attenuation Maps
S. D. Wollenweber, GE Healthcare, USA; A. H. R. Lonn, GE Healthcare, UK
M15-47 Evaluation of Inertial Measurement Units for Motion Tracking
in Medical Imaging
K. Ziemons, S. Beging, C. Biermanns, M. Lankenau, A. Wachter, FH
Aachen University of Applied Sciences, Germany; R. Fulton, University of
Sydney, Australia
M15-48 Histogram-Based Small-Animal CT Calibration with Evaluation
for Quantitative Micro-SPECT
C. Wu1,2, F. J. Beekman1,3
1
Delft University of Technology, the Netherlands; 2University Medical Center
Utrecht, the Netherlands; 3MILabs B.V., the Netherlands
M15-49 Comparison of 4-Class and Continuous Fat/Tissue Methods for
Whole-Body PET Attenuation Correction Using MR Images
S. D. Wollenweber, S. Ambwani, GE Healthcare, USA; A. H. R. Lonn,
GE Healthcare, UK; R. Mullick, D. D. Shanbhag, S. Thiruvenkadam, S.
Kaushik, GE Global Research, India; H. Qian, GE Global Research, USA; F.
Wiesinger, GE Global Research, DE
M15-50 Partial Volume Compensation for Dynamic Cardiac PET
Imaging: a Monte Carlo Simulation Study
X. Rong, G. S. K. Fung, I. Madar, Y. Du, Johns Hopkins University, USA
M15-51 Region-Specific Motion Estimation in Rodent Using PET and
MRI Image
J. W. Yu1,2, S.-K. Woo1, Y. J. Lee1, I. O. Ko1, R. J. Yoo1, J. H. Kang1, B. I.
Kim1, Y. H. Chung2, S. M. Lim1, K. M. Kim1
1
Korea Institute of Radiological and Medical Science, Korea; 2Yonsei University, Korea
M15-52 Comparison of Three Methods for Combined Correction of
Motion and Attenuation in Positron Emission Tomography
T. Koesters1,2, M. Fieseler1,2, F. Gigengack1,2, K. P. Schaefers1
1
Muenster, Germany
M15-53 Accounting for the Hysteresis of Respiratory Motion of the
Heart in Cardiac SPECT and PET Using the Bouc-Wen Model of
Hysteresis
P. Dasari1,2, A. Konik1, M. S. Shazeeb1, M. A. King1
1
UMASS Medical School, USA; 2Worcester Polytechnic Institute, USA
M15-54 The Effect of Arm Position on Respiratory Motion of the Heart
of the Heart: Implications for Emission Imaging
P. Dasari1,2, K. L. Johnson1, C. Lindsay2, M. A. King1
1
UMASS Medical School, USA; 2Worcester Polytechnic Institute, USA
M15-55 Image Recovery in PET Scanners with Partial Detector Rings
Using Compressive Sensing
S. M. Valiollahzadeh, T. Chang, J. W. Clark, Rice University, USA; O.
Mawlawi, MD Anderson Cancer Center, USA
M15-56 Image-Based Data Corrections for Positron Emission
Mammography
N. C. Ferreira1,2, F. Rodrigues1, L. Martins1,2, C. Ortigao3, F. Caramelo2, L.
Mendes1,2, C. S. Ferreira3,4, P. Almeida4, M. Castelo-Branco1,2, J. Varela3
1
ICNAS, Portugal; 2IBILI / FMUC, Portugal; 3LIP - Lab. de Instrumentacao
e Fisica Experimental de Particulas, Portugal; 4IBEB / FCUL - Instituto de
Biofisica e Engenharia Biomedica, Portugal
M15-57 Performance Assessment of Motion Correction for Different
Distributions and Count Levels
P. J. Markiewicz1,2, J. C. Matthews1, A. J. Reader2
1
University of Manchester, UK; 2McGill University, Canada
M15-58 Phantom-Based Evaluation of Scatter-Compensation
Techniques for Simultaneous Tc-99m/In-111 SPECT-CT Imaging of
Infection
M. Cervo1, M.-A. Park1,2, S. C. Moore1,2
1
Brigham and Women’s Hospital, USA; 2Harvard Medical School, USA
M15-59 Respiratory Motion Correction in PET-MRI
M. Fieseler, T. Koesters, K. P. Schaefers, H. Kugel, X. Jiang
University of Muenster, Germany
M15-60 Tc-99m/Tl-201 Crosstalk Correction on a Dedicated Cardiac
CZT SPECT Camera
S. Chiasson1,2, G. Wells2, T. D. Ruddy2
1
Carleton University, Canada; 2University of Ottawa Heart Institute, Canada
M15-61 Improving Image Quality in Molecular Breast Imaging Using
Backscattered Photons
A. Tao, McMaster University, Canada; T. H. Farncombe, Hamilton Health
Sciences, Canada
M15-62 Study of Spatial Resolution and Temporal Sampling for
Quantitative Rb-82 Cardiac PET Imaging
R. Dai1, C. Levin2, H. Peng1
1
McMaster University, Canada; 2Stanford University, USA
M15-63 Automated Quantitative Assessment of Myocardial Perfusion in
Rodent PET/SPECT Images
S.-K. Woo, Y. J. Lee, K. M. Kim, J. W. Yu, K. C. Lee, M. H. Kim, J.-A.
Park, J. H. Kang, B. I. Kim, S. M. Lim
Korea Institute of Radiological and Medical Science, Korea
230 Friday - MIC Poster Presentations M15-64 Impact of Extraneous Mispositioned Events on Motion-
Corrected Brain SPECT Images of Freely Moving Animals
G. I. Angelis1, W. Ryder1, R. Bashar1, R. Fulton1,2, S. R. Meikle1,2
1
Brain & Mind Research Institute, Australia; 2Faculty of Health Sciences,
Australia
M15-65 Optimisation of K-Edge Subtraction X-Ray Imaging Using a
Pixellated Spectroscopic Detector
S. Pani1, S. C. Saifuddin1, F. I. Ferreira1, J. W. Scuffham1,2, P. Stratmann3, M.
D. Wilson4, M. C. Veale4, S. Bell4, P. Seller4, P. J. Sellin1, R. J. Cernik5
1
University of Surrey, United Kingdom; 2Royal Surrey County Hospital, United
Kingdom; 3RWTH Aachen, Germany; 4Rutherford Appleton Laboratories,
United Kingdom; 5University of Manchester, United Kingdom
M15-66 Generalized Dynamic PET Inter-Frame and Intra-Frame
Motion Correction: Phantom and Human Validation Studies
H. Mohy-ud-Din1, N. A. Karakatsanis1, J. S. Goddard2, J. S. Baba2, W.
Willis1, A. K. Tahari1, D. F. Wong1, A. Rahmim1
1
The Johns Hopkins University, Baltimore, Maryland, USA, USA; 2Oak Ridge
National Laboratory, USA
M15-67 Accelerated Reconstruction for Identifying Image Regions
Affected by Rigid Body Movement
R. K. Barnett1,2,3, R. Fulton1,2,3, S. Meikle1,2
1
Sydney University, Australia; 2Brain & Mind Research Institute, Australia;
3
Westmead Hospital, Australia
M16 POSTER: Emission Tomography
Instrumentation 1 / New Detector Materials
and Technologies for Medical Imaging
Friday, Nov. 2 10:30-12:30 Exhibit Hall North
Session Chairs: Paul K. Marsden, King’s College London, England,
United Kingdom
Bing Bai, University of Southern California, USA
M16-1 Improvements in Image Quality When Using Patient Outline
Constraints with a Generalized Scatter PET Reconstruction Algorithm
H. Sun1,2, S. Pistorius1,2
1
University of Manitoba, Canada; 2CancerCare Manitoba, Canada
M16-2 Development and Initial Performance Measurements of
TransPET Bio-Caliburn SH1.0
Q. Xie1,2, L. Wang1,2,3, J. Zhu1,2,3, Y. Chen1,2, J. Liu1,2, M. Niu1,2, X. Chen2,
Z. Wu2, D. Xi1,2, Z. Hu3, B. Li2, Y. Zheng2,3, P. Xiao1,2
1
Wuhan National Laboratory for Optoelectronics, China; 2Huazhong University
of Science and Technology, China; 3Raycan Technology Co., Ltd (Suzhou), China
M16-3 Analytic Modeling of Software Coincidence Detection in PET
A. Long1,2, P. Xiao1,3, L. Lin1,4, Y. Li1, Q. Xie1,3
1
Huazhong University of Science and Technology, China; 2Jinggangshan
University, China; 3Wuhan National Laboratory for Optoelectronics, China;
4
Raycan Technology Co., Ltd (Suzhou), China
M16-4 Time Multiplexing Using a Static Full-Ring Multi-Pinhole
Collimator for Brain SPECT
K. Van Audenhaege, S. Vandenberghe, B. Vandeghinste, R. Van Holen
Universiteit Gent -IBBT, Belgium
M16-5 The Influence of Time Sampling Scheme on Kinetic Parameters
Obtained from Compartmental Modeling of Dynamic PET - A
Simulation Study
I. Häggström1, A. Larsson1, J. Axelsson1, A. Garpebring1, L. Johansson1, C.
R. Schmidtlein2, J. Sörensen3, M. Karlsson1
1
Umeå University, Sweden; 2Memorial Sloan-Kettering Cancer Center, USA;
3
Uppsala University Hospital, Sweden
M16-6 Methods for Achieving Efficient Bandwidth and Logic
Utilization for Event Transfer and Coincidence Processing in Clinical
PET Systems
A. P. Moor, Siemens Healthcare, USA
M16-7 Three Layer GSO Depth-of-Interaction Detector for High Energy
Gamma Camera
S. Yamamoto1, H. Watabe2, N. Kawachi3, S. Fujimaki3, K. Kato1, J.
Hatazawa2
1
Nagoya University Graduate School of Medicine, Japan; 2Osaka University
Graduate School of Medicine, Japan; 3Japan Atomic Energy Agency, Japan
M16-8 Comparison of Count Rate Sensitivity Performance for a LSOTOF System with a Cherenkov Radiation Based PbF2-TOF System
L. A. Eriksson1,2,3,4, M. Aykac1, C. L. Melcher2, M. Conti1, M. Eriksson3, C.
Michel1
1
Siemens Medical Solutions, Molecular Imaging, USA; 2Scintillation Materials
Research Center, USA; 3Karolinska Institute, Sweden; 4University of Stockholm,
Sweden
M16-9 Optical Encoding and Multiplexing of PET Coincidence Events
A. M. Grant, P. D. Olcott, C. S. Levin, Stanford University, USA
M16-10 A Novel Collimator with CdTe Semiconductor Detector: Monte
Carlo Simulation Studies
Y.-J. Lee, H.-J. Ryu, S.-W. Lee, H.-M. Cho, S.-J. Park, Y.-N. Choi, H.-J.
Kim
Yonsei University, Korea
M16-11 Results on ToF-DOI PET Probe Based on SiPMs.
L. Cosentino1, P. Musico2, F. Garibaldi3, R. Perrino4, F. Cusanno5, R. De
Leo6, P. Finocchiaro1, A. Ranieri6, A. Pappalardo1, F. Loddo6, F. Meddi3
1
lns-infn, Italy; 2INFN Genova, Italy; 3INFN Roma 1 and ISS, Italy; 4INFN
Lecce, Italy; 5Physics, Technische Universitaet Muenchen, Germany; 6INFN Bari,
Italy
M16-12 A Compton Imaging Prototype for in-Vivo Dosimetry at
Therapeutic Proton and Ion Beams
C. Golnik1, U. Dersch1, F. Fiedler2, K. Heidel2, T. Kormoll1, A. Mller1, H.
Rohling1, S. Schne2, M. Sobiella2, W. Enghard1
1
Technical University Dresden, Germany; 2Helmholtz-Zentrum DresdenRossendorf, Germany
M16-13 Evaluation of a New Small-Pixel CdTe Spectroscopic Detector
in Dual-Tracer SPECT Brain Imaging
J. W. Scuffham1,2, M. D. Wilson3, S. Pani2, D. D. Duarte2, M. C. Veale3, S.
Bell3, P. Seller3, P. J. Sellin2, R. Cernik4
1
Royal Surrey County Hospital NHS Foundation Trust, UK; 2University
of Surrey, UK; 3STFC Rutherford Appleton Laboratory, UK; 4University of
Manchester, UK
M16-14 Maximizing Timing Performance of Silicon Photomultiplier
Based Detectors
J. Y. Yeom, R. Vinke, C. S. Levin, Stanford University, USA
M16-15 Impact of the Laser-Processed X’tal Cube Detector with 1 mm
Isotropic Resolution in PET Imaging
E. Yoshida1, Y. Hirano1, H. Tashima1, N. Inadama1, F. Nishikido1, T.
Moriya2, T. Omura2, M. Watanabe2, H. Murayama1, H. Ito1, T. Yamaya1
1
National Institute of Radiological Sciences, Japan; 2Hamamatsu Photonics K.K.,
Japan
M16-16 Development and Performance Evaluation of a Single-Ring
OpenPET Prototype
E. Yoshida1, S. Kinouchi2,1, H. Tashima1, F. Nishikido1, Y. Hirano1, N.
Inadama1, H. Murayama1, H. Ito1, T. Yamaya1
1
National Institute of Radiological Sciences, Japan; 2Chiba University, Japan
M16-17 Development of a MPPC-Based DOI-PET Module with
Submillimeter 3-D Resolution
A. Kishimoto, J. Kataoka, T. Kato, T. Miura, T. Nakamori, Waseda
University, Japan; K. Kamada, Furukawa Co., Ltd., Japan; S. Nakamura,
K. Sato, Y. Ishikawa, K. Yamamura, Hamamatsu Photonics K. K., Japan; S.
Yamamoto, Nagoya University Graduate School of Medecine, Japan
M16-18 Development of a Multi-Pinhole Brain SPECT System with
CdZnTe Semiconductor Detectors
T. Donai, K. Ogawa, Graduate School of Engineering, Hosei University, Japan;
Y. Nyui, M. Fukushi, Graduate School of Health Sciences, Tokyo Metropolitan
University, Japan
232 Friday - MIC Poster Presentations M16-19 A New Method for Collimator Optimization: Application to
Quantitative Y-90 Bremsstrahlung SPECT Imaging
X. Rong, E. Frey, Johns Hopkins University, USA
M16-20 Calibration Method of Monolithic-Crystal Based Detector for
Emission Tomography
S. Espana, K. Deprez, R. Van Holen, S. Vandenberghe
M16-21 Simulation of a Monolithic Scintillator Based PET Detector
K. Saha1, O. Diaz2, S. J. Glick1
1
University of Massachusetts Medical School, USA; 2University of Surrey, UK
M16-22 TOF Measurements in PET Systems Using FPGAs
J. Torres, R. Garcia, J. Soret, J. Martos, Universidad de Valencia, Spain; J. M.
Benlloch, A. J. Gonzalez, P. Conde, CSIC-Universitat Politecnica de Valencia, Spain
M16-23 Evaluation of Very Highly Pixilated Crystal Blocks with SiPM
Readout as Candidates for PET/MR Detectors in a Small Animal PET
Insert
C. J. Thompson1, A. L. Goertzen2, F. Retire3, P. Kozlowski4, L. Ryner5, G.
Stortz4
1
Montreal Neurological Institute, Canada; 2University of Manitoba, Canada;
3
TRIUMF, Canada; 4University of British Columbia, Canada; 5National
Research Council of Canada, Canada
M16-24 Respiratory Motion Correction with Image Based Pseudo
Gating in Positron Emission Tomography
B. K. Park, T. Y. Song, J. Lee, S. Lee
Samsung Electronics, Advanced Institute of Technology, S. Korea
M16-25 High Position Resolution Gamma-Ray Iimagers Consisting
of a Monolithic MPPC Array with Submillimeter Pixelized Scintillator
Crystals
T. Kato, J. Kataoka, T. Nakamori, A. Kishimoto, Waseda University, Japan;
K. Sato, Y. Ishikawa, K. Yamamura, S. Nakamura, N. Kawabata, Hamamatsu
Photonics K. K., Japan; S. Yamamoto, Nagoya University Graduate School of
Medicine, Japan; H. Ikeda, ISAS/JAXA, Japan; K. Kamada, Furukawa Co.,
Ltd., Japan
M16-26 Microscopic SPECT Imaging with Micro-Ring Apertures and
High Resolution Semiconductor Detectors
X. C. Lai, L. J. Meng
University of Illinois at Urbana-Champaign, United States
M16-27 A New Technique to Systematically Minimize Misregistration
Introduced Errors in Cardiac Perfusion Studies with Attenuation
Correction
C. Bai, R. Conwell, Digirad Corporation, USA
M16-28 Performance Tests and Preliminary Results of TraPET Detectors
with DOI Capability
C. Y. Lee1,2, C.-H. Baek1,2, S. J. An1,2, H.-I. Kim1,2, W. J. Jo1,2, Y. H. Chung1,2
1
Radiological Science, South Korea; 2Institute of Health Science, South Korea
M16-29 Time Delay Correction Method for PET-Based Tumor Tracking
T. Shinaji1, H. Tashima2, E. Yoshida2, H. Murayama2, T. Yamaya2, H.
Haneishi1
1
M16-30 A Curve Fitting Approach Using ANN for Converting
CT Number to Linear Attenuation Coefficient for CT-Based PET
Attenuation Correction
C.-L. Lai, J.-S. Lee, J.-C. Chen, National Yang-Ming University, Taiwan
M16-31 COMPET: High-End MRI Compatible PET Scanner
K.-E. Hines1, E. Bolle1, M. Rissi1, J. Bjaalie1, O. Dorholt1, O. Rohne1, S.
Stapnes2, A. Skretting3, D. Volgyes1
1
University Of Oslo, Norway; 2CERN, Switzerland; 3RikshospitaletRadiumhospitalet Medical Center,, Norway
M16-32 Classification of Neurodegenerative Dementia by Gaussian
Mixture Models Applied to SPECT Images
E. Stühler1, G. Platsch2, M. Weih3, J. Kornhuber3, T. Kuwert3, D. Merhof1
1
University of Konstanz, Germany; 2Siemens AG, Germany; 3University of
Erlangen-Nuremberg, Germany
M16-33 Acute Changes in Regional Cerebral 18F-FDG Kinetics in Rat
Brain with Focused Ultrasound Induced Targeted Blood-Brain Barrier
Disruption
W.-Y. Chang, F.-Y. Yang, J.-S. Lee, H.-Y. Tseng, J.-C. Chen
Department of Biomedical Imaging and Radiological Sciences, National YangMing University, Taiwan
M16-34 Design of a Combined Fan and Multi-Pinhole Collimator
Combination for Clinical I-123 DaTscan Imaging on Dual-Headed
SPECT Systems
M. A. King1, G. Zubal2, J. M. Mukherjee1, R. Licho1
1
Univ of Mass Med School, USA; 2Molecular NeuroImaging L.L.C, USA
M16-35 A MPPC Based Tool for Timing and Spatial Resolution
Characterization of PET Detectors
E. J. Berg, A. L. Goertzen, University of Manitoba, Canada
M16-36 Sensitivity Improvement of ToF-PET Detector Through
Recovery of Compton Scattered Annihilation Photons
A. A. Wagadarikar, A. Ivan, S. Dolinsky, GE Global Research, USA; D. L.
McDaniel, GE Healthcare, USA
M16-37 Application of HDMI Cables as a Single Cable Solution for
Readout and Power Supply of SiPM Based PET Detectors
A. L. Goertzen1, X. Zhang1, C.-Y. Liu1, P. Kozlowski2, F. Retiere3, V. Sossi2,
G. Stortz2, C. J. Thompson4
1
3
M16-38 Design of an Optimized Multi-Pinhole Collimator for DualPurpose Clinical and Preclinical Imaging
C. H. Si, G. S. P. Mok, University of Macau, China
M16-39 Dual Isotope Imaging with LaBr3:Ce Scintillation Crystal and
H8500 PSPMT.
A. Fabbri1,2, V. Orsilini Cencelli1,2, P. Bennati3, M. N. Cinti3, R. Pellegrini3,
R. Scafe’3, G. De Vincentis3, R. Pani3, F. de Notaristefani3
1
INFN Istituto Nazionale di Fisica Nucleare, Italy; 2Roma TRE University,
Italy; 3Sapienza University, Italy
M16-40 Improvement of Three-Dimensional Tomographic Imaging
Performance by Opposed-Type Semiconductor Compton Camera System
S. Motomura1, T. Fukuchi1, T. Ida2, M. Hiromura1, H. Haba1, Y. Watanabe1,
S. Enomoto1,2
1
RIKEN CMIS, Japan; 2Okayama University, Japan
M16-41 Sensitivity and Resolution Study of a Small-Field GammaCamera System on a Tomographic Level
A.-N. Rapsomanikis1, M. Zioga1, D. Thanasas1, M. Mikeli1, E. Stiliaris1,2
1
M16-42 Expandable Programmable Integrated Front-End for
Scintillator Based Photodetectors
A. Ros Garcia, R. J. Aliaga, V. Herrero, J. M. Monzo, A. Gonzalez, R. J.
Colom, F. J. Mora, J. M. Benlloch
I3M Universitat Politecnica de Valencia, SPAIN
M16-43 Statistics- Based Position Decoding for a PMT-QuadrantSharing Block Detector
S. Bae1,2, H. Lee1, K. Lee1, H.-I. Kim3, Y. Chung3, J. Joung1,4
1
Korea University, Korea; 2Korea Institute of Radiological & Medical Sciences,
Korea; 3Yonsei University, Korea; 4Nucare Medical Systems, Inc., Korea
M16-44 A Flat Panel Virtual Pinhole PET Insert for Breast Imaging
B. Ravindranath, J. Wen, A. J. Mathews, S. Komarov, J. O’Sullivan, Y.-C.
Tai
Washington University in St. Louis, USA
M16-45 Studies for Performance Improvement of a Small Animal PET
Prototype Based on Continuous LYSO Crystals and SiPM Matrices
J. Barrio1, P. Barrillon2, M. G. Bisogni3,4, J. Cabello1, A. Del Guerra3,4, A.
Etxebeste1, C. Lacasta1, J. F. Oliver1, M. Rafecas1,5, C. Solaz1, V. Stankova1,
C. de La Taille2, G. Llosa1
1
IFIC (UVEG/CSIC), Spain; 2Laboratoire de l’Accelerateur Lineaire, France;
3
University of Pisa, Italy; 4INFN Pisa, Italy; 5Universitat de Valencia, Spain
234 Friday - MIC Poster Presentations M16-46 Design and Evaluation of a New PEM Scanner Based on
Pixelated Solid State CdTe Detectors to Overcome the Intrinsic
Limitations of State-of-the-Art Devices Based on Scintillators
G. De Lorenzo1, I. Ozsahin1, M. Kolstein1, D. Uzun1, K. Mikhaylova1, M.
Canadas2, P. Arce2, G. Arino1, Y. Calderon1, M. Chmeissani1
1
IFAE, Spain; 2CIEMAT, Spain
M16-47 Improved Visualization of Plaque in Cardiac CT Angiography
by Optimal Energy Weighting with Photon Counting Detector: a
Simulation Study
H.-M. Cho, Y.-N. Choi, S.-W. Lee, Y.-J. Lee, H.-J. Ryu, H.-J. Kim
Yonsei university, South Korea
M16-48 Development of a New PET Positron Detector for Intestinal
Cancers
Y. Hasegawa1, H. Kawai1, K. Maruhashi1, K. Mase1, H. Nakayama2, M.
Tabata1,3, M. Wada1,4
1
Graduate School of Science, Chiba University, Japan; 2Kisarazu National
College of Technology, Japan; 3Institute of Space and Astronautical
Science(ISAS), Japan Aerospace Exploration Agency (JAXA)), Japan; 4National
Institute of Radiological Sciences, Japan
M16-49 X-Ray Scintillation Panels and Elements Based on Disperse
ZnSe Scintillator
V. Litichevskyi, S. Galkin, A. Lalaiants
Institute for Scintillation Materials NAS of Ukraine, Ukraine
M16-50 Position Reconstruction in Monolithic Block Detectors
M. Streun, H. Noeldgen, G. Kemmerling, S. van Waasen
Forschungszentrum Juelich, Germany
M16-51 Energy Response of a Room-Temperature Cadmium Telluride
(CdTe) Photon Counting Detector for Simultaneous and Sequential CT
and SPECT
S.-Y. Huang, F. Alhassen, A. M. Hernandez, R. G. Gould, Y. Seo, University
of California, San Francisco, United States; W. C. Barber, J. S. Iwanczyk, N. E.
Hartsough, T. Gandhi, J. C. Wessel, DxRay, Inc., United States
M16-52 Multivariate Analysis on the Electric Currents Measured by a
transXend Detector for Ultra-Low Dose Exposure X-Ray Diagnosis
I. Kanno, H. Shimazaki, R. Imamura, K. Shima, Y. Yamashita, Kyoto
University, Japan; M. Ohtaka, M. Hashimoto, K. Ara, Japan Atomic Energy
Agency, Japan; H. Onabe, Raytech Corporation, Japan
M16-53 Dual Polarity 256-Channel Readout Integrated Circuit for Flat
Panel X-Ray Detector Systems
J. Schlesselmann, S. Petronio, K. Ye, S. Lam
FLIR Commercial Systems Inc., USA
M16-54 Simulation Study of Plasma Display Panel with GMD Structure
for X-Ray Imaging Detector
H. Lee, K. Lee, E. Min, Korea University, Korea; S. Eom, H. Park, J. Kang,
Dankook University, Korea
M16-55 Effect of Gamma Radiation on Potential Ionising Radiation
Detectors and Dosimeters Based on Quantum Dots
D. E. Leslie, P. R. Hobson, D. R. Smith, R. Baharin
Brunel University, UK
M16-56 A New Scintillator Array Module with Depth of Interaction
Resolution
C. Duan, K. Wei, B. Ye
University of Science and Technology of China, China
M16-57 A Dark Current Based Calibration Method for Silicon
Photomultiplier
V. H. Tran, D. L. McDaniel, C. Kim, J. Malaney, B. Peterson
GE HealthCare, USA
M16-58 Basic Properties of X-Ray Radiation Detector Based on Plasma
Display Panel
S. Eom, H. Park, J. Kang, H. Lee, K. Lee
Dankook University, Korea
M16-59 Simulation Study to Optimize the Number of Photo-Detection
Faces and Inter-Crystal Materials for the Xtal Cube PET Detector
T. Matsumoto1, T. Yamaya2, E. Yoshida2, F. Nishikido2, N. Inadama2, H.
Murayama2, M. Suga1
1
M16-60 Development of a Wafer-Scale Large-Area CMOS Active-Pixel
Sensor for Digital Mammography
S. K. Heo, J. P. Kosonen, S. H. Hwang, T. W. Kim, Humanray, Co., Ltd.,
South Korea; S. M. Yun, H. K. Kim, Pusan National University, South Korea
M16-61 Design and Performance of Detector Modules for the
Endoscopic PET Probe for the FP7 Project EndoTOFPET-US
E. Auffray1, F. F. Ben Mimoun Bel Hadj1, K. Doroud1, G. Fornaro1, B.
Frisch1, S. Gundacker1, P. Jarron1,2, P. Lecoq1, T. Meyer1, K. Pauwels1, N.
Brillouet3, P. Coudray3, M. Paganoni4, M. Pizzichemi4
1
CERN, Switzerland; 2INFN Torino, Italy; 3Kloe, France; 4Univerity of Milano
Bicocca, Italy
M16-62 Monolithic Crystals on SiPM Arrays in a Prototype System with
Depth of Interaction Estimation
J. Cabello1, J. E. Gillam1, J. F. Oliver1, J. Barrio1, M. Rafecas1,2, G. Llosa1
1
Instituto de Fisica Corpuscular (IFIC), Universitat de Valencia/CSIC, Spain;
2
M16-63 High Energy Gamma-Ray Imaging Using Cherenkov Cone
Detection a Monte Carlo Study with Application to a Compton Camera
System
T. E. Peterson1, A. B. Brill1, A. H. Walenta1,2
1
Vanderbilt University, USA; 2University of Siegen, Germany
M16-64 Evaluation of a Novel Wafer-Scale CMOS APS X-Ray Detector
for Use in Mammography
A. C. Konstantinidis1, Y. Zheng1, A. Olivo1, K. Bliznakova2, T. Anaxagoras3,4,
N. M. Allinson3, R. D. Speller1
1
University College London, U.K.; 2University of Patras, Greece; 3University of
Lincoln, U.K.; 4ISDI Ltd (Image Sensor Design and Innovation), U.K.
M16-65 Test of a Compton Telescope Prototype Based on Continuous
LaBr3 Crystals and Silicon Photomultipliers
M. Trovato1, J. Barrio1, J. Cabello1, S. Callier2, J. Gillam1, C. De La Taille2,
C. Lacasta1, M. Rafecas1,3, C. Solaz1, V. Stankova1, I. Torres-Espallardo1, L.
Raux2, G. Llosa’1
1
Istituto de fisica curpuscular IFIC - Universitat de Valencia/CSIC, Spain;
2
Laboratoire de l’Accelerateur Lineaire, France; 3Universitat de Valencia, Spain
M16-66 Developing a Compton Spectrometer for Determination of
X-Ray Tube Spectra
N. Reims, F. Sukowski, K. Killicarslan
Fraunhofer IIS, Germany
M16-67 Event Processing for Modular Gamma Cameras with Tiled
Multi-Anode Photomultiplier Tubes
E. Salcin, L. R. Furenlid, University of Arizona, USA
M16-68 Novel Method of Silicone Photo-Multipliers’ Temperature
Control and Stabilization
A. V. Stolin, S. Majewski, R. R. Raylman, West Virginia University, USA
M16-69 The Fabricaton of the Flexible Scintillator for the Medical
Imaging System
J. S. Kim1, K. M. Oh1, J. N. Kim1, J. Y. Lee1, G. S. Cho1, J. K. Park2, S. H.
Nam1
1
Inje university, South Korea; 2International university of Korea, South Korea
M16-70 Influence of Misalignment of a Scintillator Array and a MultiAnode PMT for 4-Layer DOI PET Detector
M. Nitta1,2, N. Inadama2, F. Nishikido2, Y. Hirano2, E. Yoshida2, H.
Tashima2, H. Kawai1,2, H. Ito2, T. Yamaya2
1
M16-71 Development of a Four-Layer DOI Detector Composed of ZrDoped GSO Scintillators and a High Sensitive Multi-Anode PMT
M. Nitta1,2, Y. Hirano2, N. Inadama2, F. Nishikido2, E. Yoshida2, H.
Tashima2, H. Kawai1,2, H. Ito2, T. Yamaya2
1
236 Friday - MIC Poster Presentations M16-72 Studies of a Multi-Channel TOF-PET Brain Imager Prototype
with the SiPM-Based Readout
P. Murat, E. Ramberg, A. Ronzhin, L. Sergey, Fermilab, USA; C.-M. Kao,
C.-T. Chen, H. Kim, University of Chicago, USA; S. Majewski, West Virginia
University, USA
M16-73 Feasibility Study of Using Cherenkov Light for Time-of-Flight
PET Systems
N. Vurgun, H. Peng, McMaster University, Canada
M16-74 Investigation of Cesium Zinc Telluride Based System as a Room
Temperature Planar Imager for Plant
B. A. Bale, L. Scheel, J. S. Baba, Oak Ridge National Labs, United States
M17 POSTER: Image Reconstruction Methods 2 /
Intra-Operative Probes and Portable Imaging
Systems
Session Chairs: Suleman Surti, University of Pennsylvania, USA
Johan L. Nuyts, KU Leuven, Belgium
M17-1 Fast Variance Computation for Quadratically Penalized Iterative
Reconstruction of 3D Axial CT Images
S. M. Schmitt, J. A. Fessler, University of Michigan, USA
M17-2 Comparisons Motion Correction Methods for PET Studies
I. Hong, Z. Burbar, C. Michel, Siemens HealthCare, USA
M17-3 Fast Variance Image Predictions for Motion-Compensated Image
Reconstruction
S. Y. Chun, J. A. Fessler, University of Michigan, USA
M17-4 Fast and Accurate Rotator for Rotation-Based Iterative
Reconstruction Algorithms
K. Kacperski, J. Pietrzak
The Maria Sklodowska - Curie Memorial Cancer Centre and Institute of
Oncology, Poland
M17-5 Simulated One Pass Listmode for Fully 3D Image Reconstruction
of Compton Camera Data
J. E. Gillam1, J. F. Oliver1, I. Torres-Espallardo1, C. Lacasta1, G. Llosa1, M.
Trovato1, J. Barrio1, J. Cabello1, V. Stankova1, C. Solaz1, M. Rafecas1,2
1
Instituto de Fsica Corpuscular (IFIC) Universitat de Valencia/CSIC, Spain;
2
M17-6 Joint Segmentation and Quantification of Oncological Lesions in
PET/CT: Preliminary Validation on a Zeolite Phantom
E. De Bernardi1,2,3, C. Soffientini3, F. Zito4, G. Baselli3
1
University of Milano-Bicocca, Italy; 2Tecnomed Foundation, Italy; 3Politecnico
di Milano, Italy; 4Fondazione Ca Granda Ospedale Maggiore Policlinico, Italy
M17-7 Regularization of 3D Iterative Reconstruction for a LimitedAngle PET Tomograph
E. Vicente1,2, J. L. Herraiz3, J. Seidel4,5, M. V. Green4,5, M. Desco6,7, J. J.
Vaquero7, J. M. Udias1
1
Universidad Complutense Madrid, Spain; 2Consejo Superior de Investigaciones
Cientificas (CSIC), Spain; 3Massachusetts Inst. of Technology (MIT), USA;
4
SAIC-Frederick Inc. (Consultant), USA; 5National Cancer Institute, National
Institutes of Health, USA; 6Hospital General Universitario Gregorio Maranon,
Spain; 7Universidad Carlos III de Madrid, Spain
M17-8 GPU-Accelerated Forward and Backward Projection with
Spatially Varying Kernels in 3D DIRECT TOF PET Reconstruction
S. Ha1, S. Matej2, M. Ispiryan2, K. Mueller1
1
Stony Brook University, USA; 2University of Pennsylvania, USA
M17-9 Improved List-Mode Reconstruction with Area-SimulatingVolume Projector in 3D PET
H. Ye, X. Niu, W. Wang
M17-10 SR-POSEM: a New Algorithm for Improved Accelerated Image
Reconstruction of SPECT Data
P. E. B. Vaissier, M. C. Goorden, F. J. Beekman
TU Delft, The Netherlands
M17-11 Use of Anatomical Information in a Bayesian Reconstruction
with an Edge-Preserving Median Prior
H.-M. Huang1, I.-T. Hsiao1,2
1
Chang Gung University, Taiwan; 2Chang Gung Memorial Hospital, Taiwan
M17-12 Tomographic Image Reconstruction Based on Artificial Neural
Network (ANN) Techniques
M. Argyrou1, D. Maintas2, C. Tsoumpas3, E. Stiliaris1
1
National & Kapodistrian University of Athens, Greece; 2Medical Center of
Athens, Greece; 3King’s College, UK
M17-13 A Comparison Study on KL Domain Penalized Weighted LeastSquares Approach for Low-Dose Cone-Beam CT Imaging
H. Zhang1, Y. Liu1, H. Han1, Y. Fan1, J. Wang2, Z. Liang1
1
Stony Brook University, USA; 2University of Texas Southwestern Medical
Center, USA
M17-14 Projector with Realistic Detector Scatter Modelling for PET
List-Mode Reconstruction
A. Autret1, J. Bert1, O. Strauss2, D. Visvikis1
1
LaTIM, France; 2LIRMM, France
M17-15 pCT Reconstruction with an Algebraic Method
G. A. P. Cirrone1, M. Bruzzi2,3, M. Bucciolini2,3, C. Civinini2, G. Cuttone1,
D. Lo Presti4,5, M. Favetta1, S. Pallotta2,3, C. Pugliatti4,5, N. Randazzo4,5, F.
Romano1,6, M. Scaringella2,3, V. Sipala7, C. Stancampiano4,5, C. Talamonti2,3,
M. Zani2,3
1
Laboratori Nazionali del Sud-INFN, Italy; 2INFN - Sez. FI, Italy; 3Universita’
degli Studi di Firenze, Italy; 4Universita’ degli Studi di Catania, Italy; 5INFN
- Sez. CT, Italy; 6Museo Storico della Fisica e Centro Studi e Ricerche, Italy;
7
Universita’ degli Studi di Sassari, Italy
M17-16 Accelerated Monte Carlo Based Simultaneous I-123/Tc-99m
SPECT Reconstruction
M. I. Karamat1, T. H. Farncombe1,2
1
McMaster University, Canada; 2Hamilton Health Sciences, Canada
M17-17 Investigation of Different Compressed Sensing Approaches for
Respiratory Gating in Small Animal CT
J. F. Abascal1, A. Sisniega1, C. Chavarrias2, J. J. Vaquero1, M. Desco2, M.
Abella1
1
Universidad Carlos III de Madrid, Spain; 2Hospital GU Gregorio Maranon,
CIBERSAM, Spain
M17-18 Total Variation Based Image Restoration Algorithm for
Reducing Radiation Doses in the 4D- Digital Tomosynthesis
Y. Jian
Department of Electrical and Computer Engineering, Duke University, USA
M17-19 A Sinogram Resolution Modelling Adapted to the Geometry of
the HRRT
L. Mendes1,2, C. Comtat3, N. C. Ferreira1,2
1
Instituto de Ciencias Nucleares Aplicadas a Saude, Portugal; 2Instituto
Biomedico de Investigacao de Luz e Imagem, Portugal; 3Commissariat a l’Energie
Atomique et aux Energies Alternatives, France
M17-20 Total Variation-Regularized Image Reconstruction of
Decomposed K-Edge Data in Spectral CT
Q. Xu, Washington University in St. Louis, USA; E. Roessl, R. Proksa, Philips
Techologie GmbH, Germany; C. Schirra, Philips Research North America, USA
M17-21 CT Image Reconstruction Design by Investigation of the
Propagation of Hotelling SNR
A. A. Sanchez, E. Y. Sidky, X. Pan
University of Chicago, USA
M17-22 A Preliminary Investigation of Image Reconstruction with
Variable Resolution in Diagnostic CT
Z. Zhang1, J. Bian1, X. Han1, D. Shi2, A. Zamyatin2, E. Y. Sidky1, X. Pan1
1
University of Chicago, United States; 2Toshiba Medical Research Institute,
United States
238 Friday - MIC Poster Presentations M17-23 Constrained TV-Minimization Image Reconstruction from
Sparse-View Diagnostic CT Data
Z. Zhang1, X. Han1, J. Bian1, D. Shi2, A. Zamyatin2, P. Rogalla3, E. Sidky1,
X. Pan1
1
University of Chicago, United States; 2Toshiba Medical Research Institute,
United States; 3UHN Toronto General Hospital, Canada
M17-24 Non-Local Means Methods Using CT Side Information for
I-131 SPECT Image Reconstruction
S. Y. Chun, J. A. Fessler, Y. K. Dewaraja
M17-25 GPU-Enabled PET Motion Compensation Using Sparse and
Low-Rank Decomposition
J. Cui, C. S. Levin, Stanford University, USA
M17-26 Influence Increasing LOR Angle Has on Parallel Flat Detector
High-Resolution PET Images
W. Luo, Naviscan Inc., USA; M. Dahlbom, UCLA, USA; L. MacDonald,
M17-27 Automatic Parameter Selection in PET Image Reconstruction
Based on No-Reference Image Quality Assessment
J. L. Herraiz, Madrid-MIT Consortium, United States; S. Gabarda, G.
Cristobal, Consejo Superior de Investigaciones Cientificas (CSIC), Spain
M17-28 Quantitative Evaluation of a New Image Reconstruction
Approach for Gated Cardiac SPECT Images
H. Babla, C. Bai, R. Conwell, Digirad Corporation, USA
M17-29 An Ordered-Subsets Proximal Preconditioned Gradient
Algorithm for Total Variation Regularized PET Image Reconstruction
A. Mehranian1, A. Rahmim2, M. R. Ay3, H. Zaidi1
1
Geneva University Hospital, Switzerland; 2Johns Hopkins University, USA;
3
Tehran University of Medical Sciences, Iran
M17-30 System Matrix for a Small Animal PET Scanner Based on Point
Source Measurements, Monte Carlo Simulations and on an Analytical
Detector Response Function Model - A Comparison Study
M. Hohberg1,2, F. R. Schneider2, T. Kuestner3, I. Torres-Espallardo4, S. I.
Ziegler2
1
University of Pisa, Italy; 2Klinikum rechts der Isar der Technischen Universitaet
Muenchen, Germany; 3Technische Universitaet Muenchen, Germany; 4University
of Valencia, Spain
M17-31 Direct Parametric Reconstruction for Dynamic [18F]FDG PET/
CT Imaging in the Body
F. A. Kotasidis1,2, J. C. Matthews2, A. J. Reader3, G. I. Angelis4, P. M. Price5,
H. Zaidi1
1
3
McGill University, Canada; 4University of Sydney, Australia; 5Imperial college,
United Kingdom
M17-32 Effects of Statistical Inference on Diffusion Signal
Reconstruction
B. P. Neuman, C. Tench, University of Nottingham, UK; L. Bai, ,
M17-33 Edge Artifact Reduction Methods for Iterative PET
Reconstruction
J. P. Haldar, Y. Lin, B. Bai, R. M. Leahy
University of Southern California, USA
M17-34 Characterizing a Discrete-to-Discrete X-Ray Transform for
Iterative Image Reconstruction with Limited Angular-Range Scanning
in CT
E. Y. Sidky1, J. H. Joergensen2, X. Pan1
1
University of Chicago, USA; 2Technical University of Denmark, Denmark
M17-35 High Performance Multi-GPU Acceleration for Fully 3D ListMode PET Reconstruction
Z. Bahi, J. Bert, A. Autret, D. Visvikis, LaTIM, France
M17-36 Convergence of Iterative Image Reconstruction Algorithms for
Digital Breast Tomosynthesis
E. Y. Sidky1, J. H. Joergensen2, X. Pan1
1
University of Chicago, USA; 2Technical University of Denmark, Denmark
M17-37 Joint Estimation of the Activity and the Events of Interaction in
SPECT Systems
S. Pedemonte1, S. Arridge1, B. Hutton2, S. Ourselin1
1
Centre for Medical Image Computing, United Kingdom; 2Institute of Nuclear
Medicine, University College London Hospitals NHS Trust, United Kingdom
M17-38 Patient Specific Method to Determine Maximum a Posteriori
Reconstruction Hyperparameters for Myocardial SPECT
X. Li, M. Ghaly, L. Cheng, E. C. Frey
M17-39 Impact of the Forward Projection Model in Reconstruction of
Small-Animal SPECT Data Acquired with a Space-Variable-Focusing
Collimator
D. Benoit1, J. Bonte1, M. Leabad2, S. Maitrejean2, F. Mathy3, G.
Montemont3, I. Buvat1
1
QIM IMNC-IN2P3/CNRS, FRANCE; 2Biospace Lab, FRANCE; 3CEALETI, FRANCE
M17-40 LOR-Interleaving Image Reconstruction for PET with
Collimation
Y. Li, S. Matej, J. S. Karp, S. D. Metzler
M17-41 Development and Assessment of Statistical Iterative Image
Reconstruction for CT on a Small Animal SPECT/CT Dual-Modality
System
T. Dai1,2, X. Deng3, C. N. Ionita3, Q. Wei1,2, T. Ma1,2, Y. Liu1,2, D. R.
Bednarek3, S. Rudin3, R. Yao3
1
Tsinghua University, China; 2Ministry of Education, China; 3State University
of New York at Buffalo, USA
M17-42 Total Variation Minimization for in-Beam PET Image
Reconstruction
S. Kinouchi1,2, T. Yamaya2, H. Tashima2, E. Yoshida2, H. Ito2, M. Suga1
1
M17-43 Development of GPU Based Image Reconstruction Method for
Clinial SPECT
H. Liu1, J. Chen2, T. Y. Ma1, S. Chen1, Y. Q. Liu1, S. Wang1, Y. J. Jin1
1
Tsinghua University, China; 2National Institute of Metrology, China
M17-44 Effective Anatomical Priors for Emission Tomographic
Reconstruction
Y.-J. Tsai1, C.-Y. Chou2, I.-T. Hsiao1,3
1
Chang Gung University, Taiwan; 2National Taiwan University, Taiwan;
3
Chang Gung Memorial Hospital, Taiwan
M17-45 Fast Cone-Beam-Based LOR Reconstruction for 3D PET
I. J. Ahn, K. Y. Jeong, W. H. Nam, J. H. Kim, J. B. Ra
M17-46 A Non-Local Means Regularized Iterative Reconstruction
Method for Low-Dose Dental CBCT
J. Hao1,2, L. Zhang1,2, L. Li1,2, K. Kang1,2
1
(Tsinghua University), China
M17-47 Metal Artifact Reduction Algorithm for Single Energy and Dual
Energy CT Scans
A. A. Zamyatin, D. Xu
Toshiba Medical Research Institute USA, United States
M17-48 Dynamic 3D PET Reconstruction for Kinetic Analysis Using
Patch-Based Low-Rank and Sparsity Penalties
K. S. Kim, J. C. Ye
Korea Advanced Institute of Science and Technology (KAIST), South Korea
M17-49 Full Field Spatially-Variant Image-Based Resolution Modelling
Reconstruction for the HRRT
G. I. Angelis1,2, F. A. Kotasidis2,3, J. C. Matthews2, P. J. Markiewicz2, W. R.
Lionheart4, A. J. Reader5
1
Brain & Mind Research Institute, Australia; 2School of Cancer and Enabling
Sciences, MAHSC, UK; 3Division of Nuclear Medicine and Molecular Imaging,
Switzerland; 4School of Mathematics, UK; 5Montreal Neurological Institute,
Canada
240 Friday - MIC Poster Presentations M17-50 Image Reconstruction and Signal Detectability in Dual-Head
Small-Animal PET
Y.-J. Kao1, C.-H. Kao1, Y. Dong2, C.-M. Kao3, C.-T. Chen3, W. Wang1,
C.-Y. Chou1
1
National Taiwan University, Taiwan; 2Illinois Institute of Technology, USA;
3
The University of Chicago, USA
M17-51 Time-of-Flight Image Reconstruction with TV Minimization
Constraint for a Dual-Head Small-Animal PET System
H.-Y. Chou1, C.-Y. Tsai1, C.-M. Kao2, C.-T. Chen2, C.-Y. Chou1
1
National Taiwan University, Taiwan; 2The University of Chicago, USA
M17-52 Reliable Assessment of Statistical Variability for Image Quality
Studies Employing Channelized Hotelling Observers
A. Wunderlich, F. Noo, M. Heilbrun, University of Utah, USA
M17-53 Shift-Invariant Cone-Beam Reconstruction Outside R-Lines
with a Disconnected Source Trajectory
Z. Yu1,2, F. Noo1, G. Lauritsch3, A. Maier3, F. Dennerlein3, J. Hornegger2
1
University of Utah, U.S.A; 2Friedrich-Alexander-University ErlangenNuremberg, Germany; 3Siemens AG, Germany
M17-54 Image Representation Using Mollified Pixels for Iterative
Reconstruction in X-Ray CT
F. Noo1, K. Schmitt1,2,3, K. Stierstorfer3, H. Schoendube3
1
University of Utah, USA; 2University of Erlangen-Nuremberg, Germany;
3
Siemens AG, Healthcare Sector, Germany
M17-55 GPU-Accelerated Sensitivity Matrix Calculation for Motion
Compensated List-Mode PET Reconstruction
R. Bashar1, W. Ryder1, G. I. Angelis1, A. Kyme1, S. R. Meikle1,2, R. Fulton1,2
1
Brain & Mind Research Institute, Australia; 2Faculty of Health Sciences,
Australia
M17-56 Iterative Reconstruction Using a Pyramid-Shaped Basis
Function
K. Schmitt1,2,3, F. Noo1, J. Hornegger2, K. Stierstorfer3, H. Schoendube3
1
University of Utah, Dept of Radiology, USA; 2University of ErlangenNuremberg, Germany; 3Siemens AG, Healthcare Sector, Germany
M17-57 Impact of Truncation to the Reconstruction with a Small
Number of Projections
Y. Mao, G. L. Zeng, University of Utah, USA
M17-58 A Comparison of Data-Driven Methods for Patient Motion
Estimation in Cardiac SPECT Imaging
J. M. Mukherjee1, J. Dey1, A. Konik1, B. F. Hutton2, M. A. King1
1
University of Massachusetts, United States; 2University College London, UK
M17-59 PET Image Reconstruction Based on Several Respiratory-Phase
Low-Dose CT Images
W. H. Nam1, I. J. Ahn1, K. Y. Jeong1, J. H. Kim1, K. M. Kim2, B. I. Kim2,
J. B. Ra1
1
KAIST, Republic of Korea; 2Korea Institute of Radiological and Medical
Sciences, Republic of Korea
M17-60 Determination of the Arterial Input Function in Mice Using a
Beta Microprobe System
F. Buether, D. Reinhardt, M. P. Law, K. P. Schaefers
European Institute for Molecular Imaging, Germany
M17-61 Development of Intraoperative Beta Probes Based on Silicon
Photomultipliers
N. Hudin1, L. Pinot1, Y. Charon1, N. Dinu2, B. Janvier1, T. Ait Imando2, D.
Benoit1, M.-A. Duval1, V. Puill2, L. Menard1
1
Laboratoire IMNC, France; 2Laboratoire de lAcclrateur Linaire, France
M17-62 Molecular Breast Imaging Guided Biopsy
J. W. Hugg, R. Keen, D. Beylin, E. Anashkin, R. Moore, B. Patt
Gamma Medica, USA
M17-63 A Pilot Ambi-Cranial PET System for GBM Surgery Guidance:
Characterization and Analysis
D. Ruan, M. Dahlbom, K. Iwwamoto, UCLA Medical School, USA
M18 POSTER: Emission Tomography
Instrumentation 2/ Other Medical Imaging
Technologies
Session Chairs: Roger Lecomte, Université de Sherbrooke, Canada
Timothy G. Turkington, Duke University Medical
Center, USA
M18-1 Development of a Geometry-Configurable and Environment-
Controllable PET System for Functional Plant Imaging
Q. Wang1, H. Wu1, J. Wen1, D. Hu2, A. Mathews1, B. Ravindranath1, S.
Komarov1, S. Siegel2, J. A. O’Sullivan1, Y.-C. Tai1
1
Washington University in St. Louis, USA; 2Siemens Molecular Imaging, USA
M18-2 Gradient Transparent RF Housing for Simultaneous PET/MRI
Using Carbon Fiber Composites
P. M. Dueppenbecker1,2, S. Lodomez1, W. Renz3, D. Truhn4, P. Marsden2, V.
Schulz1,3
1
Philips Research, DE; 2King’s College London, UK; 3RWTH Aachen University,
DE; 4Irmato Industrial Solutions, DE
M18-3 Development of an MRI Compatible dSiPM-Based PET
Detector Stack for Simultaneous Preclinical PET/MRI
P. M. Dueppenbecker1,2, B. Weissler1, P. Gebhard1,2, D. Schug3, P. Marsden2,
V. Schulz1,3
1
Philips Research, DE; 2King’s College London, UK; 3RWTH Aachen University,
DE
M18-4 Depth of Interaction Detection on Pixelated PET Detector
D. Hu, S. B. Siegel, Siemens MI, USA
M18-5 Monte Carlo Simulation of a Dental Positron Emission
Tomograph and Image Reconstruction of Scatter and True Coincidence
Events
I. Valastyan1,2, M. Colarieti-Tosti1, W. Ren1, A. Turco1
1
Royal Institute of Technology, Sweden; 2Institute of Nuclear Research of the
Hungarian Academy of Sciences, Hungary
M18-6 FPGA-Based Acquisition System for Clinical PET Scanner
O. Ivanov, G. Mann, K. Burr, W. Wang, D. Gagnon, B. Roberts, C. Rollet
Toshiba Medical Research Institute USA, United States
M18-7 An Algorithm for Automatic Flood Histogram Segmentation for
a PET Detector
H. Du, K. Burr
M18-8 Design and Characterisation of a Detector for Imaging I-125
Emissions from Freely Moving Mice
D. A. Prokopovich1, D. Boardman1, A. Z. Kyme2, G. Angelis2, F. Boisson1,
M. I. Reinhard1, S. R. Meikle2
1
Australian Nuclear Science and Technology Organisation, Australia; 2University
of Sydney, Australia
M18-9 Calibration Methodology for a Dual-Ended Readout Silicon
Photomultiplier Based Depth-of-Interaction PET Detector Module
W. Xi, J. McKisson, A. G. Weisenberger, S. Lee, M. Taylor, A. Stepanyan,
C. Zorn
Thomas Jefferson National Accelerator Facility, USA
M18-10 Combined Analog/Digital Approach to Performance
Optimization for the LaPET Whole-Body TOF PET Scanner
B. Ashmanskas, Z. S. Davidson, B. C. LeGeyt, F. M. Newcomer, J. V.
Panetta, W. A. Ryan, R. Van Berg, R. I. Wiener, J. S. Karp
M18-11 Performance Evaluation of a Single-Ring Time-of-Flight PET
Camera
Q. Peng, W.-S. Choong, V. Chinh, J. Huber, M. Janecek, D. Wilson, R.
Huesman, W. Moses
242 Friday - MIC Poster Presentations M18-12 System Characterization of a CZT Detector Based MR
Compatible Small Animal SPECT System
A. J. Rittenbach1, J. Xu1, K. Parnham2, J. W. Hugg2, B. M. W. Tsui1
1
Johns Hopkins University, USA; 2Gamma Medica, Inc, USA
M18-13 Anger Positioning Algorithm with Position Decoder Circuit:
Hybrid Readout Circuit for PET Consisting of GAPD Arrays
S. Lee, Y. Choi, J. Kang, J. H. Jung
Sogang University, Korea
M18-14 A Position Decoder Circuit for PET Detector with Different
Physical Properties
J. Jung, Y. Choi, J. H. Jung, S. Kim
Sogang University, Korea
M18-15 Simple Method to Stabilize the Temperature Dependent
Performance of PET Detector Using GAPD
Y. Huh1,2, Y. Choi1, J. H. Jung1, J. W. Jung1, K. B. Kim1, H. B. Shin1, B. T.
Kim2
1
Sogang University, Korea; 2SungkyunKwan University, Korea
M18-16 A Cost-Effective Modular Programmable HV Distribution
System for Photodetectors
F. W. Lau, J.-Y. Yeom, A. Vandenbroucke, P. D. Reynolds, D. R. Innes, C. S.
Levin, Stanford University, USA
M18-17 A Dynamic Single Photon Emission Computed Tomography
Myocardial Perfusion Imaging Protocol Using a 4D Spatiotemporal
Iterative Reconstruction
F. Alhassen1, U. Shrestha1, R. G. Gould1, E. Botvinick1, Y. Seo1, G. T.
Gullberg1,2
1
University of California, San Francisco, USA; 2Lawrence Berkeley National
Laboratory, USA
M18-18 A Cost-Effective High-Resolution Modular Pixelated Clinical
SPECT Detector Based on Small NaI (Tl) Pixels with Medium-Size
Single-Anode PMTs, Utilizing Spatial Modulation of Scintillation Light
Output
M. Rozler, W. Chang, Rush University Medical Center, IL
M18-19 A Variable-Pitch Slat Stack for Task-Specific Slit-Slat
Collimation
M. Rozler, W. Chang, Rush University Medical Center, IL
M18-20 Fundamental Performance of a New Planer PEM
S. Ito, H. Sato, U. Yoshiyuki, FURUKAWA CO.,LTD., Japan; M. Miyake, K.
Kumagai, M. Baba, M. Ito, Tohoku University, Japan; S. Yamamoto, Nagoya
University, Japan
M18-21 Angular Viewing Time Optimization for Slit-Slat SPECT
X. Zheng, S. D. Metzler, University of Pennsylvania, USA
M18-22 Efficient System Modeling for Tapered PET Scanner
M. Zhang1, J. Zhou1, M. Rodrguez-Villafuerte1,2, Y. Yang1, J. Qi1
1
Department of Biomedical Engineer, UC davis., US; 2Instituto de Fsica,
Universidad Nacional Autnoma de Mxico, Mexico
M18-23 Assessing the Performance of C-SPECT Cardiac Tomographer
Using GATE-Based Simulations
J. Strologas, Rush University Medical Center, USA
M18-24 First Results from the BNL Plant Imaging System
M. Budassi1, S. Stoll2, M. L. Purschke2, B. Ravindranath3, J. Fried2, T. Cao1,
J.-F. Pratte4, P. O’Connor2, C. L. Woody2, P. Vaska2, D. J. Schlyer2
1
Stony Brook University, USA; 2Brookhaven National Laboratory, USA;
3
Washington University in St. Louis, USA; 4University of Sherbrooke, Canada
M18-25 Time-of-Flight PET-MR Detector Development Based on
Silicon Photomultiplier
C. L. Kim, A. Ganin, D. L. McDaniel, J. Malaney, G. McBroom, GE
Healthcare, USA; J. Guo, W. Ashwin, A. Ivan, GE Global Research, USA
M18-26 Evaluation and Development for Positron Emission
Mammography Based on Pr:LuAG Scintillator Crystals
H. Sato, S. Ito, Y. Usuki, Furukawa Co., Ltd., Japan; M. Miyake, K.
Kumagai, M. Baba, M. Ito, Tohoku University, Japan; S. Yamamoto, Nagoya
University Graduate School of Medicine, Japan
M18-27 Brain SPECT with Multipinhole Collimators
J. D. Bowen1, Q. Huang2, G. T. Gullberg3, Y. Seo1
1
University of California, San Francisco, United States; 2Shanghai Jiao Tong
University, China; 3Lawrence Berkeley National Laboratory, United States
M18-28 Development of a New Brain PET Scanner Based on Single
Event Data Acquisition
T. Isobe, R. Yamada, K. Shimizu, K. Ote, K. Sakai, T. Moriya, H. Yamauchi,
A. Saito, T. Omura, M. Watanabe, Hamamatsu Photonics K.K., Japan
M18-29 A New Depth of Interaction PET Detector with Monolithic
Plane Scintillator Stack
Y. Hirano, N. Inadama, E. Yoshida, F. Nishikido, H. Tashim, H. Ito, T.
Yamaya
M18-30 Performance Evaluation of Continuous Depth-of-Interaction
Encoding PET Detector Using Different Reflector Designs
M. S. Lee, M. Ito, J. S. Lee
Seoul National University College of Medicine, Korea
M18-31 Timing Analysis of the Xtal Cube PET Detector Based on SixSurface Readout Using 96 MPPCs
F. Nishikido, Y. Hirano, E. Yoshida, N. Inadama, H. Murayama, H. Ito, T.
Yamaya
M18-32 Measure PET Detector Performance with the Intrinsic
Radioactivity of Scintillator
Q. Wei1, T. Ma1, S. Wang1, R. Yao2, Y. Liu1
1
Tsinghua University, China; 2State University of New York at Buffalo, USA
M18-33 Evaluation of Centrally Located Sources in Coincidence Timing
Calibration for Time-of-Flight PET
R. R. Wargo, L. J. Rankine, J. M. Wilson, T. G. Turkington
Duke University Medical Center, USA
M18-34 Investigation of Four Phantoms for PET Normalization
L. J. Rankine, J. M. Wilson, T. G. Turkington
Duke University Medical Center, USA
M18-35 Quantitative Comparison of PET Scanners by Multiple
Manufacturers Using Patient-Sized Phantoms
J. M. Wilson, J. E. Bowsher, T. G. Turkington
Duke University, USA
M18-36 Zoom and Wobble PET (II) : Realization of a Prototype System
of Sensitivity and Resolution Maximized Brain-Body PET
Y. D. Son, Z. H. Cho, B. K. Kang, H. K. Kim, D. H. Kwon, Y. H. Joo, Y.
B. Kim
Neuroscience Research Institute, Gachon University, Republic of Korea
M18-37 Wobbling-Based Maximum Likelihood Expectation Maximize
Reconstruction for the Wobbling PET
H. K. Kim, Y. D. Son, P. H. Lee, Y. B. Kim, Z. H. Cho
Gachon University, South Korea
M18-38 Imaging Capability of Small Animal PET Using Siemens
Biograph True Point True V Scanner
Y. S. Lee1,2, J. S. Kim1, H.-J. Kim2, J. H. Kang1, S. M. Lim1, K. M. Kim1
1
Korea institute of radiological and medical science, KIRAMS, Republic of Korea;
2
M18-39 The Quality Field of View of a Discovery 530c
J. N. Aarsvold1,2, J. R. Galt2, J. A. Nye2, F. D. Grammens3, Z. A. Glass3
1
Atlanta Veterans Affairs Medical Center & Emory University, USA; 2Emory
University School of Medicine, USA; 3Georgia Institute of Technology, USA
M18-40 Highly-Integrated CMOS Interface Circuits for SiPM-Based
PET Imaging Systems
S. Dey, T. K. Lewellen, R. S. Miyaoka, J. C. Rudell
M18-41 Development of a High Resolution Four Layer DOI Detector
Using MPPCs for Brain PET
T. Omura, T. Moriya, R. Yamada, H. Yamauchi, T. Sakai, T. Miwa, M.
Watanabe, Hamamatsu Photonics K.K., Japan
244 Friday - MIC Poster Presentations M18-42 Estimation of Sinogram Blurring Matrix for Inveon microPET
from Point Source Scans
K. Gong, J. Zhou, M. Tohme, J. Qi
University of California, Davis, United States
M18-43 The AdaptiSPECT Pinhole Aperture
C. Chaix1, J. W. Moore1, R. Van Holen2, L. R. Furenlid1,3, H. H. Barrett1,3
1
College of Optical Sciences - The University of Arizona, USA; 2MEDISIPS
Department of Electronics and Information Systems, Ghent University, Belgium;
3
Department of Radiology - The University of Arizona, USA
M18-44 First Imaging Result with an Ultrahigh Resolution Stationary
MR Compatible SPECT System
L. Cai1, Z. Shen1, J. Zhang1,2, C.-T. Chen3, L. Meng1
1
University of Illinois at Urbana Champaign, USA; 2Chinese Academy of
Sciences, China; 3University of Chicago, USA
M18-45 Impact of Analog IC Impairments in SiPM Interface Electronics
S. Dey, T. K. Lewellen, R. S. Miyaoka, J. C. Rudell
M18-46 Evaluation of Computed Tomography Scan Ability in Detecting
Chest Nodules Using Tissue Equivalent Phantom
V. Changizi, Tehran University of Medical Sciences, Iran; S. Moein Azad,
Islamic Azad University, Iran
M18-47 Stationary Edge Detection and Compressed Sensing Based
Scatter Estimation for Scatter Correction in Computed Tomography
B. Meng, L. Xing, H. Lee, B. Fahimian
Stanford University, US
M18-48 Monitoring Respiratory Motion Using Continuous Wave
Doppler Radar in a Near Field Multi Antenna Approach
F. Pfanner1, T. Allmendinger2, T. Flohr2, M. Kachelrieß1,3
1
Friedrich-Alexander-University Erlangen-Nürnberg (FAU), Germany;
2
Healthcare Sector, Germany; 3German Cancer Research Center (DKFZ),
Germany
M18-49 Analysis of Bony Tissue in Synchrotron Radiation X-Ray
microCT Using Graph Cuts and the Connect Algorithm
A. A. M. Meneses1, C. J. G. Pinheiro2, D. Braz3, L. F. Oliveira4, W. F. Sacco1,
R. C. Barroso4
1
Federal University of Western Para, Brazil; 2Federal University of Espirito
Santo, Brazil; 3Federal University of Rio de Janeiro, Brazil; 4Rio de Janeiro State
University, Brazil
M18-50 Preliminary Studies into the Determination of Mean Glandular
Dose During Diagnostic Mammography Procedure in Ghana
I. Nsiah-Akoto, Ghana Atomic Energy Commission, Ghana; A. B. Andam,
Univerisity of Ghana, Ghana; E. K. Addison, A. J. Forson, Kwame Nkrumah
University of Science and Technology, Ghana
M18-51 Exploration of Brain Activations by Passive Hand Movements
and Subject’s Intention Based on Kawashira Method Using 3T-fMRI
T. Kawashima1, K. Kida2, S. Kuwahara1, T. Yokote1, T. Doi1, S. Goto1, Y.
Azuma1
1
Okayama University, Japan; 22Japanese Red Cross Okayama Hospital, Japan
M18-52 Observation of Activation Brain Areas in Response to the
Stimulation by the Right Hand Movement of Kawahira Method Using
fMRI
T. Yokote1, K. Kida2, S. Kuwahara1, T. Kawashima1, T. Doi1, S. Goto1, Y.
Azuma1
1
M18-53 Reduction of Scan Time for Phase Image of 3T Magnetic
Resonance Imaging to Detect of Calcification
T. Doi1, K. Kida2, S. Goto1, Y. Azuma1, T. Kawashima1, T. Yokote1, T.
Kajitani2
1
M18-54 Detection of Calcification in Human Breast Using Phase Image
of Magnetic Resonance Imaging
K. Kida1, S. Goto2, T. Doi2, T. Kajitani1, Y. Azuma2
1
Japanese Red Cross Okayama Hospital, Japan; 2Okayama University, Japan
M18-55 Theoretical Calibration for Spectrum Estimation Error in Dual
Energy CT
P. Zheng1,2,3, Y. Liu3, Y. Xing1,2
1
Tsinghua University, P. R. China; 2Ministry of Education, P. R. China;
3
Ministry of Environmental Protection of P. R. China, P. R. China
M18-56 Dosimetry in Small Animal CT with Monte Carlo Simulations
C.-L. Lee, S.-J. Park, D.-H. Kim, P.-H. Jeon, H.-J. Kim
M18-57 Accuracy of Linear Attenuation Coefficients Measured with a
Photon Counting CT System
T. Kobayashi, K. Ogawa, F. Kaibuki, Graduate School of Engineering, Hosei
University, Japan; T. Yamakawa, T. Nagano, D. Hashimoto, Telesystems Co
Ltd., Japan
M18-58 Electron Density Resolution Determination and Systematic
Uncertainties in Proton Computed Tomography (pCT)
G. Dedes1,2, S. Rit2, D. Dauvergne1, N. Freud2, J. Krimmer1, J. M. Letang2,
C. Ray1, E. Testa1
1
IPNL, Universite de Lyon, F-69003 Lyon, France; Universite Lyon 1 and
CNRS/IN2P3, UMR 5822 F-69622 Villeurbanne, France, France; 2CREATIS,
Universite de Lyon, F-69622 Lyon, France; Universite Lyon 1 and CNRS UMR
5220; INSERM U1044; INSA-Lyon; Centre Leon Berard, France, France
M18-59 Beam Hardening Correction Using a Attenuation Coefficient
Decomposition Approach
J. Deng, S. Yan, Siemens Molecular Imaging, USA
M18-60 Comparative Analysis of Preprocessing Techniques for
Extracting Co-Occurrence Texture Features for Automatic Segmentation
of Breast Ultrasound
R. I. Rivera-Islas, CINVESTAV-IPN, Mexico; W. Gomez-Flores, ,
M18-61 Evolutive Pulse-Coupled Neural Networks for Breast
Ultrasound Segmentation
E. Aceves-Adan, CINVESTAV-IPN, Mexico; W. Gomez-Flores, ,
M18-62 Dual Energy Tissue Cancellation Based on Appearance
Complexity
S. Kim, Y. Sung, H.-H. Oh, D.-G. Kang, K. Lee, S. Lee
Samsung Advanced Institute of Technology, Korea
M18-63 Electron Density Imaging Combining Transmission and
Compton Scattered X-Ray CT Technique
J. Yoshida, A. Yamazaki, K. Watanabe, A. Uritani
M18-64 Rotation-Free Computed Tomography with Orthogonal Ray
Imaging: First Millimetric Experimental Results
H. Simões1, M. C. Battaglia1,2, M. Capela3, M. C. Lopes3, P. Crespo1
1
Laboratório de Instrumentação e Física Experimental de Partículas, Portugal;
2
Universidade de Coimbra, Portugal; 3Instituto Português de Oncologia de
Coimbra Francisco Gentil, EPE, Portugal
M18-65 Digital Breast Tomosynthesis and Digital Mammography a
Comparison of Figure of Merit for Different Average Glandular Dose
Y.-S. Kim, H.-S. Park, H.-J. Kim
Yonsei University, South Korea
M18-66 The Property of Signal-to-Noise and its variation over spatial
frequency in Differential Phase Contrast CT
X. Tang, Y. Yang, S. Tang
Department of Radiology and Imaging Sciences, Emory University School of
Medicine, USA
M18-67 Impact of Covariance on Differential X-Ray Phase Contrast
Image Quality
D. Beque, J. I. Sperl, C. Cozzini
GE Global Research, Germany
M18-68 Many-View under-Sampling (MVUS) Technique for Low-Dose
CT: Dose Versus Image Quality
T. Lee, J. Min, S. Cho
246 Friday - MIC Poster Presentations M18-69 Bladder Wall Motion Compensation by Minimizing a New
Information-Theoretic Measure
Q. Lin1,2, Z. Liang1, J. Ma1, H. Li1, S. Jambawalikar1, D. Harrington1, H.
He2
1
State University of New York at Stony Brook, U.S.A.; 2Sichuan University,
China
M18-70 Potential for Image-Guided Coronary Artery Care with
Magnetic Nanoparticles
I. N. Weinberg1, L. O. Mair2, P. Y. Stepanov1, M. Urdaneta1, R. Probst2, S.
T. Fricke3
1
Weinberg Medical Physics, USA; 2University of Maryland, USA; 3Children’s
National Medical Center, USA
M18-71 Comparison of Projection Domain Noise Reduction Methods
in Low-Dose Dental CBCT
J. Hao1,2, L. Li1,2, L. Zhang1,2, Z. Chen1,2, K. Kang1,2
1
M18-72 Reducing Intra Plane Blurring in Dental Panoramas
C. Hofmann, M. Knaup, Institut of Medical Physics, Germany; M.
Kachelrieß, German Cancer Research Center (DKFZ), Germany
M18-73 Phantom Experimentation on Infrared and Optical
Tomography
A.-N. Rapsomanikis1, M. Zioga1, M. Kontos1, M. Mikeli1, E. Stiliaris1,2
1
M18-74 Limited Angle Geometries Applied to Small Animal Imaging
H. Barquero, D. Brasse, IPHC - CNRS, FRANCE
M18-75 Noise Simulation for Low-Dose Computed Tomography
Y. Fan, A. Zamyatin, Toshiba Medical Research Instituate, United States; S.
Nakanishi, Toshiba Medical Systems Corp., Japan
M18-76 Comparison of Patient Doses at Different CT Scanners with the
Same Acquisition Protocol
L. Balkay, A. Oszlanszki, A. Krizsan
Institute of Nuclear Medicine, University of Debrecen, Hungary
M18-77 Iterative Dual-Energy Raw Data Decomposition for Slow kVp
Switching: a Feasibility Study
A. Sisniega1, J. F. Abascal1, M. Abella1, M. Desco2, J. J. Vaquero1
1
Universidad Carlos III de Madrid, Spain; 2Hospital GU Gregorio Maranon,
CIBER de Salud Mental (CIBERSAM), Spain
M18-78 Smoothly Clipped Absolute Deviation (SCAD) Regularization
for Compressed Sensing MRI Using an Augmented Lagrangian Scheme
A. Mehranian1, H. Salighe Rad2,3, M. R. Ay2,3, A. Rahmim4, H. Zaidi1,5,6
1
Geneva University Hospital, Switzerland; 2Tehran University of Medical
Sciences, Iran; 3Tehran University of Medical Sciences, Tehran; 4Johns Hopkins
University, USA; 5Geneva University, Switzerland; 6University of Groningen,
Netherlands
M18-79 Observable Analysis for Proton Computed Tomography
C. Bopp1, J. Colin2, D. Cussol2, C. Finck1, M. Labalme2, M. Rousseau1, D.
Brasse1
1
Université de Strasbourg, IPHC, CNRS UMR7178, 23 rue du Loess, France;
2
LPC CAEN, ENSICAEN, 6 bd Marchal Juin, France
M18-80 Comparison of Absorbed Doses and Images Quality for LowDose and Standard-Dose CT Scanning of the Paranasal Sinuses
P. Jamshidi1,2, M. Bayat1,2
1
Zanjan University of Medical Sciences (ZUMS), Iran; 2Education and
Treatment Center of Mousavi, Iran
M18-81 Analysis of Calcium Distribution in Femur of Female Rats
Submitted to Different Chemotherapy Regimens
C. B. V. D. Andrade1,2, C. Salata1, C. M. D. Silva1, S. C. Ferreiramachado1,3, L. P. Nogueira1, R. C. Barroso1, A. P. D. Almeida1, D. Braz4, C.
E. deAlmeida1
1
UERJ, Brazil; 2USS, Brazil; 3UFF, Brazil; 4UFRJ, Brazil
M18-82 Multi-Resolution Diffusion Tensor Filter for Preserving Noise
Power Spectrum in Low-Dose CT Imaging
M. S. Kaplan, Z. Yang, A. A. Zamyatin
M18-83 Image Reconstruction of Computerized Tomography by
Photoacoustic Methods
V. M. Moock, C. García-Segundo, E. Garduño, F. Arámbula Cosio
Universidad Nacional Autónoma de México, México
M18-84 Multiple Frequency Focusing Method using Orthogonal Subband Codes for Ultrasound Imaging Scanners based on Wide Bandwidth
CMUT Arrays
B.-H. Kim, S. Lee, Y. Kim, K. Cho, J. Song
Samsung Advanced Institute of Technology, Samsung Electronics Co., LTD,
South Korea
M18-85 Computed Tomography System Using a MHSP for Small
Animal Imaging with Energy Resolving Capability
L. F. N. D. Carramate1, C. C. A. B. Oliveira1,2, A. L. M. Silva1, C. D. R.
Azevedo1, A. M. da Silva1, J. F. C. A. Veloso1
1
Aveiro University, Portugal; 2LBNL, USA
M18-86 Study of a New Approach to Get Fast CT-DEI Images of Normal
and Pathological Breast Specimens
A. L. C. Conceicao1,2, M. Antoniassi2, M. E. Poletti2
1
HASYLAB at DESY, Germany; 2Universidade de Sao Paulo, Brazil
M18-87 An Improved Motion Tracking Technique for Motion
Correction in Computed Tomography (CT)
J.-H. Kim1, J. Nuyts2, Z. Kuncic1, R. Fulton1,3
1
University of Sydney, Australia; 2Katholieke Universiteit, Belgium; 3Westmead
Hospital, Australia
M18-88 Auto Prescan Calibration Method for Multislice Fast Spin Echo:
a Simple Approach for Slice Selection Gradient Area Calibration
D. H. Lee1, C. P. Hong1, M. W. Lee2, B. S. Han1
1
Yonsei University, Rep. of Korea; 2Samsung Electronics, Rep. of Korea
M18-89 Evaluation of Convergence Speed of a Modified Nesterov
Gradient Method for CT Reconstruction
X. Rui, L. Fu, K. Choi, B. De Man
General Electric - Global Research, USA
M18-90 The Effect of Motion Artifacts on Motion Estimation and Its
Potential Solutions
Q. Tang1, H. Bal2, K. Taguchi1
1
The Johns Hopkins University, USA; 2Independent researcher, USA
M18-91 Sparse Angular X-Ray Cone Beam CT Image Iterative
Reconstruction Using Normal-Dose Scan Induced Nonlocal Prior
H. Zhang1, Z. Bian1, J. Ma1, J. Huang1, Z. Liang2, W. Chen1
1
School of Biomedical Engineering, Southern Medical University, China;
2
Department of Radiology, Stony Brook University, USA
M18-92 Penalized Weighted Alpha-Divergence Approach to Sinogram
Restoration for Low-Dose X-Ray Computed Tomography
L. Tian1, J. Ma1, Z. Bian1, Y. Zhang1, H. Zhang1, Z. Liang2, W. Chen1
1
School of Biomedical Engineering, Southern Medical University, China;
2
Department of Radiology, Stony Brook University, USA
M18-93 A Visibility Optimization Method for Grating-Based X-Ray
Phase Contrast Imaging
G. P. Kudielka, K. Mahdi, J. I. Sperl, D. Bequ, C. Cozzini
GE Global Research, Germany
248 Friday - MIC Poster Presentations Notes
Notes
Notes
07:00
07:30
08:00
MIC Refresher
Course 4
Saturday, 3 November
Grand Ballroom
Center
Grand Ballroom
North
Exhibit Hall South
Saturday - MIC Oral
Presentations
M23 Data Correction and Quantitative
Imaging Techniques 2
Saturday, Nov. 3 10:30-12:30 Grand Ballroom Center
08:30
09:00
M21: POSTER: High
Resolution & Pre-Clinical
Imaging Instrumentation
09:30
10:00
M22: POSTER: Imaging
in Radiotherapy / Image
Processing and Parametric
Imaging
Session Chairs: Georges El Fakhri, Harvard Medical School and
Massachusetts General Hospital, USA
Steven R. Meikle, University of Sydney, Australia
M23-1 (10:30) TOF-MLAA for Attenuation Correction in Thoracic
10:30
11:00
11:30
12:00
M23: Data Correction and
Quantitative Imaging
Techniques 2
12:30
13:00
13:30
14:00
14:30
15:00
15:30
16:00
16:30
PET/CT
J. J. Hamill, V. Y. Panin, Siemens Healthcare, USA
M23-2 (10:45) Evaluation of an Atlas-Based MR-Based PET Head
Attenuation Correction Using PET/CT & MR Clinical Data
S. D. Wollenweber, S. Ambwani, GE Healthcare, USA; A. H. R. Lonn, GE
Healthcare, UK; R. Mullick, GE Global Research, India; F. Wiesinger, GE
Global Research, DE; Z. Piti, Radiology, HU; G. Novak, M. Fidrich, GE
Healthcare, HU
M23-3 (11:00) Markov Random Field and Gaussian Mixture for MRIDriven Partial Volume Correction in PET
A. Bousse1, S. Pedemonte2, K. Erlandsson1, B. A. Thomas1, S. Ourselin2, S.
Arridge2, B. F. Hutton1
1
Institute of Nuclear Medicine, UCL, United Kingdom; 2Centre for Medical
Image Computing, UCL, United Kingdom
M23-4 (11:15) MRI Assisted Motion Correction in Dual-Gated 5D
Myocardial Perfusion PET Imaging
J. Tang, Oakland University, USA; N. Hall, Saint Joseph Mercy Oakland
Hospital, USA; A. Rahmim, Johns Hopkins University, USA
M23-5 (11:30) A Generic Respiratory Motion Model Based on 4D MRI
Imaging and 2D Image Navigators
H. J. Fayad1, C. Buerger2, C. Tsoumpas2, C. Cheze-Le-Rest1, D. Visvikis1
1
INSERM UMR1101, LaTIM, France; 2Kings College, UK
M23-6 (11:45) Fast Iterative Nonlinear Algorithms for Reduced
Parameter Space Kinetic Modeling
M. B. Oktay, D. J. Kadrmas, University of Utah, USA
M23-7 (12:00) Accurate and Consistent Lesion Quantitation with
Clinically Acceptable Penalized Likelihood Images
E. Asma1, S. Ahn1, S. G. Ross2, A. Chen2, R. M. Manjeshwar1
1
General Electric Global Research, USA; 2General Electric Healthcare, USA
M23-8 (12:15) Evaluation of the Quantitative Imaging Capability of a
Simultaneous Beta-and-Coincidence-Gamma Plant Imager
J. Wen, R. Dirks, L. Sobotka, H. Wu, Y.-C. Tai
Washington University in St. Louis, USA
17:00
17:30
18:00
18:30
19:00
19:30
254 254
Saturday - MIC Oral Presentations 255
Saturday - MIC Poster
Presentations
M21-12 Experimental Sub-Millimeter Resolution with a Small-Animal
M21 POSTER: High Resolution & Pre-Clinical
Imaging Instrumentation
Saturday, Nov. 3 08:15-10:30 Grand Ballroom North
Session Chairs: Freek J. Beekman, Delft University of Technology,
Netherlands
Yuan-Chuan Tai, Washington University in St. Louis,
USA
M21-1 Development of a Ultrahigh Resolution PET System for Small
Animals
S. Yamamoto1, H. Watabe2, Y. Kanai2, K. Kato1, J. Hatazawa2
1
Nagoya University Graduate School of Medicine, Japan; 2Osaka University
Graduate School of Medicine, Japan
M21-2 Spatial Localization of Metallic Particles in a Liquid Solution
Using X-Ray Fluorescence Tomography
W. Hassan, L. Hamawy, Lebanese International University, Lebanon; S.
Barre, Institut Polytechnique de Grenoble, France; S. Legoupil, Commissariat a
l’energie Atomique, France
M21-3 The RITOR Project (Research for Inner Ear CT)
R. Brancaccio1,2, M. Bettuzzi1,2, M. P. Morigi1,2, F. Casali1,2, L. Ragazzini1,2
1
University of Bologna, Italy; 2INFN, Italy
M21-4 High-Resolution Anamorphic SPECT Imaging
H. L. Durko, H. H. Barrett, L. R. Furenlid
University of Arizona, USA
M21-5 A 2D Sensitivity Encoded Silicon Photomultiplier (SeSP) for
simultaneous high resolution PET/MR scanners
V. Schulz1,2, A. Berneking1, F. Kiessling2, A. Gola3, C. Piemonte3
1
Philips Research Aachen, Germany; 2RWTH-Aachen University, Germany;
3
M21-6 Evaluation of Light Extraction from PET Detector Modules
Using Gamma Equivalent UV Excitation
B. Jatekos, E. Lorincz, F. Ujhelyi, G. Erdei
M21-7 Development and Evaluation of DOI Capable Detectors and
System Level Effects
C. J. Bircher, Y. Shao, X. Sun, A. Lan
M21-8 Small Animal PET with a Clinical PET/CT: Optimizing Image
Quality with MAP Reconstruction and Super-Resolution
F. P. DiFilippo, Cleveland Clinic, USA; Y. Lin, B. Bai, R. M. Leahy, University
of Southern California, USA
M21-9 Comparison of Performances of the Hybrid Pixel XPAD3 Versus
the CCD DALSA XR-4 in Micro CT Imaging
H. Ouamara1, F. Cassol Brunner1, A. Bonissent1, Y. Boursier1, C. KronlandMartinet1, J.-C. Clemens1, M. Dupont1, F. Debarbieux2, C. Morel1
1
CPPM, France; 2IBDML, France
M21-10 SPECT Imaging of Mouse Organs with protoBrazuka
J. Mejia1,2, O. Y. Galvis-Alonso1, B. Miller3
1
Medicine School of Sao Jose do Rio Preto, Brazil; 2Instituto Israelita de Ensino e
Pesquisa Albert Einstein, Brazil; 3University of Arizona, USA
M21-11 SPECT Imaging of Small Animal (Mice) Organs with SPEM
J. Mejia1,2, M. A. Reis1, A. C. C. Miranda1, E. Amaro Jr1, R. A. Bressan1
1
Instituto Israelita de Ensino e Pesquisa Albert Einstein, Brazil; 2Medicine School
of Sao Jose do Rio Preto, Brazil
256 Saturday - MIC Poster Presentations RPC-PET Prototype
P. Martins1,2, P. Crespo1, R. Ferreira Marques1,2, L. Lopes1, P. Fonte1,3
1
Portugal; 2University of Coimbra, Portugal; 3ISEC - Instituto Superior de
Engenharia de Coimbra, Portugal
M21-13 Performance Comparison of GENISYS4 and microPET
Preclinical PET Scanners
B. Bai1, M. Dahlbom2, R. Park1, L. Hughes1, G. Dagliyan1, L.-P. Yap1, P. S.
Conti1
1
University of Southern California, USA; 2University of California, USA
M21-14 Dual-Energy Micro-CT for Small Animal Bone-Iodine
Decomposition
C. Bouckaert, B. Vandeghinste, S. Vandenberghe, C. Vanhove
Ghent University-IBBT, Belgium
M21-15 X-Ray Dose Quantification for Various Scanning Protocols with
the GE eXplore 120 Micro-CT
F. Bretin, M. A. Bahri, G. Warnock, C. Phillips, A. Luxen, A. Seret, A.
Pleneveaux
University of Liege, Belgium
M21-16 Physical Characterization of a Wireless Radiotracer Detection
System Based on Pixelated Silicon for in Vivo Brain Studies in Freely
Moving Rats
J. Maerk1, D. Benoit2, L. Balasse2, M. Benoit3, J.-C. Clemens1, S. Fieux4, D.
Fougeron1, J. Graber-Bolis1, B. Janvier2, M. Jevaud1, A. Genoux2, P. GisquetVerrier5, M. Menouni1, F. Pain2, L. Pinot2, C. Tourvielle4, L. Zimmer4, C.
Morel1, P. Laniece2
1
Centre de Physique des Particules de Marseille (Univ. Aix-Marseille et CNRS),
France; 2Imagerie et Modelisation en Neurobiologie et Cancerologie (Univ. P7/
P11 et CNRS), France; 3CERN, Switzerland; 4CERMEP-Imagerie du vivant
(Groupement Hospitalier et Univ. Lyon 1), France; 5Centre de Neurosciences de
Paris-Sud (Univ. P11 et CNRS), France
M21-17 Theranostics Imaging of Tumours Labelled with Gold
Nanoparticles: Concept Validation
A. Castoldi1,2, C. Guazzoni1,2, G. V. Montemurro1,2, K. Ricketts3, G. Royle3,
M. Loizidou4, U. Cheema4, A. Nyaga4, A. Bjeoumikhov5
1
Politecnico di Milano, Italy; 2INFN, Italy; 3University College London, UK;
4
UCL Medical School, UK; 5IfG GmbH, Germany
M21-18 Performance Evaluation of the GE eXplore CT 120 Micro-CT
for Various Scanning Protocols
M. A. Bahri, F. Bretin, G. Warnock, A. Luxen, E. Salmon, A. Plenevaux, A.
Seret
University of Liege, Belgium
M21-19 A Sub-Millimeter-Resolution PET Scanner Prototype Based on
Single LYSO Crystal Readout with SiPMs and MLEM Reconstruction
F. R. Schneider, M. Hohberg, A. Kristen, J. Pulko, S. I. Ziegler, A. B. Mann,
I. Konorov, S. Paul
Technische Universitaet Muenchen, Germany
M21-20 Monte-Carlo Simulation of 18F Positron Imaging Using a
Silicon Pixel Detector with Energy Information
Q. Wang, K. Shi, S. I. Ziegler
Technische Universitaet Muenchen, Germany
M21-21 High-Accuracy Optical Tracking System for Freely Moving Mice
Inside a Small Animal PET Scanner
S. Schmid, M. Dawood, L. Frohwein, X. Jiang, K. P. Schaefers
University of Muenster, Germany
M21-22 A Second Generation Virtual Pinhole PET Micro Insert System
B. Ravindranath1, J. Wen1, A. J. Mathews1, S. Komarov1, L. Wang1, D. Hu2,
S. B. Siegel2, J. O’Sullivan1, Y.-C. Tai1
1
Washington University in St. Louis, USA; 2Siemens Medical Solutions, USA
M21-23 SiPM-Based PET Module with Depth of Interaction
F. Pennazio, Universita` degli Studi di Torino and INFN, Italy
On behalf of the 4DMPET Collaboration
Saturday - MIC Poster Presentations 257
M21-24 A Low Cost, Multipurpose, Multiplatform Pinhole Collimator-
Based Upgrading of a Clinical Gamma Camera for Small Animal SPECT
Imaging
O. Y. Galvis-Alonso1, J. Mejia2, L. F. Oliveira3, E. E. Carvalho3, J. Braga4, J.
P. Leite3, M. V. Simoes3
1
Medicine School of Sao Jose do Rio Preto (FAMERP), Brazil; 2Instituto Israelita
de Ensino e Pesquisa Albert Einstein, Brazil; 3University of Sao Paulo (USP-RP),
Brazil; 4Brazilian National Institute for Space Research (INPE), Brazil
M21-25 Effect of Temperature on the Performance of a SiPM Detector
for an MR Compatible PET System
A. L. Goertzen1, X. Zhang1, C.-Y. Liu1, P. Kozlowski2, F. Retiere3, V. Sossi2,
G. Stortz2, C. J. Thompson4
1
3
M21-26 Detector Design for a Dedicated Mouse Brain PET
C. Parl, A. Kolb, C.-C. Liu, B. J. Pichler
Eberhard Karls University Tuebingen, Germany
M21-27 Detector Module of the miniPET-3 Small Animal PET Scanner
J. Imrek, G. Hegyesi, G. Kalinka, B. Kiraly, J. Molnar, F. Nagy, I. Valastyan,
Institute of Nuclear Research of the Hungarian Academy of Sciences, Hungary;
Z. Szabo, L. Balkay, University of Debrecen, Hungary
M21-28 Advantages of Augmenting Standard PET Data with HighResolution Information
N. Clinthorne1, K. Brzezinski2, E. Chesi3, M. Grkovski4, B. Grosicar4, H.
Kagan5, C. Lacasta2, M. Mikuz4, S. Smith5, V. Stankova2, A. Studen4, P.
Weilhammer3, D. Zontar4
1
University of Michigan, USA; 2IFIC/CSIC University of Valencia, Spain;
3
CERN, Switzerland; 4Jozef Stefan Institute, Slovenia; 5Ohio State University,
USA
M21-29 Comparison of Three Different Approaches to Correct for
Partial Volume Effect for the nanoScan PET/CT Pre-Clinical Scanner
I. Szanda1, K. Thielemans1, J. Lantos2, G. E. Mullen1, G. Nemeth2, L.
Livieratos1,3, J. E. Mackewn1, S. Hobor2, G. Egri2, T. Bukki2, P. Major2, P. K.
Marsden1
1
King’s College London, United Kingdom; 2Mediso Ltd., Hungary; 3Guys and St
Thomas Hospitals, United Kingdom
M21-30 New PMT-Quadrant-Sharing Block Detector Development for
High Performance TOF PET Applications
Y. Zhang, R. Ramirez, H. Li, H. Bagheai, W.-H. Wong
M21-31 Imaging Performance of the Inveon SPECT System Using
Single and Multi-Pinhole Collimators Dedicated to Mouse Studies
F. Boisson1, D. Zahra1, A. Parmar1, S. R. Meikle2, M.-C. Gregoire1, A.
Reilhac1
1
M21-32 Evaluation of Matrix9 for Small-Animal PET
J. Du1, J. Schmall1, Y. Yang1, K. Di1, E. Roncali1, N. Pavlov2, S. Buckley2, C.
Jackson2, S. R. Cherry1
1
University of California-Davis, USA; 2SensL Technologies Ltd., Ireland
M21-33 Parameter Optimization and Effective Imaging Volume
Determination of Helical Scan for a Pinhole Animal SPECT
R. Yao1, X. Deng1, T. Dai2, Q. Wei2, J.-F. Beaudoin3, C. Naaman3, T. Ma2, J.
Cadorette3, R. Lecomte3
1
State University of New York at Buffalo, United States; 2Tsinghua University,
China; 3University of Sherbrooke, Canada
M21-34 Characterization of Detectors for a High Sensitivity SPECT
System for Small Animals and Plants
K. L. Byrne, J. Zhou, J. Qi, S. R. Cherry, G. S. Mitchell,
UC Davis, USA
M21-35 Imaging Progression of Cardiac Hypertrophy in Spontaneously
Hypertensive Rats Using Dynamic SPECT with Pinhole Collimation
R. Boutchko1, K. M. Brennan1, M. Abdallah2, D. Mitra2, G. T. Gullberg1
1
Lawrence Berkeley National Lab, CA; 2Florida Institute of Technology, FL
258 Saturday - MIC Poster Presentations M21-36 Characterization of One Plane from a 1mm3 Resolution
Clinical PET System
P. D. Reynolds, F. W. Y. Lau, A. Vadenbroucke, D. R. Innes, U. Yoruk, C.
S. Levin
M21-37 Identifying and Sorting Crystal Pixel Locations in Position
Sensitive Detectors Using Pictorial Structures
A. Vandenbroucke, C. S. Levin, Stanford University, CA
M21-38 Design and Performance Evaluation of SiPM PET Detector for
High Magnetic Field Small Animal Dedicated PET/MR Imaging
G. B. Ko, S. I. Kwon, H. S. Yoon, J. S. Lee
Seoul National University College of Medicine, Korea
M21-39 Considerations of Inter-Crystal Scattering and Signal-to-Noise
Ratio for High Resolution PET Block Detector Design
H. Peng, McMaster University, Canada; C. Levin, Stanford University, USA
M21-40 Ring Artifact Reduction for Preclinical microCT via Adaptive
Distance-Weighted Pixel Correction
S. Yan, J. Deng, T. Bruckbauer
Siemens Molecular Imaging, USA
M21-41 Slit-Slat Collimator Geometrical Calibration for a PET/SPECT
Dual Modality Animal Scanner
X. Deng1, J.-F. Beaudoin2, J. Cadorette2, C. Naaman3, R. Lecomte2,3, R. Yao1
1
University at Buffalo, USA; 2Centre Hospitalier Universitaire de Sherbrooke,
Canada; 3Universit de Sherbrooke, Canada
M21-42 Strategies for More Compact Pulse Width Modulation for
Silicon Photomultiplier Readout
M. F. Bieniosek, P. D. Olcott, C. S. Levin
M21-43 Design of a New Small-Animal SPECT System Based on
Rectangular Pinhole Apertures
S. D. Metzler, University of Pennsylvania, USA; S. C. Moore, M.-A. Park,
Brigham and Women’s Hospital and Harvard Medical School, USA
M21-44 Development and Quantitative Assessment of a Beam
Hardening Correction Model for Preclinical μCT
S. Mohapatra, J. J. Sunderland, S. Walsh, M. R. Acevedo
University of Iowa, USA
M21-45 Signal Correction Strategies for Large-Area Position-Sensitive
Solid-State Photomultipliers Used in Small Animal PET Detector
Designs
J. P. Schmall1, J. Du1, P. Dokhale2, K. S. Shah2, S. R. Cherry1
1
University of California - Davis, United States; 2Radiation Monitoring Devices,
Inc., United States
M21-46 Multiplexing Strategies for cMiCE PET Detectors
R. S. Miyaoka, W. C. Hunter, L. Pierce
M21-47 Markerless Motion Tracking Enabling Motion Compensated
PET in Awake Rats
A. Kyme1, S. Se2, S. Meikle1, W. Ryder1, K. Popovic1, C. Baldock1, R.
Fulton1,3
1
University of Sydney, Australia; 2MDA Systems Ltd, Canada; 3Westmead
Hospital, Australia
M21-48 Preliminary Results of Developed Dual Energy (I-131,Tc-99m)
Gamma Ray Imaging System for Small Animal
J. G. Kim1, Y. Jung1,2, T. S. Lee1, J. S. Kim1, S.-K. Woo1, J.-A. Park1, S. M.
Lim1, K. M. Kim1
1
Korea Instiute of Radiological and Medical Sciences, Korea; 2bDepartment of
Radiology science, Korea University, Korea
M21-49 Imaging Performance of the Inveon SPECT System Comparing
Rat and Mouse Dedicated Single and Multi-Pinhole Collimators
F. Boisson1, D. Zahra1, H. Hamze1, S. R. Meikle2, M.-C. Gregoire1, A.
Reilhac1
1
M21-50 A Comparison of Maximum List-Mode-Likelihood Estimation
and Maximum-Likelihood Clustering Algorithms for Depth Calibration
in Continuous-Crystal PET Detectors
W. C. J. Hunter, T. K. Lewellen, R. S. Miyaoka
M21-51 Complete Scheme for Beam Hardening Correction in Small
Animal Computed Tomography
C. de Molina1, A. Sisniega2, M. Desco1,2, J. J. Vaquero2, M. Abella2
1
Hospital GU Gregorio Maraon, Spain; 2Universidad Carlos III de Madrid,
Spain
M22 POSTER: Imaging in Radiotherapy / Image
Processing and Parametric Imaging
Saturday, Nov. 3 08:15-10:30 Exhibit Hall South
Session Chairs: Arkadiusz Sitek, Brigham and Women’s Hospital and
Harvard Medical School, USA
Chien-Min Kao, The University of Chicago, USA
M22-1 Iterative Motion-Compensated Reconstruction for Image-Guided
Radiation Therapy
M. Brehm1, P. Paysan2, M. Oelhafen2, P. Kunz2, M. Kachelrieß1,3
1
University of Erlangen-Nürnberg, Germany; 2Varian Medical Systems,
Switzerland; 3German Cancer Research Center (DKFZ), Germany
M22-2 Optimization of the in-Beam OpenPET Detector for Carbon
Beam Irradiation
F. Nishikido, Y. Hirano, N. Inadama, E. Yoshida, H. Tashima, S. Sato, T.
Inaniwa, H. Murayama, H. Ito, T. Yamaya
M22-3 PET Scanning of Ocular Melanomas after Proton Therapy
C. Hoehr1, K. Dinelle2, M. Trinczek1, E. Blackmore1, R. Lee3, W. Kwa3, S.
Blinder2, V. Sossi2, T. Ruth1, K. Paton2
1
TRIUMF, Canada; 2UBC, Canada; 3BCCA, Canada
M22-4 Development of a PET Detector Module for Dose Verification in
Carbon Therapy
H.-I. Kim1,2, C.-H. Baek1,2, S. J. An1,2, C. Y. Lee1,2, W. J. Jo1,2, K. Lee3, Y. H.
Chung1,2
1
Molecular Imaging Lab, Korea; 2Health Science, Korea; 3Medical Impomation
Processing Lab, Korea
M22-5 The Impact of Secondary Particles on in-Beam PET Imaging for
Dose Verification in Carbon Ion Therapy
S. J. An1,2, W.-G. Jung3, Y. H. Chung1,2
1
College of Health Science, Yonsei University, Republic of Korea; 2Institute
of Health Science, Yonsei University, Republic of Korea; 3Korea Institute of
Radiological and Medical Sciences, Republic of Korea
M22-6 Orthogonal Ray Imaging with Megavoltage Beams: Simulated
Results with an Anthropomorphic Phantom
M. C. Battaglia1,2,3, H. Simões1, V. Bellini3,4, E. Cisbani4,5, M. C. Lopes6, P.
Crespo1
1
2
Universidade de Coimbra, Portugal; 3Università di Catania, Italy; 4Istituto
Nazionale di Fisica Nucleare, Italy; 5Istituto Superiore di Sanità, Italy; 6Instituto
Português de Oncologia de Coimbra Francisco Gentil, EPE, Portugal
M22-7 LYSO Scintillators Coupled to Phototransistors for Orthogonal
Ray Imaging: Experimental Results at 4 and 6-MV Linacs
H. Simões1, M. C. Battaglia1,2, M. Capela3, A. Cavaco4, P. César4, M. C.
Lopes3, P. Rachinhas4, P. Soares4, P. Crespo1
1
2
Universidade de Coimbra, Portugal; 3Instituto Português de Oncologia de
Coimbra Francisco Gentil, EPE, Portugal; 4Centro Hospitalar e Universitário de
Coimbra, EPE, Portugal
260 Saturday - MIC Poster Presentations M22-8 Are Prompt Gamma Rays More Closely Correlated to the Proton
Range than PET in Treatment Verification?
D. C. Oxley1, A. K. Biegun1,2, A. J. van der Borden3, S. Brandenburg1, P.
Cambraia Lopes2, A. van der Schaaf3, A. van ‘t Veld3, D. R. Schaart2, P.
Dendooven1
1
University Of Groningen, The Netherlands; 2Delft University of Technology, The
Netherlands; 3University Medical Center Groningen, The Netherlands
M22-9 The Imaging Performance of Electronic Portal Imaging Devices
Evaluated Self-Consistently for Both X-Rays and Optical Photons
A. L. McNamara1, S. J. Blake1, P. Vial1,2, L. Holloway1,2,3, P. B. Greer4,5, Z.
Kuncic1
1
University of Sydney, Australia; 2Liverpool and Macarthur Cancer Therapy
Centres, Australia; 3University of Wollongong, Australia; 4Department of
Radiation Oncology, Australia; 5University of Newcastle, Australia
M22-10 Real-Time Monitoring During Ion Therapy: Development and
Evaluation of a Beam Hodoscope and Its Dedicated Electronics
M. De Rydt1,2, S. Deng3, D. Dauvergne2, G. Dedes2, N. Freud4, J.
Krimmer2, J.-M. Letang4, G.-N. Lu5, H. Mathez3, K. Parodi6, M. Pinto2, C.
Ray2, V. Reithinger2, M.-H. Richard2, I. Rinaldi6, F. Roellinghoff2, E. Testa2,
Y. Zoccarato3
1
Instituut voor Kern- en Stralingsfysica, K.U.Leuven, Belgium; 2IPNL,
Universite de Lyon, Universite Lyon 1 and CNRS/IN2P3, UMR 8522, France;
3
IPNL, Universite de Lyon, Universite Lyon 1 and CNRS/IN2P3, MicRhAu,
UMR 8522, France; 4CREATIS, Universite de Lyon, Universite Lyon 1 and
CNRS UMR 5220, France; 5Universite de Lyon, Institut des Nanotechnologies
de Lyon INL-UMR5270, CNRS, Universite Lyon 1, France; 6Heidelberg Ion
Therapy Center, Germany
M22-11 Imaging for Radiation Therapy of Moving Tumors:
Optimization of Imaging Protocols for Internal Target Volume
Definition and Monte Carlo Simulations of Dose Delivery
S. St. James1,2, J. Seco3,2, P. Mishra1,2, J. H. Lewis1,2
1
Brigham and Women’s Hospital, USA; 2Harvard Medical School, USA;
3
Massachusetts General Hospital, USA
M22-12 Clinical Potential of Proton Tomosynthesis in Proton Beam
Therapy
B. J. Min1, J. Kwak2, J. Lee3, S. Cho3, S. Y. Park4, K. Chung1, S. Cho1, Y. K.
Lim1, D. Shin1, S. B. Lee1
1
Proton Therapy Center, National Cancer Center, Korea; 2Department of
Radiation Oncology, Asan Medical Center, Korea; 3Department of Nuclear and
Quantum Engineering, KAIST, Korea; 4McLaren Cancer Institute, McLaren,
USA
M22-13 Optimization of Collimator Designs for Real-Time Proton
Range Verification by Measuring Prompt Gamma Rays
P. Cambraia Lopes1,2,3, M. Pinto2, H. Simoes2, A. K. Biegun1,4, P.
Dendooven4, D. C. Oxley4, K. Parodi3, D. R. Schaart1, P. Crespo2
1
Delft University of Technology, The Netherlands; 2Laboratorio de
Instrumentacao e Fisica Experimental de Particulas, Portugal; 3University Clinic
of Heidelberg, Germany; 4University Of Groningen, The Netherlands
M22-14 Theoretical and Numerical Analysis of the Single-Ring
OpenPET Geometry for in-Beam PET
H. Tashima1, Y. Hirano1, S. Kinouchi2, E. Yoshida1, H. Ito1, T. Yamaya1
1
National Institute of Radiological Siences, Japan; 2Chiba University, Japan
M22-15 Reconstruction from Truncated Projections Using Constrained
Total-Variation Minimization Applied to PET for Hadron-Therapy
Monitoring
J. Cabello1, I. Torres-Espallardo1, J. E. Gillam1, F. Diblen2, M. Rafecas1,3
1
Instituto de Fisica Corpuscular (IFIC), Universitat de Valencia/CSIC, Spain;
2
Universiteit Ghent, Belgium; 3Universitat de Valencia, Spain
M22-16 PET-Based Dosimetry in Particle Therapy: Assessing the
Feasibility of Regional MLEM Reconstruction as Quantitative Tool
C. Gianoli1, E. De Bernardi1,2,3, M. Riboldi1,4, G. Baselli1, J. Bauer5, K.
Parodi5, G. Baroni1,4
1
Politecnico di Milano, Italy; 2University of Milano-Bicocca, Italy; 3Tecnomed
Foundation, Italy; 4National Center for Oncologic Hadrontherapy (CNAO),
Italy; 5Heidelberg University Hospital, Germany
M22-17 Dedicated Multichannel Readout ASIC Coupled with Single
Crystal Diamond for Dosimeter Application
A. Fabbri1,2, V. Orsolini Cencelli1,3, F. de Notaristefani1,2, C. Verona1,3, G.
Verona Rinati1,3, M. Marinelli1,3, F. Petulla1,2
1
INFN Istituto Nazionale di Fisica Nucleare, Italy; 2Roma TRE University of
Rome, Italy; 3Tor Vergata University of Rome, Italy
M22-18 Pile-up Correction Techniques for Real-Time Dosimetry in
Photon Radiotherapy
M. Miklavec1, R. Novak1, B. Loeher2,3, D. Savran2,3,4, S. Sirca5,1, M. Vencelj1
1
Jozef Stefan Institute, Slovenia; 2GSI Helmholtzzentrum fuer
Schwerionenforschung, Germany; 3Frankfurt Institute for Advanced Studies
FIAS, Germany; 4Innovation Centre for Advanced Sensors and Sensor Systems,
INCAS, The Netherlands; 5University of Ljubljana, Faculty of Mathematics and
Physics, Slovenia
M22-19 3D Dose Verification Using 2D Images of CCD Camera Scintillation Screen System
S. Cho1, J.-I. Shin1, D.-H. Kim2, S. Park1, B. J. Min1, K. Chung1, C. Jeong1,
D. Shin1, Y. K. Lim1, J. Y. Kim1, S. Y. Park3, S. B. Lee1
1
National Cancer Center, Korea; 2Research Institute of Biomedical Engineering,
Korea; 3McLaren Cancer Institute, USA
M22-20 Prompt Gamma Imaging with a Slit Camera for Real-Time
Range Control in Proton Therapy: Experimental Validation up to 230
MeV with HICAM and Development of a New Prototype
I. Perali1, A. Celani2, P. Busca1,3, A. Marone1, C. Fiorini1,3, M. Basilavecchia2,
T. Frizzi2, F. Roellinghoff4, J. Smeets5, D. Prieels4, F. Stichelbaut4, F. Vander
Stappen4, S. Henrotin4, A. Benilov4
1
Politecnico di Milano, Italy; 2XGLab, Italy; 3INFN, Italy; 4Ion Beam
apllications SA, Belgium; 5Universit Libre de Bruxelles, Belgium
M22-21 Scintillation Detector Design and Performance for Proton
Water-Equivalent Pathlength Measurements Used in Proton CT and
Radiography
V. A. Bashkirov, Loma Linda University, USA
M22-22 Detector Design for Range Monitoring in Hadron Therapy by
Means of Image Reconstruction
F. Diblen, S. Espana, R. Van Holen, S. Vandenberghe
M22-23 Feasibility of Using Distal Endpoints for in-Room PET Range
Verification of Proton Therapy
K. Grogg, X. Zhu, C. H. Min, B. Winey, T. Bortfeld, H. Paganetti, G. El
Fakhri, Mass General Hospital, USA
M22-24 Feasibility of a PET Acquisition System for Full in-Beam
Monitoring in Proton Therapy
G. Sportelli1, N. Camarlinghi1, K. Straub1, N. Belcari1,2, M. G. Bisogni1,2,
G. A. P. Cirrone1, G. Cuttone1, S. Ferretti2, N. Marino1, J. E. Ortuno3,4, F.
Romano1, V. Rosso1,2, A. Santos3,4, A. Del Guerra1,2
1
Istituto Nazionale di Fisica Nucleare, Italia; 2Universita di Pisa, Italia;
3
Universidad Politecnica de Madrid, Spain; 4CIBER de Bioingeniera,
Biomateriales y Nanomedicina, Spain
M22-25 A Study of Proton Activation Tracer for Real-Time Dose
Monitoring in Radiotherapy
T. P. Lou, L. Mihailescu
M22-26 Deformed Image Restoration for on-board CBCT in Lung
Patient Case with Prior CT Information
Y. Jian
Department of Electrical and Computer Engineering, Duke University, USA
M22-27 Level Set Based Real-Time Anatomy Tracking
W. Liu, D. Ruan
University of California, Los Angeles, United States
M22-28 Gaussian Mixture Regression for Real-Time Tumor Motion
Prediction from External Surface Motion
F. Tahavori, M. Alnowami, K. Wells
University of Surrey, UK
262 Saturday - MIC Poster Presentations M22-29 Dynamic PET With Partial Data for Application to Whole
Body Studies
W. Zhu1, B. Bai1, P. S. Conti1, Q. Li2, R. M. Leahy1
1
University of Southern California, USA; 2Massachusetts General Hospital, USA
M22-30 Closed-Form Kinetic Parameter Estimation Using Wavelets
G. L. Zeng1, A. M. Hernandez2, D. J. Kadrmas1, G. T. Gullberg2
1
University of Utah, USA; 2Lawrence Berkeley National Laboratory, USA
M22-31 Reliability of Non-Parametric Kinetic Analysis for Dynamic
Studies with PET and MR
D. Hawe1, A. Hurley1, L. D. O’Suilleabhin2, M. Cronin1, F. O’Sullivan1
1
University College Cork, Ireland; 2University of California, USA
M22-32 Image Based Extraction of the Arterial Input Function for
Mapping Kinetic Parameters
J. Huang1, D. Conway1, L. Daly1, M. Muzi2, D. A. Mankoff2, F. O’Sullivan1
1
University College Cork, Ireland; 2University of Washington, USA
M22-33 Empirical Mode Decomposition as a feature extraction method
for Alzheimer’ Disease Diagnosis
J. M. Gorriz, University of Granada, Spain
M22-34 Optical Flow Vs Bspline Image Registration for Respiratory
Motion Modeling
H. J. Fayad1, C. Bakhous2, T. Pan3, D. Visvikis1
1
INSERM UMR1101, LaTIM, France; 2INIRIA-LJK, France; 3M.D. Anderson
Cancer Center, USA
M22-35 Monotonic Algorithm for Joint Entropy-Based Anatomical
Priors in Parametric PET Image Reconstruction
A. Bousse, C. Panagiotou, K. Erlandsson, S. Ourselin, S. Arridge, B. F.
Hutton
University College London, United Kingdom
M22-36 Adaptive Parametric Kinetic Modelling for Improved Full Field
of View Fitting of PET Data
J. C. Matthews1, A. J. Reader2, G. I. Angelis3, P. M. Price1, P. J. Markieiwicz1,
F. A. Kotasidis1,4
1
University of Manchester, UK; 2McGill University, Canada; 3University of
Sydney, Australia; 4Geneva University Hospital, Switzerland
M22-37 NUMERICS: Online Image Registration and Image
Comparison Platform
G. V. Gerganov1, V. Kuvandjiev1, I. S. Dimitrova1, I. Kawrakow2, K. K.
Mitev1
1
Sofia University, Bulgaria; 2ViewRay, Inc., USA
M22-38 3D X-Ray Phase-Contrast Tomography Based on Constrained
L1-Norm Minimization
A. Kostenko1, K. J. Batenburg2, E. S. Offerman1, L. J. van Vliet1
1
Delft University of Technology, The Netherlands; 2Centrum Wiskunde &
Informatica, The Netherlands
M22-39 Automatic Generation of Myocardial Contour with Respiratory
Motion Correction Using Contrast Enhanced Cardiac MRI for
Myocardial Perfusion Analysis
T. Natsume1, M. Nakano1, K. Kitagawa2, M. Ishida2, H. Sakuma2, T.
Ichihara1
1
Fujita Health University, Japan; 2Mie University Hospital, Japan
M22-40 Development of a Theory for Determining the Fluoro-Perfusion
Image-Based Fractional Flow Reserve Using Angiography in the
Coronary Angiography Lab
T. Ichihara1, T. Sakaguchi2, T. Natsume1, Y. Sekikawa1, J. C. Trost3, O.
Yousuf3, J. A. C. Lima3, R. T. George3
1
Fujita Health University School of Health Science, Japan; 2Toshiba Medical
Systems Corporation, Japan; 3The Johns Hopkins University School of Medicine,
USA
M22-41 SIFT-Based Motion Registration for Sequence Images of Instant
CT
L. Li, Y. Wang, Z. Chen, L. Zhang, Department of Engineering
Physics,Tsinghua University, China; G. Wang, VT-WFU School of Biomedical
Engineering and Sciences, Virginia Tech, USA
M22-42 A Feasibility Study of High Order Volumetric Texture Features
for Computer Aided Diagnosis of Polyps via CT Colonography
B. Song1, G. Zhang2, H. Zhu1, W. Zhu1, H. Lu2, Z. Liang1
1
Stony Brook University, USA; 2Fourth Military Medical University, China
M22-43 Motion-Based Adaptive View Interpolation in Tomosynthesis
J. H. Lee, Y. Sung, J. Lee, K. Lee, K. E. Jang, S. Lee
Samsung Advanced Institute of Technology (SAIT), Republic of Korea
M22-44 Intensity Normalization of FP-CIT SPECT in Patients with
Parkinsonism Using the Alpha-Stable Distribution
D. Salas-Gonzalez, J. M. Gorriz, J. Ramirez, F. J. Martinez, R. Chaves, F.
Segovia, I. A. Illan
University of Granada, Spain
M22-45 Deformable Model-Based PET Segmentation for Heterogeneous
Tumor Volume Delineation
M. Abdoli1, R. A. J. O. Dierckx1, H. Zaidi1,2
1
University of Groningen, University Medical Center Groningen, The
Netherlands; 2Geneva University Hospital, Switzerland
M22-46 A Fast Surface-Aware 3D Non-Linear Image Registration
Algorithm Implemented on a GPU
A. Gruslys, R. Ansorge, S. Sawiak
University of Cambridge, UK
M22-47 Matching of Irreversibly Deformed Images in Microscopy
Based on Piecewise Monotone Subgradient Optimization Using Parallel
Processing
J. Michalek, M. Capek, J. Janacek, L. Kubinova
Institute of Physiology ASCR, v.v.i., Czech Republic
M22-48 Low Count PET Sinogram Denoising
S. Peltonen, U. Tuna, U. Ruotsalainen
M22-49 A Multi Resolution and Multi Observation Framework for
Multi Modal Medical Images Processing and Analysis
H. Hanzouli, A. Le Pogam, D. Visvikis, M. Hatt
INSERM UMR1101, LaTIM, France
M22-50 Accurate Markerless Respiratory Tracking for Gated Whole
Body PET Using the Microsoft Kinect
P. J. Noonan1, J. Howard2, D. Tout1, I. Armstrong1, H. A. Williams1, T. F.
Cootes1, W. A. Hallett2, R. Hinz1
1
University of Manchester, UK; 2Imanova Imaging Centre, UK
M22-51 Relaxation Time Estimation in MRI
F. Baselice, G. Ferraioli, V. Pascazio
Universita’ di Napoli Parthenope, Italy
M22-52 Evaluation of Time of Flight (TOF) and Point Spread Function
(PSF) Reconstructions in the Quantification of Myocardial Blood Flow
with 13N Ammonia and PET: Comparison among Reconstructions
(Reprojection, OSEM), Software (PMOD and CARIMAS) and
Operators
L. Presotto1,2, E. Busnardo2, V. Bettinardi2,3, C. Landoni2,1, P. Todeschini2, O.
Rimoldi3, M. C. Gilardi3,4,1, L. Gianolli2
1
University of Milano Bicocca, Italy; 2San Raffaele Scientific Institute, Italy;
3
CNR, Italy; 4Tecnomed Foundation, Italy
M22-53 Improved Computer-Aided Colonic Polyp Detection Using a
Modified SVM Classifier with Adaptive Kernel
L. Fan, B. Song, X. Gu, Z. Liang
Stony Brook University, USA
M22-54 A Synthetic Image Phantom for Evaluation of the Performance
of Numerical Algorithms for Comparison of Noisy Medical Images
K. K. Mitev, G. V. Gerganov, Sofia University, Bulgaria; I. Kawrakow,
ViewRay, Inc., USA
M22-55 Direct 4D PET Reconstruction of Parametric Images into a
Stereotaxic Brain Atlas
P. Gravel1, J. Verhaeghe2, A. J. Reader1
1
McGill University, Canada; 2University of Antwerp, Belgium
264 Saturday - MIC Poster Presentations M22-56 Optimization of High Resolution PET Iterative Reconstruction
with Resolution Modeling for Image Derived Input Function
J. Lewis1, J. Anton1, S. Carter1,2, K. Herholz1, M.-C. Asselin1, R. Hinz1
1
University of Manchester, United Kingdom; 2Karolinska Institutet, Sweden
M22-57 Comparing Respiratory and Patient Movement During
Dynamic PET
L. Vengadabady1, K. Thielemans1,2,3, D. McCabe3, A. Challapalli1, T. J.
Spinks3, E. Aboagye1
1
Imperial College London, UK; 2Algorithms and Software Consulting Ltd, UK;
3
Hammersmith Imanet Ltd, UK
M22-58 Modeling of Human Glioblastoma with Spectral Analysis in
18F-FMISO PET Imaging
M. Bentourkia, Université de Sherbrooke, Canada; F. Lamare, M. Allard, P.
Fernandez, Universit de Bordeaux2, France
M22-59 An Efficient Extraction of Frontal Bone Surface In Ultrasound
Images with the Assistance of Diffusion Filters
S. Alimohamadi1, P. Farnia1, J. Hasani Bidgoli1, A. Ahmadian1,2
1
Research Center for Science and technology in Medicine, Iran; 2Tehran
University of Medical Sciences, Iran
M22-60 Derivation of Image-based Input Function Specific to Small
Arteries
J. L. Herraiz1, S. C. Moore2, R. L. Pande3, J. M. Fantony3, A. Sitek2, M.-A.
Park2
1
Madrid-MIT Consortium, United States; 2Brigham and Women’s Hospital,
Harvard Medical School, United States; 3Brigham and Women’s Hospital,
United States
M22-61 Towards Automated MR-Independent Estimation of
Neuroreceptor Binding Potential Parametric Maps for PET
M. Bieth, K. Siddiqi, Center for Intelligent Machines, McGill University,
Canada; P. Gravel, A. J. Reader, Montreal Neurological Institute, McGill
University, Canada
M22-62 Evaluation of Rapid Dual-Tracer FLT+FDG PET Tumor
Imaging with Patient Data
D. J. Kadrmas, T. C. Rust, J. M. Hoffman
University of Utah, USA
M22-63 Detection of Spinal Vertebra in 2D and 3D Using Mathematical
Morphology and Polynomial Curve Fitting
W. Ward1, P. H. Lim1, U. Bagci2, L. Bai1
1
University of Nottingham, UK; 2National Institutes of Health, USA
M22-64 Enhanced Whole-body Parametric PET Imaging Using
Statistical Ridge Regression Methods and Correlation-Coefficient
Filtering
N. A. Karakatsanis, M. A. Lodge, H. Mohy-ud-Din, A. K. Tahari, Y. Zhou,
R. L. Wahl, A. Rahmim, Johns Hopkins University, USA
M22-65 Dual Estimation of Activity Maps and Kinetic Parameters for
Dynamic PET Imaging
J. Xu, F. Gao, H. Liu, P. Shi
Rochester Institute of Technology, USA
M22-66 PET Evidence of Academic Achievement Using Voxel-Based
Statistical Analysis Method for Differential Fear Conditioning Rat Model
A. R. Yu1,2, J. S. Kim1, J.-S. Choi3, Y. K. Lee3, H. J. Kim2, S. M. Lim1, K. M.
Kim1
1
Korea Institute of Radiological & Medical Sciences, Republic of Korea; 2Yonsei
University, Republic of Korea; 3Korea University, Republic of Korea
M22-67 Detection of Cardiac Abnormalities from Tagged and Untagged
MRI by Using a Deformable Mesh Model to Estimate Heart Motion
F. M. Parages1, T. S. Denney Jr2, J. G. Brankov1
1
Illinois Institute of Technology, United States; 2Auburn University, United States
M22-68 Generation of 18F-FCWAY PET Standard Brain Template for
SPM Analysis
W. Lee1, K. M. Kim1, T. J. Jeon2, C. H. Lyoo2, J. Y. Choi2, J. G. Kim1, S.-K.
Woo1, J.-A. Park1, B. I. Kim1, Y. H. Ryu2, S. M. Lim1
1
Korea Institute of Radiological & Medical Science, Korea; 2Gangnam Severance
Hospital, College of Medicine, Korea
M22-69 Approximation of Voxel-Level Variances from Spatial-Variances
for Single Scan PET Data
P. J. Markiewicz1,2, J. C. Matthews1, A. J. Reader2
1
University of Manchester, UK; 2McGill University, Canada
M22-70 A Novel Edge Protective Adaptive Filter for High Energy X-Ray
Imaging Technology
Y. Wang, X. Qiu, Y. Li, Tsinghua University, China
M22-71 Data Space Conversion for Tissue Cancellation in Dual Energy
Mammography
S. Han, D.-G. Kang, Y. Sung
Samsung Advanced Institute of Technology, Samsung Electronics, South Korea
266 Saturday - MIC Poster Presentations Notes
Notes
268 Saturday - MIC Poster Presentations Notes
Notes
270 Saturday - MIC Poster Presentations Author Index
Contributions from Collaborations
44DMPET CollaborationM21-23/p.257
AGIPD CollaborationN2-6/p.82
AIDA ConsortiumN14‑213/p.146
Alessandria-Aveiro-Freiburg-Liberec-PragueTorino-Trieste CollaborationN13-6/p.123
Alibava CollaborationN14-215/p.146
ALICE CollaborationN14-155/p.141
N14-211/p.145
AMoRE CollaborationN41-8/p.185
ANTARES and KN3NeT Collaborations
N12-1/p.121
ARGO-YBJ CollaborationN12-3/p.122
ARIANNA CollaborationN19-3/p.158
ATLAS CollaborationN1-181/p.101
N14-208/p.145
N14-212/p.145
N14-225/p.147
N14-226/p.147
N14-227/p.147
N14-228/p.147
N14-229/p.147
N14-230/p.147
N14-231/p.147
N14-232/p.147
N14-239/p.147
N17-1/p.156
N18-3/p.157
N24-3/p.161
N24-6/p.162
N32-1/p.179
N32-2/p.179
N43-7/p.187
N46-3/p.216
N46-7/p.217
ATLAS Forward Physics Collaboration
N17-7/p.157
ATLAS IBL CollaborationN14-210/p.145
ATLAS Liquid Argon Calorimeter Group
N25-7/p.162
ATLAS Tile Calorimeter SystemN14-61/p.133
N14-236/p.147
N19-2/p.158
ATLAS Upgrade Planar Pixel Sensors R&D
Project
N33-4/p.180
BEAMView CollaborationM06-1/p.188
Belle II PID GroupN23-8/p.161
CALICEN14-161/p.141
CALICE CollaborationN14-69/p.134
N14-143/p.140
N14-149/p.140
N14-152/p.140
N35-5/p.181
N35-6/p.181
N35-7/p.181
Calice Collaboration/ILD Concept Collaboration
N14-145/p.140
CLOUD CollaborationN14-151/p.140
N14-147/p.140
N14-163/p.141
N24-1/p.161
N24-4/p.161
N32-3/p.179
N45-5/p.216
CMS ECAL GroupN14-153/p.140
N35-4/p.181
CMS PLT CollaborationN24-5/p.162
CMS Tracker CollaborationN33-5/p.180
COBRAR09-3/p.170
COUPP CollaborationN12-2/p.122
DAMIC CollaborationN14-203/p.145
Daya Bay CollaborationN1-126/p.97
N14-105/p.137
DEAP CollaborationN32-5/p.179
DEPFET CollaborationN14-148/p.140
N29-7/p.177
DSSC ConsortiumN2-4/p.81
EndoTOFPET-US CollaborationJNM-2/p.125
FACT CollaborationN12-4/p.122
FIRST CollaborationN37-5/p.182
FLUKA CollaborationN7-7/p.118
Inter-Experiment Working Group on Radiation
Damage in Silicon DetectorsN33-1/p.179
International Collaboration on Neutron
Detectors / Scintillation Detector Working Group
He-1-4/p.224
KLOE2 experimentN19-7/p.158
LAPPDN1-223/p.104
LCTPC CollaborationN38-4/p.183
N38-5/p.183
LENA projectN1-222/p.104
LHCb CollaborationN17-2/p.156
N17-3/p.156
N46-4/p.217
LHCb Outer Tracker Collaboration
N14-122/p.138
LHCb Silicon Tracker GroupN14-150/p.140
LHCb VELO GroupN18-2/p.157
N33-2/p.179
LHCb VELO Upgrade GroupN24-2/p.161
MAGIC CollaborationN14-50/p.132
MEG Timing Counter GroupN17-4/p.157
Muon Portal CollaborationN1-2/p.87
NA62 CollaborationN13-1/p.122
NA62 RICH Working Group: CERN, INFN
Firenze, INFN PerugiaN45-1/p.216
NIFFTE CollaborationN39-5/p.184
OpenGATE CollaborationM10-23/p.204
PAMELA CollaborationN12-5/p.122
PANDA Cherenkov GroupN17-5/p.157
N20-3/p.158
PANDA CollaborationN19-6/p.158
N32-4/p.179
N35-1/p.181
PANDA Micro-Vertex-Detector Group
N18-4/p.157
pCT CollaborationJNMR-1/p.126
HT-3-8/p.76
M22-21/p.262
PHENIX CollaborationN14-19/p.130
N14-114/p.138
N14-160/p.141
N19-4/p.158
N39-1/p.183
PICSEL Team of IPHC-Strasbourg
N29-8/p.177
PoGOLite CollaborationN36-2/p.181
POLAR CollaborationN36-1/p.181
PRIMA CollaborationR14-1/p.194
PRISMA CollaborationHT-2-7/p.76
RD50 CollaborationN25-1/p.162
RD51 CollaborationN38-7/p.183
REWARD ConsortiumN1-11/p.88
RooStats GroupN14-89/p.136
SuperB Muon Detector GroupN35-8/p.181
TOTEM T2 GroupN13-4/p.122
Ultra-High Rate Germanium Group and Delayed
Gamma CollaborationN1-47/p.90
VERITAS CollaborationN14-235/p.147
ZEUS CollaborationN43-8/p.187
Author Index 271
Contributions from Individuals
A
Aalseth, Craig EN1‑124/p.96
N14‑123/p.138
Aarsvold, John N
M18‑39/p.244
Abascal, Juan Felipe M17‑17/p.238
M18‑77/p.247
Abba, Andrea N14‑109/p.137
N14‑54/p.133
Abbas, Sajid M09‑56/p.200
Abbaszadeh, Shiva N14‑180/p.143
Abbisso, Salvatore N1‑187/p.101
Abdallah, Mahmoud M15‑30/p.228
M21‑35/p.258
Abdoli, Mehrsima M22‑45/p.264
Abdul‑Jabbar, Najeb M
R04‑21/p.107
Abe, Keiichi N14‑129/p.139
Abe, Toshinori N2‑1/p.81
Abe, Yutaka M15‑1/p.226
Abella, Monica M18‑77/p.247
M21‑51/p.260
M17‑17/p.238
Aberg, Daniel R02‑4/p.84
Abidi, Mouadh M05‑6/p.188
Aboagye, Eric M22‑57/p.265
Acevedo, Michael R
M21‑44/p.259
Aceves‑Adan, Eduardo M18‑61/p.246
Achenbach, Patrick N1‑69/p.92
Ackermann, Benjamin HT‑2‑6/p.76
Acosta, Luis N14‑217/p.146
N20‑6/p.159
Adachi, I. N14‑45/p.132
Adachi, Ichiro N1‑217/p.103
N17‑6/p.157
Adams, Aaron R08‑4/p.170
Adams, Ken N1‑54/p.91
Addison, Eric KM18‑50/p.245
Agarwal, Shruti M10‑49/p.206
Agarwal, Siddharth M09‑75/p.201
Agasthya, Greeshma A
M09‑70/p.201
N28‑9/p.165
Agata, Y. R07‑1/p.169
Aghababyan, Arthur N14‑237/p.147
Agodi, Clementina N14‑176/p.142
Aguayo Navarrete, Estanislao N15‑4/p.155
Aguiar, Pablo M09‑53/p.200
Ahangarianabhari, Mahdi N6‑5/p.118
Ahmad, A. N1‑239/p.105
Ahmadian, Alireza M22‑59/p.265
Ahn, Chiwon N1‑74/p.92
Ahn, Il Jun M17‑59/p.241
M17‑45/p.240
Ahn, Sangtae M23‑7/p.255
M19‑5/p.219
Aiello, Sebastiano N14‑165/p.141
N40‑4/p.184
Ait Imando, Tabi M17‑61/p.241
Aiyawar, Vijaya N15‑5/p.155
Akagi, Takashi HT‑4‑4/p.77
Akimoto, Kenta M15‑1/p.226
Akimoto, Ryoji N31‑5/p.178
Akurugoda Gamage, Kelum A
N5‑4/p.117
Alarcon, Juan N14‑64/p.133
Alaribe, Leonard O
N10‑7/p.121
Albanese, Chris M20‑7/p.220
Albers, Michael N20‑2/p.158
Alberti, Roberto N1‑202/p.102
Albrow, Mike GN1‑187/p.101
Alcorta, Martin N20‑2/p.158
Alekhin, Mikhail S
N10‑2/p.120
N10‑1/p.120
Alemayehu, Bemnet N14‑96/p.136
Alessio, Adam MM15‑3/p.226
Alhassen, Fares M16‑51/p.235
M18‑17/p.243
M09‑68/p.201
Alhawsawi, Abdulsalam N14‑96/p.136
Aliaga, Ramon JM16‑42/p.234
N14‑99/p.136
Alimohamadi, Samaneh M22‑59/p.265
Alimov, Svyatoslav He‑1‑5/p.224
Alkhorayef, Mohammed N14‑115/p.138
Allard, Michle M22‑58/p.265
Allec, Nicholas N14‑180/p.143
Allee, David RN1‑71/p.92
Allen, Branden TR05‑5/p.124
R09‑6/p.170
Allen, Raymond J
N42‑5/p.186
Allinson, Nigel M
M15‑37/p.229
M16‑64/p.236
N14‑183/p.143
N37‑3/p.182
Allmendinger, Thomas M18‑48/p.245
Allport, Philip PN25‑4/p.162
Almeida, Andr PM18‑81/p.247
Almeida, Pedro M07‑6/p.190
M15‑56/p.230
M15‑33/p.228
M10‑71/p.208
M09‑15/p.197
Alnowami, Majdi M22‑28/p.262
Aloisio, Alberto N19‑5/p.158
N14‑112/p.137
N14‑94/p.136
N23‑1/p.161
Altapova, Venera R04‑10/p.106
Alvarez Illan, Ignacio M10‑14/p.203
Alvarez Pastor, Jose’ M
R04‑57/p.110
Alvarez, Paula LN14‑141/p.140
N14‑140/p.139
Alves, Eduardo R02‑2/p.84
Alves, Francisco N14‑168/p.142
Amaro Jr, Edson M21‑11/p.256
Amaro, Fernando D
N13‑7/p.123
Ambrosino, Fabio N14‑144/p.140
Ambwani, Sonal M10‑70/p.208
M23‑2/p.255
M15‑49/p.229
M10‑73/p.208
Ameli, Fabrizio N19‑5/p.158
N14‑94/p.136
Amerio, Silvia N32‑6/p.179
Amman, Mark NR01‑6/p.223
N14‑82/p.135
N29‑3/p.177
R03‑3/p.85
Ammendola, Roberto N14‑36/p.131
Amorini, Francesca N20‑6/p.159
N14‑217/p.146
Amselem, Arnaud N23‑5/p.161
An, Lvxing N21‑3/p.159
An, Su Jung M22‑5/p.260
M16‑28/p.233
M22‑4/p.260
Anashkin, Edward 272 Author Index M17‑62/p.241
Anaxagoras, Thalis M15‑37/p.229
N14‑183/p.143
N37‑3/p.182
M16‑64/p.236
Andam, Aba BM18‑50/p.245
Andersen, Flemming L
M10‑68/p.207
Andersen, Ken H
N1‑73/p.92
Anderson, John T
N20‑2/p.158
Anderson, Kevin K
N5‑6/p.117
Anderson, Thomas R
N3‑3/p.82
Andersson, Hans NR01‑1/p.223
Andrade, Cherley B
M18‑81/p.247
Andre, Jacques N1‑130/p.97
Andreev, Cvetan N1‑21/p.88
Andresen, Nord N2‑2/p.81
Andreyev, Andriy M09‑22/p.197
M19‑6/p.219
Andricek, Ladislav N34‑6/p.180
N33‑3/p.179
N14‑148/p.140
Andricek, Ladislaw N40‑3/p.184
Andritschke, Robert N1‑230/p.104
Anevski, Dragi N1‑73/p.92
Angelis, Georgios M18‑8/p.242
M14‑1/p.218
Angelis, Georgios I
M17‑55/p.241
M17‑49/p.240
M15‑14/p.227
M22‑36/p.263
M19‑3/p.219
M17‑31/p.239
M10‑52/p.206
M15‑64/p.231
Angelone, Maurizio R07‑5/p.169
Angelsen, Christian N2‑5/p.82
N2‑3/p.81
Anghel, V.N.P. N1‑30/p.89
Anghel, Vinicus N1‑4/p.87
Annetta, Nicholas N14‑40/p.131
Anokhin, Igor EN37‑7/p.183
Ansorge, Richard M22‑46/p.264
Antaya, Timothy A
N1‑50/p.91
Antilogus, Pierre N14‑51/p.132
Antolak, Arlyn JN42‑4/p.186
N1‑101/p.95
Anton, Jose M22‑56/p.265
Antoniassi, Marcelo M18‑86/p.248
Anton‑Rodriguez, Jose M15‑5/p.226
M15‑14/p.227
Anwand, Wolfgang N20‑7/p.159
Anzalone, Antonino N14‑217/p.146
N20‑6/p.159
Ao, Edwin CM15‑21/p.227
Aoki, Toru R08‑7/p.170
R10‑4/p.171
R04‑43/p.109
Aplin, Steven N46‑5/p.217
Apruzese, John PN1‑42/p.90
N42‑5/p.186
N11‑3/p.121
Arámbula Cosio, Fernando M18‑83/p.248
Ara, Kuniaki M16‑52/p.235
Arai, Naoki N1‑69/p.92
Arai, Yasuo N44‑1/p.215
N1‑193/p.102
N1‑227/p.104
N42‑1/p.186
N36‑4/p.182
Araki, Sakae N14‑1/p.129
Arce, Pedro M16‑46/p.235
Archambault, John Paul N1‑58/p.91
Archer, Dan N11‑7/p.121
Argyrou, Maria M17‑12/p.238
Arino, Gerard M16‑46/p.235
Arita, Yoshinori N23‑8/p.161
Armaingaud, Christopher N38‑6/p.183
Armbruster, Tim N9‑7/p.120
Armitage, John N1‑30/p.89
N1‑4/p.87
Armstrong, Ian M22‑50/p.264
Arpin, Louis M05‑6/p.188
Arridge, Simon R
M22‑35/p.263
M17‑37/p.240
M03‑6/p.167
M08‑3/p.190
M15‑9/p.226
M23‑3/p.255
M04‑6/p.168
M09‑24/p.197
Arthur, Paul RN1‑6/p.87
Asai, Makoto N28‑8/p.165
Aschauer, Florian N14‑117/p.138
Aschauer, Stefan N1‑230/p.104
N1‑228/p.104
Aschenauer, Elke Caroline N14‑220/p.146
Ashby, Joseph N14‑164/p.141
Ashmanskas, Bill M18‑10/p.242
Ashwin, Wagadarikar M18‑25/p.243
Aslam, Ibrahim N1‑58/p.91
Asma, Evren M23‑7/p.255
Aso, Tsukasa N28‑3/p.164
HT‑4‑4/p.77
Aspell, Paul N6‑6/p.118
Aspinall, Michael D
N1‑110/p.95
N1‑62/p.91
Asselin, Marie‑Claude M22‑56/p.265
Assis, Joaquim N14‑78/p.135
Asztalos, Stephen N29‑3/p.177
Atanackovic, Jovica N1‑58/p.91
Athanasiades, Athanasios N1‑98/p.94
N1‑41/p.90
N1‑34/p.89
He‑1‑6/p.224
Attie, David N21‑3/p.159
Aucott, Timothy N8‑6/p.119
N15‑7/p.155
Auditore, Lucrezia N14‑217/p.146
N20‑6/p.159
Auffray, Etiennette JNMR‑2/p.126
M10‑62/p.207
M16‑61/p.236
N28‑2/p.164
N41‑6/p.185
Augustine, Frank N1‑46/p.90
N1‑122/p.96
Auricchio, Natalia R04‑57/p.110
R09‑1/p.170
R14‑2/p.195
Austin, Derek WM15‑16/p.227
Autret, Awen M17‑35/p.239
M17‑14/p.238
Auvray, Vincent M09‑29/p.198
Avigo, Riccardo N1‑118/p.96
Aweda, Tolulope M20‑8/p.220
Axelsson, Jan M15‑24/p.227
M16‑5/p.231
Ay, Mohammad R
M17‑29/p.239
M18‑78/p.247
Ayad, Rachid N1‑239/p.105
Ayaz‑Maierhafer, Birsen N8‑5/p.119
Ayerbe Gayoso, Carlos N1‑69/p.92
Aykac, Mehmet M16‑8/p.232
Ayoub, Mohamed R02‑5/p.84
JMR‑2/p.125
R04‑60/p.110
R13‑5/p.194
R14‑6/p.195
Ayres, Richard M10‑74/p.208
Azevedo, Carlos D
M18‑85/p.248
N13‑7/p.123
N14‑133/p.139
Azmoun, Babek M13‑7/p.218
Azuma, Yoshiharu M18‑53/p.245
M18‑51/p.245
M18‑52/p.245
M18‑54/p.245
Azzellino, Giovanni N45‑7/p.216
B
Baba, Justin SM16‑74/p.237
M15‑66/p.231
Baba, Mamoru M18‑20/p.243
M18‑26/p.243
Baba, Takashi N22‑2/p.160
Babaeizadeh, Saeed M03‑4/p.167
Babalola, Stephen O
R04‑26/p.107
Babentsov, Volodymyr R04‑8/p.106
R16‑2/p.221
R04‑27/p.108
Babla, Hetal M17‑28/p.239
M15‑12/p.227
Baciak, James ER04‑71/p.111
Badawi, Ramsey D
M14‑7/p.219
M10‑39/p.205
M05‑2/p.188
Badikov, V. R12‑5/p.194
Bae, Jaekeon M09‑51/p.199
Bae, Jun‑Hyung N14‑29/p.131
N1‑197/p.102
N1‑195/p.102
N1‑196/p.102
Bae, Seungbin M09‑51/p.199
M16‑43/p.234
Baehr, Alexander N40‑3/p.184
Baek, Cheol‑Ha M16‑28/p.233
M22‑4/p.260
Baesso, Paolo N1‑19/p.88
N8‑2/p.119
Bagagli, Francesco N43‑2/p.186
Bagci, Ulas M22‑63/p.265
Baghaei, Hossain M03‑8/p.167
M21‑30/p.258
Baginski, Mark JN1‑166/p.100
Bagnasco, Stefano N14‑73/p.134
Bagolini, Alvise N1‑182/p.101
N14‑204/p.145
Baharin, Ruzalina M16‑55/p.235
Bahi, Zakaria M17‑35/p.239
Bahri, Mohamed Ali M21‑15/p.257
M21‑18/p.257
Bai, Bing M17‑33/p.239
M21‑8/p.256
M21‑13/p.257
M22‑29/p.263
M19‑2/p.219
Bai, Chuanyong M15‑12/p.227
M17‑28/p.239
M16‑27/p.233
Bai, Li M17‑32/p.239
M22‑63/p.265
Bai, Xiaowei M02‑2/p.166
Bai, Xue N22‑7/p.160
Baiev, Oleksandr U
N14‑79/p.135
Bailey, Alexis N37‑3/p.182
Baker, Mark AR13‑6/p.194
R04‑42/p.109
Baker, Robert R09‑6/p.170
R05‑5/p.124
Bakhous, Christine M22‑34/p.263
Bal, Hashali M18‑90/p.248
Balakrishnan, Ganesh R07‑6/p.169
Balakrishnan, Karthik M04‑4/p.167
Balasse, Laure M21‑16/p.257
Balbuena, Juan Pablo N14‑57/p.133
N14‑58/p.133
R04‑3/p.106
Baldazzi, Giuseppe N6‑5/p.118
Baldini, Wander N35‑8/p.181
Baldisseri, Alberto N24‑7/p.162
Baldock, Clive M21‑47/p.259
Bale, Ben AM16‑74/p.237
Balfour, Daniel M15‑5/p.226
Balkay, Laszlo N14‑182/p.143
M10‑38/p.205
M10‑37/p.205
M21‑27/p.258
M18‑76/p.247
Ball, Robert N31‑7/p.179
Balla, Alessandro N13‑2/p.122
Ballabriga, Rafael N1‑226/p.104
Ballester, Otger N45‑2/p.216
Balta Beylergil, Sinem M10‑46/p.206
Baltay, Charles N14‑201/p.145
Balvage, Duane R
N15‑8/p.155
Bancroft, Christopher M
N1‑26/p.89
N14‑48/p.132
N36‑3/p.181
Bandstra, Mark N15‑7/p.155
Bao, Qinan M10‑40/p.205
Barber, Thomas N25‑3/p.162
Barber, William C
M16‑51/p.235
R01‑2/p.84
JMR‑4/p.125
Barbosa, Fernando N1‑185/p.101
N1‑125/p.96
Bari, Abdul N14‑207/p.145
N14‑92/p.136
Barish, Barry LC1‑2/p.86
Barnes, Samuel R
JNM‑8/p.126
N28‑4/p.164
Barnett, Robert K
M15‑67/p.231
Barnowski, Ross N8‑6/p.119
N1‑52/p.91
N14‑86/p.135
Baron, Alfred QN1‑231/p.104
Baroni, Guido M22‑16/p.261
Barquero, Harold M18‑74/p.247
Barre, Stephane M21‑2/p.256
Barrett, Harrison H
M03‑1/p.166
M18‑43/p.245
M21‑4/p.256
Barrientos, Diego N14‑22/p.130
N14‑5/p.129
Barrillon, Pierre M05‑5/p.188
M16‑45/p.234
Barrio, John M05‑5/p.188
Author Index 273
M16‑62/p.236
M17‑5/p.237
M16‑65/p.236
M16‑45/p.234
Barroso, Regina C
M18‑49/p.245
M18‑81/p.247
Barthelmy, Scott R09‑6/p.170
R05‑5/p.124
Bartling, Sönke M09‑37/p.198
M09‑47/p.199
Bartsch, Valeria N32‑1/p.179
Basaglia, Tullio N46‑8/p.217
Baselice, Fabio M22‑51/p.264
Baselli, Giuseppe M17‑6/p.237
M22‑16/p.261
Bashar, Rezaul M17‑55/p.241
M15‑64/p.231
M10‑52/p.206
Bashkirov, Vladimir A
HT‑3‑2/p.76
N14‑174/p.142
N14‑192/p.144
R04‑24/p.107
M22‑21/p.262
N14‑189/p.144
Basilavecchia, Manuel M22‑20/p.262
Bastieri, Denis N32‑6/p.179
Baszak, Jarosław N1‑148/p.98
N34‑5/p.180
Batcheler, James N15‑5/p.155
Batdorf, Michael T
N15‑8/p.155
Bateman, James E
N21‑1/p.159
Batenburg, K. Joost M22‑38/p.263
Bates, Richard LN25‑2/p.162
N14‑164/p.141
Batič, Matej N14‑240/p.136
N28‑6/p.165
N28‑5/p.165
N14‑65/p.134
N7‑4/p.118
N14‑66/p.134
N7‑3/p.118
N7‑8/p.118
Batigne, Guillaume N24‑7/p.162
Battaglia, Marco HT‑3‑2/p.76
N14‑174/p.142
Battaglia, Maria C
M22‑7/p.260
M22‑6/p.260
M18‑64/p.246
Battistoni, Giuseppe N14‑176/p.142
Bauce, Matteo N32‑6/p.179
Baudot, Jerome JNM‑5/p.126
Bauer, Christopher M10‑76/p.208
Bauer, Julia M22‑16/p.261
Baumann, Tobias N14‑224/p.146
Baumbach, Tilo R04‑9/p.106
R04‑10/p.106
Baumbaugh, Barry W
N1‑213/p.103
Bayat, Mohammad M18‑80/p.247
Bazzacco, Dino N14‑22/p.130
Bea, Jun Hyung N1‑144/p.98
Beach, Shaun EN14‑92/p.136
N14‑207/p.145
Beanlands, Rob S
M15‑44/p.229
Beasley, Kevin N14‑234/p.147
Beaudoin, Jean‑Francois M21‑41/p.259
M21‑33/p.258
Beaumont, Jonathan N1‑102/p.95
Bec, Julien M02‑2/p.166
Becchetti, Frederick D
N5‑8/p.117
Becchetti, Marc F
N1‑95/p.94
N1‑56/p.91
R04‑61/p.110
Beck, Patrick RR12‑5/p.194
R08‑3/p.169
R04‑19/p.107
Beck, Thomas JM09‑8/p.196
Becker, Eric MN15‑8/p.155
N14‑96/p.136
Becker, Julian N4‑7/p.83
Becla, Krzysztof R13‑1/p.194
N1‑136/p.97
N10‑5/p.120
Becla, Piotr N10‑5/p.120
R13‑1/p.194
N1‑136/p.97
Bedell, Andrea N1‑26/p.89
Bednarek, Daniel R. M10‑58/p.206
M17‑41/p.240
M10‑44/p.205
Bednarzik, Martin R04‑55/p.110
Beekman, Freek J
M17‑10/p.238
M15‑48/p.229
M05‑4/p.188
Beeksma, Brad N37‑6/p.182
Beene, James RN31‑7/p.179
Beging, Stefan M15‑47/p.229
Beigbeder, Christophe N6‑4/p.118
Beking, Michael N44‑8/p.215
Belas, Eduard R10‑7/p.171
R04‑70/p.111
R04‑47/p.109
Belcari, Nicola M22‑24/p.262
Bell, Steven JM16‑13/p.232
NR01‑1/p.223
M15‑65/p.231
R04‑38/p.108
R04‑42/p.109
R13‑6/p.194
Bell, Zane WN46‑8/p.217
N28‑6/p.165
He‑2‑1/p.225
N14‑240/p.136
Bellato, Marco N14‑22/p.130
Belley, Matthew D
N14‑90/p.136
Bellinger, Steven L
He‑2‑7/p.225
R12‑7/p.194
N5‑3/p.117
N1‑42/p.90
N1‑97/p.94
Bellini, Fabio N1‑114/p.96
N14‑176/p.142
Bellini, Vincenzo M22‑6/p.260
Bellis, Stephen M13‑2/p.218
Bellisai, Simone N16‑5/p.156
Bellutti, Pierluigi N14‑53/p.132
N45‑8/p.216
Belsky, Andrei N.
N1‑162/p.99
N1‑161/p.99
Belzunce, Martin A
N14‑64/p.133
Ben Attouch, Mohamed Walid M05‑6/p.188
Benassi, Giacomo R13‑3/p.194
R14‑2/p.195
R02‑1/p.84
R09‑1/p.170
R08‑6/p.170
R07‑3/p.169
Bencardino, Raffaele N1‑219/p.103
Bencivenni, Giovanni N13‑2/p.122
N13‑5/p.122
Benetti, Massimiliano R07‑5/p.169
Benetti, Michele N1‑171/p.100
Benhammou, Yan N31‑7/p.179
Benilov, Arthur M22‑20/p.262
Benitez, Victor N14‑158/p.141
Benjamin, Doug 274 Author Index N14‑87/p.135
Benlloch, Jose Maria M09‑46/p.199
M16‑42/p.234
M16‑22/p.233
N1‑194/p.102
Bennati, Paolo M16‑39/p.234
Benoit, Didier M17‑61/p.241
M19‑7/p.220
M17‑39/p.240
M08‑1/p.190
M21‑16/p.257
Benoit, Mathieu M21‑16/p.257
Bensalah, Hakima R02‑2/p.84
R04‑56/p.110
R08‑5/p.170
R04‑36/p.108
Benson, Thomas M09‑21/p.197
Bentefour, E. HN31‑7/p.179
Benton, Eric N1‑96/p.94
Bentourkia, M’hamed M22‑58/p.265
Benz, Arnold R04‑55/p.110
Benz, Jacob MN1‑43/p.90
Beque, Dirk M18‑93/p.248
M18‑67/p.246
Berashevich, Julia R07‑4/p.169
Berenyi, Ervin M10‑77/p.208
Berg, Eric JM16‑35/p.234
Bergamaschi, Anna N2‑8/p.82
Berger, Lutz JNM‑3/p.125
Bergeron, Melanie M05‑7/p.188
Berjillos Morente, Rafael N20‑6/p.159
Berjillos, Rafael N14‑217/p.146
Berker, Yannick M09‑3/p.196
M09‑2/p.196
Bernard, Ethan PN1‑157/p.99
N20‑5/p.159
Berneking, Arne M21‑5/p.256
Bernius, Catrin N14‑225/p.147
Bernstein, Adam N27‑10/p.164
N14‑136/p.139
N27‑4/p.164
N1‑90/p.94
N39‑6/p.184
Berry, James ENR01‑8/p.223
Berry, Kevin DN1‑87/p.94
N1‑81/p.93
Bert, Julien M17‑14/p.238
M08‑1/p.190
M17‑35/p.239
Bertolone, Gregory N44‑4/p.215
Bertuccio, Giuseppe N29‑5/p.177
N6‑5/p.118
R12‑1/p.193
Berubé, Benoit‑Louis N1‑237/p.105
N34‑2/p.180
N40‑2/p.184
Berzano, Dario N14‑73/p.134
Bessiere, Aurlie N26‑6/p.163
Best, David JN1‑166/p.100
Best, Jeremy SN33‑7/p.180
Betancourt, Christopher N25‑3/p.162
Bettarini, Stefano N29‑2/p.177
N44‑6/p.215
Bettinardi, Valentino M10‑28/p.204
M22‑52/p.264
Bettuzzi, Matteo M09‑18/p.197
M21‑3/p.256
Beverina, Luca N45‑7/p.216
Beyer, Thomas M10‑68/p.207
Beylin, David M17‑62/p.241
M20‑7/p.220
Bezrukov, Ilja M11‑7/p.191
M15‑26/p.228
Bhandari, Harish B
N1‑234/p.104
M13‑3/p.218
Bhat, Ishwara R12‑6/p.194
Bhopatkar, Vallary N1‑32/p.89
Bi, Wenyuan N1‑7/p.87
N1‑3/p.87
Biagioni, Andrea N14‑36/p.131
Bian, Junguo M20‑2/p.220
M17‑23/p.239
M17‑22/p.238
Bian, Zhaoying M18‑91/p.248
M18‑92/p.248
Bianchi, Fabrizio N14‑71/p.134
N14‑80/p.135
N14‑72/p.134
N43‑9/p.187
Bianchi, Filippo N14‑98/p.136
Bianco, Laura N4‑7/p.83
Bianco, Simone N18‑4/p.157
Bianda, Michele N12‑7/p.122
Bickley, Abigail A
N1‑24/p.89
N1‑93/p.94
Biebel, Otmar N14‑157/p.141
N13‑3/p.122
Biegun, Aleksandra K
M22‑8/p.261
M06‑3/p.189
M22‑13/p.261
Bieniosek, Matthew F
M21‑42/p.259
Biermanns, Christiane M15‑47/p.229
Bieth, Marie M22‑61/p.265
Biezen, Johannes v
R03‑5/p.85
N1‑163/p.99
Bignan, Gilles N1‑130/p.97
Bilheux, H ZN1‑87/p.94
Binda, Maddalena N45‑7/p.216
Bindley, Glenn R01‑1/p.84
R15‑7/p.221
Biner, Daniel AN10‑2/p.120
N10‑1/p.120
Bingham, Philip N14‑68/p.134
Birch, Jens N21‑8/p.160
N1‑73/p.92
He‑1‑3/p.224
Bircher, Chad JJNM‑4/p.125
M21‑7/p.256
M11‑1/p.191
Birk, Matthias JNM‑3/p.125
Bisogni, Maria Giuseppina M05‑5/p.188
M16‑45/p.234
N14‑24/p.130
M22‑24/p.262
Bitossi, Massimiliano N14‑15/p.130
Bittner, Bernhard N13‑3/p.122
N14‑157/p.141
Bizarri, Gregory A
N10‑4/p.120
N10‑3/p.120
N28‑1/p.164
Bjaalie, Jan M16‑31/p.233
Bjeoumikhov, Aniouar M21‑17/p.257
Black, Andres R08‑5/p.170
R04‑36/p.108
R02‑2/p.84
Blackburn, Brandon W
N11‑4/p.121
Blackie, Douglas N1‑189/p.101
Blackmore, Ewart M22‑3/p.260
Blackston, Matthew A
N8‑5/p.119
Blahuta, Samuel N26‑6/p.163
Blaj, Gabriel N1‑226/p.104
R04‑12/p.107
Blake, Sam JM22‑9/p.261
Blanc, Pauline N41‑5/p.185
Blanpied, Gary SN3‑5/p.82
Blasco Igual, jose M
N14‑5/p.129
Blasi, Nives N1‑119/p.96
N1‑151/p.98
Blinder, Stephan M05‑4/p.188
M22‑3/p.260
Bliss, David N10‑5/p.120
Bliznakova, Kristina M16‑64/p.236
Blondel, Claire R04‑40/p.109
R10‑2/p.171
Bloser, Peter FN1‑26/p.89
N36‑3/p.181
N14‑48/p.132
Blostein, Jeronimo N21‑7/p.160
Blue, Andrew N14‑164/p.141
N2‑5/p.82
Boardman, David N1‑49/p.91
M18‑8/p.242
R10‑6/p.171
Boatner, Lynn AN26‑3/p.163
Bocci, Valerio N19‑5/p.158
N14‑94/p.136
N23‑1/p.161
Bodnar, Igor N14‑63/p.133
Bodnarik, Julia G
N1‑86/p.93
N36‑7/p.182
Boehnen, Chris B
N8‑8/p.119
Boezio, Mirko N12‑5/p.122
Bogart, Greg RN1‑99/p.94
N1‑84/p.93
Boggs, Steven EN14‑49/p.132
N14‑82/p.135
Bognar, Laszlo M10‑77/p.208
Bohm, Christian N14‑118/p.138
N14‑236/p.147
N23‑3/p.161
N14‑237/p.147
Bohm, Ralph N1‑69/p.92
Boiano, Ciro N1‑113/p.96
N14‑111/p.137
N20‑6/p.159
N14‑34/p.131
N14‑217/p.146
N1‑151/p.98
Boisson, Frederic M10‑51/p.206
M21‑31/p.258
M21‑49/p.259
M14‑1/p.218
M18‑8/p.242
Boisvert, Alexandre N34‑2/p.180
N40‑2/p.184
Boisvert, Vronique N14‑228/p.147
Bolding, Simon R
N1‑94/p.94
R12‑7/p.194
Bolle, Erlend M16‑31/p.233
M09‑45/p.199
Bolotnikov, Aleksey E
JNMR‑5/p.126
R04‑27/p.108
R01‑3/p.84
R05‑2/p.124
R08‑4/p.170
R04‑26/p.107
R03‑4/p.85
R02‑3/p.84
R16‑3/p.222
R04‑62/p.110
R11‑2/p.193
R04‑44/p.109
R13‑2/p.194
R04‑8/p.106
Bolshakov, Andrey R04‑29/p.108
Bombelli, Luca N14‑53/p.132
N1‑202/p.102
N14‑54/p.133
N4‑8/p.83
N45‑8/p.216
Bomben, Marco N1‑182/p.101
Bonacorsi, Daniele N43‑3/p.186
N46‑6/p.217
Bonaiuto, Vincenzo N14‑233/p.147
Bonavita, Angelo M
N20‑8/p.159
Bonicalzi, Ricco M
N1‑124/p.96
Bonifacio, Daniel A
M10‑22/p.204
Bonissent, Alain M21‑9/p.256
Bonnin, Christian N39‑2/p.183
Bonte, Julien M19‑7/p.220
M17‑39/p.240
Bonvicini, Giovanni N1‑239/p.105
Booker, Paul N2‑3/p.81
Boone, Kyle N22‑5/p.160
Bopp, Cécile M18‑79/p.247
HT‑4‑3/p.77
Borel, Herve N24‑7/p.162
Borghi, Giacomo JNMR‑7/p.126
Borodina, Olga N1‑69/p.92
Bortfeld, Thomas M22‑23/p.262
Bortolato, Damiano N14‑22/p.130
Boscardin, Maurizio N14‑154/p.140
N14‑53/p.132
N44‑7/p.215
N14‑204/p.145
N1‑182/p.101
N45‑8/p.216
Boshkova, Tatiana N1‑21/p.88
Bosi, Andrea N1‑117/p.96
Bosisio, Luciano N1‑182/p.101
Boston, Andrew J
N8‑3/p.119
Boston, Helen CN8‑3/p.119
Botte, James N1‑30/p.89
N1‑4/p.87
Botvinick, Elias H
M18‑17/p.243
M09‑68/p.201
Bouali, Ines M09‑13/p.197
Boucher, Yvan ANR01‑8/p.223
R14‑3/p.195
Bouckaert, Carmen M21‑14/p.257
Boudjemline, Khalil N1‑30/p.89
N1‑4/p.87
Boulahouache, C. N1‑239/p.105
Bourret‑Courchesne, Edith D
N10‑3/p.120
N10‑4/p.120
N1‑178/p.100
R04‑21/p.107
Boursier, Yannick M08‑1/p.190
M21‑9/p.256
Bousse, Alexandre M22‑35/p.263
M15‑9/p.226
M23‑3/p.255
M04‑6/p.168
M09‑24/p.197
Boussel, Loic M09‑29/p.198
Boutchko, Rostyslav M09‑36/p.198
M21‑35/p.258
Boutet, Sebastien N2‑7/p.82
N1‑238/p.105
Bouton, Chad N14‑40/p.131
Bouvier, Stephane N24‑7/p.162
Bouziri, Haithem M05‑6/p.188
Bowden, Nathaniel s
N27‑10/p.164
N1‑90/p.94
N27‑4/p.164
Bowen, Jason DM18‑27/p.244
Bowen, Stephen R
M15‑3 /p.226
Bowsher, James E
Author Index 275
M18‑35/p.244
Boxall, Colin N1‑13/p.88
Bracco, Angela N1‑151/p.98
N1‑118/p.96
Bradt, Clayton JN14‑207/p.145
N14‑92/p.136
Brady, David N14‑90/p.136
Braga, Joao M21‑24/p.258
Braga, Leo HN14‑167/p.142
N14‑172/p.142
Brambila, Cludia R
N14‑74/p.134
Brambilla, Andrea M10‑5/p.202
Brambilla, Sergio N1‑113/p.96
N39‑2/p.183
N14‑111/p.137
N1‑151/p.98
Brancaccio, Rosa M21‑3/p.256
M09‑18/p.197
Branchini, Paolo N13‑2/p.122
N19‑7/p.158
Brandenburg, Sytze M22‑8/p.261
M06‑3/p.189
Brands, Hartmut N8‑4/p.119
Brankov, Jovan G
M22‑67/p.265
Brasse, David M08‑1/p.190
HT‑4‑3/p.77
M18‑74/p.247
M18‑79/p.247
Brau, James EN35‑3/p.181
N14‑201/p.145
Braverman, Joshua N1‑155/p.99
Bravin, Alberto N14‑195/p.144
Braz, Delson M18‑49/p.245
M18‑81/p.247
Brefczynski‑Lewis, Julie M10‑76/p.208
Brehm, Marcus M09‑37/p.198
M22‑1/p.260
M15‑32/p.228
Breidenbach, Martin N35‑3/p.181
Brendle, Cornelia M15‑26/p.228
Brennan, James N1‑60/p.91
N11‑5/p.121
N1‑59/p.91
Brennan, Kathleen M
M21‑35/p.258
Brenner, Richard N14‑222/p.146
Breskin, Amos N13‑7/p.123
Bressan, Rodrigo A
M21‑11/p.256
Bretin, Florian M21‑18/p.257
M21‑15/p.257
Breton, Dominique N6‑4/p.118
Bretz, Thomas N12‑4/p.122
Brezina, Christoph N38‑4/p.183
Brianzi, Mirko N14‑177/p.143
Brient, Jean‑Claude LC3‑2/p.127
Briggl, Konrad N14‑37/p.131
N16‑6/p.156
Brill, Aaron BM16‑63/p.236
Brillouet, Nicolas M16‑61/p.236
Britton, Charles L
N11‑7/p.121
Brockherde, Werner N34‑3/p.180
Broennimann, Christian N6‑2/p.117
Brons, Stephan JNM‑5/p.126
HT‑2‑6/p.76
Bronzi, D N34‑3/p.180
Brost, Alexander M10‑56/p.206
Brown, Cassarah R
R04‑54/p.110
Brown, James RR02‑5/p.84
Brown, Mark N28‑2/p.164
Brown, Sam WHe‑1‑8/p.224
Brown, Simon N14‑164/p.141
Brown, Steven TR14‑4/p.195
N15‑8/p.155
Brubaker, Erik N27‑4/p.164
N1‑90/p.94
N11‑5/p.121
N1‑14/p.88
Bruckbauer, Thomas M21‑40/p.259
Bruckman de Renstrom, Pawel N24‑3/p.161
Bruer‑Krisch, Elke N14‑195/p.144
Brun, Julie N1‑130/p.97
Brunetti, Riccardo N14‑73/p.134
Bruno, Guerard N21‑6/p.160
Bruschini, Claudio N14‑120/p.138
Bruzzi, Mara M17‑15/p.238
M06‑6/p.189
N14‑177/p.143
N14‑187/p.143
Bryman, Doug N1‑30/p.89
N1‑4/p.87
Brzezinski, Karol N14‑110/p.137
N14‑185/p.143
M21‑28/p.258
Bucci, Joseph N37‑6/p.182
Bucciolini, Marta N14‑177/p.143
M17‑15/p.238
M06‑6/p.189
N14‑187/p.143
Buck, Vimal N14‑40/p.131
Buckley, Steve M21‑32/p.258
Budano, Antonio N13‑2/p.122
Budassi, Michael N43‑5/p.187
M10‑64/p.207
M18‑24/p.243
Budden, Brent SN1‑166/p.100
N1‑164/p.99
Budtz‑Jorgensen, Carl R14‑2/p.195
R04‑57/p.110
Buechele, Maximilian N14‑224/p.146
Bueno, James N1‑30/p.89
N1‑4/p.87
Buerger, Christian M23‑5/p.255
Buether, Florian M17‑60/p.241
Buffet, Jean‑Claude He‑1‑3/p.224
N1‑76/p.93
Bugalho, Ricardo N16‑4/p.156
M15‑29/p.228
M10‑62/p.207
Bugar, Marek R14‑6/p.195
Buis, Camille NR01‑3/p.223
Bukki, Tamas M09‑5/p.196
M21‑29/p.258
Bull, N. DN11‑7/p.121
Burbar, Ziad M15‑31/p.228
M17‑2/p.237
Burdin, Sergey N14‑91/p.136
Burge, Stephen N2‑5/p.82
N2‑3/p.81
Burger, Arnold R08‑3/p.169
Burger, Martin M15‑35/p.228
M15‑43/p.229
Burgett, Eric AN1‑91/p.94
Burggraf, Larry W
N20‑8/p.159
N1‑24/p.89
Burghard, Brion J
N15‑8/p.155
Burns, Jon N1‑8/p.87
Burns, Russell N39‑4/p.184
Burr, Kent CM18‑7/p.242
M18‑6/p.242
N14‑41/p.131
M12‑4/p.192
Busca, Paolo N14‑53/p.132
M22‑20/p.262
276 Author Index N1‑119/p.96
N1‑158/p.99
N14‑54/p.133
N1‑120/p.96
Busnardo, Elena M22‑52/p.264
Butchko, Rostyslav M15‑30/p.228
Butler, Anthony R04‑10/p.106
Butler, Phil R04‑10/p.106
Butsyk, Sergey AN19‑4/p.158
Buttar, Craig N14‑164/p.141
Butterling, Maik N20‑7/p.159
Butzer, Jochen R10‑1/p.171
R04‑10/p.106
Buvat, Irene M17‑39/p.240
M19‑7/p.220
M07‑3/p.189
M08‑1/p.190
Buyens, Fanny M09‑19/p.197
Buzhan, Pavel N22‑4/p.160
Buzug, Thorsten M
M10‑10/p.203
M09‑66/p.201
Byrne, Katherine L
M21‑34/p.258
C
César, Paulo M22‑7/p.260
Cabello, Jorge M05‑5/p.188
M16‑62/p.236
M16‑65/p.236
M17‑5/p.237
M22‑15/p.261
M16‑45/p.234
Caccia, Massimo L
N12‑7/p.122
HT‑3‑5/p.76
Cachovan, Michal M15‑19/p.227
Cadorette, Jules M21‑33/p.258
M21‑41/p.259
Caffrey, Augustine J
N1‑33/p.89
Caffrey, David JN1‑33/p.89
Cahn, Sidney BN20‑5/p.159
Cai, Liang M18‑44/p.245
Cai, Siou‑yin N14‑171/p.142
Cai, Xiao N1‑72/p.92
Calabretta, Luciano N42‑6/p.186
HT‑2‑3/p.75
Caldeira, Liliana L
M09‑15/p.197
Calderini, Giovanni N1‑182/p.101
Calderon, Yonatan M16‑46/p.235
Calestani, Davide R07‑3/p.169
R08‑6/p.170
R13‑3/p.194
Callier, Stephane M16‑65/p.236
N14‑8/p.129
N4‑1/p.83
Calvi, Marta N1‑209/p.103
Camarda, Giuseppe S
R04‑8/p.106
R02‑3/p.84
R03‑4/p.85
R01‑3/p.84
R04‑26/p.107
R04‑62/p.110
R05‑2/p.124
R08‑4/p.170
R11‑2/p.193
R04‑11/p.107
R16‑3/p.222
Camarlinghi, Niccoló M22‑24/p.262
N14‑73/p.134
N43‑2/p.186
Cambraia Lopes, Patricia M22‑8/p.261
M22‑13/p.261
M06‑3/p.189
Camera, Franco N1‑118/p.96
N14‑111/p.137
N1‑151/p.98
N1‑119/p.96
N1‑113/p.96
Campbell, Christopher N20‑2/p.158
Campbell, Desmond L
M10‑50/p.206
Campbell, Joe CN22‑6/p.160
Campbell, Michael N1‑226/p.104
R04‑12/p.107
Canadas, Mario M16‑46/p.235
Cannata, Domenico R07‑5/p.169
Canning, Andrew N10‑4/p.120
Canova, Marcello N5‑5/p.117
Cantrell, Julia AR09‑4/p.170
N1‑201/p.102
Cao, Lei RN42‑2/p.186
N1‑28/p.89
N5‑5/p.117
Cao, Liji M05‑1/p.188
M10‑62/p.207
M15‑29/p.228
Cao, Tuoyu M13‑7/p.218
M10‑64/p.207
N43‑5/p.187
M18‑24/p.243
Capeans, Mar N14‑126/p.138
N14‑127/p.138
N14‑132/p.139
Capek, Martin M22‑47/p.264
Capela, Miguel M18‑64/p.246
M22‑7/p.260
Capodiferro, Manlio N13‑2/p.122
Caponio, Francesco N14‑109/p.137
N14‑54/p.133
Capote, Ricardo M10‑71/p.208
Capra, Stefano N1‑29/p.89
Capussela, Tiziana N14‑144/p.140
Caragiulo, Pietro N1‑237/p.105
N9‑3/p.120
N14‑42/p.132
N14‑43/p.132
Caramelo, Francisco M15‑56/p.230
Carbone, Beatrice N14‑166/p.141
N1‑187/p.101
N1‑111/p.95
Cardella, Giuseppe N20‑6/p.159
N14‑217/p.146
Cardenas, Andres R04‑66/p.111
Cardenas, Edna S
N11‑4/p.121
Cardini, Alessandro N13‑5/p.122
N1‑210/p.103
Cardoso, Bill R16‑1/p.221
N1‑36/p.90
Cardoso, Guilherme N15‑6/p.155
Carette, Michel N1‑130/p.97
Carimatto, Augusto N14‑64/p.133
Carini, Gabriella A
N34‑2/p.180
N1‑238/p.105
N1‑237/p.105
N14‑43/p.132
Carman, Leslie N1‑55/p.91
Carman, M LN1‑105/p.95
Carniti, Paolo N14‑11/p.130
Carolan, Martin N14‑196/p.144
Caroli, Ezio R04‑57/p.110
R14‑2/p.195
R09‑1/p.170
Carpenter, Michael P
N20‑2/p.158
Carr, Alexandre M10‑62/p.207
Carramate, Lara F
N14‑133/p.139
M18‑85/p.248
Carraresi, Luca N14‑217/p.146
Carrire, Philippe N14‑134/p.139
Carson, Richard E
M09‑55/p.200
M19‑1/p.219
M02‑5/p.166
M07‑4/p.189
M15‑36/p.228
M14‑5/p.219
Carter, Jake N11‑7/p.121
Carter, Stephen M22‑56/p.265
Caruso, Anthony N
R12‑7/p.194
N1‑42/p.90
He‑2‑7/p.225
Carvalho, Eduardo E
M21‑24/p.258
Casali, Franco M21‑3/p.256
M09‑18/p.197
Casali, Nicola N1‑114/p.96
Casati, Marta N14‑187/p.143
Casella, Andrew M
N5‑6/p.117
Casey, Michael EN30‑5/p.178
M04‑7/p.168
Casse, Gianluigi N25‑4/p.162
N14‑215/p.146
N14‑164/p.141
Cassese, Antonio N45‑1/p.216
Cassol Brunner, Franca M21‑9/p.256
Cassola, Vagner F
N14‑76/p.135
Castaldini, Antonio R02‑2/p.84
R02‑1/p.84
Castejon, Francisco N14‑70/p.134
Castelo‑Branco, Miguel M15‑56/p.230
Castiglioni, Eduardo R04‑66/p.111
Castiglioni, Isabella M15‑4/p.226
Castiglioni, Jorge R04‑66/p.111
Castoldi, Andrea N40‑6/p.185
N20‑6/p.159
N14‑67/p.134
N14‑217/p.146
M21‑17/p.257
Castruita, Dan R04‑22/p.107
R15‑6/p.221
Catana, Ciprian M02‑4/p.166
Cates, Joshua WN30‑6/p.178
N1‑214/p.103
N29‑6/p.177
Cattadori, Carla N14‑9/p.129
Cattaneo, Marco N14‑75/p.135
Cattaneo, Paolo W
N17‑4/p.157
Caughey, Thomas N1‑55/p.91
Cavaco, Ana M22‑7/p.260
Cavalcoli, Daniela R02‑2/p.84
Cavallaro, Salvatore N42‑6/p.186
HT‑2‑3/p.75
Cavallini, Anna R02‑2/p.84
R02‑1/p.84
Cave, Francis DN1‑62/p.91
Cavicchioli, Costanza N14‑155/p.141
Cavoto, Gianluca N14‑2/p.129
Cazalas, Edward N14‑202/p.145
R12‑3/p.193
Cecilia, Angelica R04‑9/p.106
N10‑7/p.121
R04‑10/p.106
R10‑1/p.171
Celani, Andrea N9‑8/p.120
M22‑20/p.262
Celentano, Giuseppe He‑2‑5/p.225
Celler, Anna M19‑6/p.219
Celona, Luciano HT‑2‑3/p.75
N42‑6/p.186
Cerello, Piergiorgio N43‑2/p.186
N14‑73/p.134
Cerioni, Stefano N13‑2/p.122
Cernik, Robert JM16‑13/p.232
M15‑65/p.231
NR01‑1/p.223
Cervo, Morgan M15‑58/p.230
M10‑45/p.206
Cha, Bo Kyung N1‑224/p.104
M10‑53/p.206
Chaix, Cecile M18‑43/p.245
Chakoumakos, Bryan C
N26‑3/p.163
Challapalli, Amarnath M22‑57/p.265
Chan, Chung M02‑5/p.166
M19‑1/p.219
Chanal, Herve N24‑7/p.162
Chandra, Rico N1‑12/p.88
He‑2‑3/p.225
Chang, Chu‑En N14‑46/p.132
Chang, Fu‑xing N14‑171/p.142
Chang, Ming M09‑27/p.198
M09‑28/p.198
Chang, Tingting M15‑55/p.230
Chang, Wei M18‑19/p.243
M18‑18/p.243
Chang, Wen‑Yuan M16‑33/p.234
Changizi, Vahid M18‑46/p.245
Chao, Tsi‑chian N14‑171/p.142
Chapman, Eric C
N1‑46/p.90
Chapman, J. WN31‑7/p.179
Charbon, Edoardo N14‑120/p.138
N14‑26/p.130
N34‑4/p.180
Charlebois, Serge A.
N34‑2/p.180
N40‑2/p.184
Charles, Evan N1‑30/p.89
N1‑4/p.87
Charles, Laurent N39‑2/p.183
Charlton, Timothy R
N21‑1/p.159
Charon, Yves M17‑61/p.241
Charrue, Pierre N46‑2/p.216
Chatterji, Sudeep N25‑6/p.162
Chatziioannou, Arion F
M11‑2/p.191
M10‑40/p.205
M09‑81/p.201
M09‑80/p.201
Chaudhari, Abhijit J
M14‑7/p.219
M05‑2/p.188
Chaudhuri, Sandeep K
R13‑4/p.194
R07‑2/p.169
Chauveau, Jacques N1‑182/p.101
Chauvie, Stephane N14‑73/p.134
Chauvin, Jean‑Pierre N1‑130/p.97
Chavarrias, Cristina M17‑17/p.238
Chaves Rodriguez, Rosa M
M10‑14/p.203
Chaves, Rosa M22‑44/p.264
Chawla, Amarpreet S
N14‑90/p.136
Chbihi, A. N14‑217/p.146
Chbihi, Abdelouahad N20‑6/p.159
Chechik, Rachel N13‑7/p.123
Cheema, Umber M21‑17/p.257
Chekatt, Hocine M08‑1/p.190
Chen, Anthony M23‑7/p.255
Chen, Augustine E
N14‑171/p.142
Author Index 277
Chen, Cai N1‑80/p.93
Chen, Chin‑Tu N1‑111/p.95
M16‑72/p.237
M09‑62/p.200
M09‑61/p.200
M18‑44/p.245
N14‑166/p.141
M17‑50/p.241
M17‑51/p.241
Chen, Feng R04‑10/p.106
Chen, Henry R01‑1/p.84
R15‑7/p.221
R08‑3/p.169
Chen, Huangshan N1‑1/p.87
Chen, Hucheng N6‑1/p.117
Chen, Jie N1‑96/p.94
Chen, Jing N14‑44/p.132
M10‑18/p.203
M17‑43/p.240
Chen, Junfeng N10‑6/p.120
Chen, Jyh‑cheng M16‑33/p.234
M15‑25/p.228
M16‑30/p.233
Chen, Lidong N10‑6/p.120
Chen, Lihong N1‑216/p.103
Chen, Lin M15‑42/p.229
Chen, Shin‑Yu N1‑57/p.91
Chen, Si M10‑80/p.208
M17‑43/p.240
M10‑59/p.207
Chen, Wan‑Ting M10‑34/p.205
N14‑31/p.131
Chen, Wei N1‑183/p.101
N14‑55/p.133
N14‑206/p.145
Chen, Wufan M18‑91/p.248
M18‑92/p.248
Chen, Xiao Jie N1‑46/p.90
N1‑122/p.96
N22‑6/p.160
Chen, Xiaofeng N41‑7/p.185
Chen, Ximeng R04‑64/p.110
Chen, Xin M16‑2/p.231
Chen, Yong R12‑3/p.193
Chen, Yong PN14‑202/p.145
Chen, Yuanbao M16‑2/p.231
Chen, Yuanbo He‑1‑2/p.224
Chen, Zhiqiang M09‑41/p.199
M09‑26/p.197
M22‑41/p.263
M09‑28/p.198
N1‑3/p.87
N1‑7/p.87
M09‑35/p.198
M18‑71/p.247
M09‑27/p.198
M09‑42/p.199
Cheng, Cui RR04‑2/p.106
Cheng, Jianping N14‑33/p.131
N1‑17/p.88
N1‑1/p.87
M10‑80/p.208
N1‑27/p.89
Cheng, Ju‑Chieh (Kevin) M10‑57/p.206
M09‑20/p.197
Cheng, Lishui M17‑38/p.240
Cheng, Xiaolei N1‑66/p.92
Cheng, Xiaoyin M10‑75/p.208
M09‑48/p.199
Cheng‑Liao, Jinxiu M09‑39/p.198
Cherepy, Nerine N26‑4/p.163
N41‑3/p.185
Cherlin, Alex JMR‑2/p.125
Cherlin, Alexander R13‑5/p.194
Cherry, Simon RM21‑32/p.258
M21‑45/p.259
M21‑34/p.258
M10‑39/p.205
M09‑79/p.201
M03‑2/p.167
M02‑2/p.166
Cherukuri, Chaitanya N9‑8/p.120
Chesi, Enrico M21‑28/p.258
N14‑110/p.137
N14‑185/p.143
Cheung, Chin LN1‑108/p.95
Cheze‑Le‑Rest, Catherine M23‑5/p.255
Chiara, Christopher J
N20‑2/p.158
Chiasson, Stephanie M15‑60/p.230
Chiba, Teppei N22‑7/p.160
Chichester, David L
N1‑92/p.94
N15‑3/p.155
N1‑128/p.97
N1‑174/p.100
N14‑77/p.135
N11‑1/p.121
Chien, Simon M03‑4/p.167
Childers, Taylor N32‑2/p.179
N14‑230/p.147
N14‑227/p.147
Childres, Isaac R12‑3/p.193
N14‑202/p.145
Chin, Mary PN14‑115/p.138
Chinh, Vu M18‑11/p.242
Chinn, Garry M09‑63/p.200
Chiodi, Giacomo N19‑5/p.158
Chiodini, Gabriele N40‑4/p.184
Chipaux, Remi N28‑2/p.164
Chivers, Daniel H
N1‑48/p.90
N1‑221/p.103
N3‑7/p.82
N15‑7/p.155
Chmeissani, Mokhtar M16‑46/p.235
N16‑3/p.156
Cho, Eunae R02‑4/p.84
Cho, Gyu seok M16‑69/p.236
Cho, Gyuseong N1‑144/p.98
N1‑195/p.102
N1‑196/p.102
N14‑29/p.131
N1‑74/p.92
N1‑197/p.102
Cho, Hyo Min M10‑55/p.206
Cho, Hyo‑Min M16‑47/p.235
JMR‑1/p.125
M16‑10/p.232
Cho, Kyungil M18‑84/p.248
Cho, Minsik N1‑197/p.102
N1‑144/p.98
N1‑196/p.102
N14‑29/p.131
Cho, Seungryong M09‑56/p.200
M09‑52/p.199
M18‑68/p.246
M22‑12/p.261
Cho, Steve JNMR‑5/p.126
Cho, Sung Ho R04‑68/p.111
Cho, Sungkoo M22‑19/p.262
M22‑12/p.261
Cho, Zang Hee M18‑36/p.244
M18‑37/p.244
Choe, Hyeok‑jun M10‑78/p.208
Choi, Hwang Ho M09‑67/p.201
Choi, Hyo Jeong R04‑33/p.108
R04‑35/p.108
R04‑34/p.108
Choi, Jai Yong M22‑68/p.265
Choi, June‑Seek M22‑66/p.265
Choi, Kerkil M18‑89/p.248
Choi, Yong M18‑15/p.243
M18‑14/p.243
M18‑13/p.243
M10‑78/p.208
M09‑84/p.202
Choi, Yu‑Na M10‑55/p.206
M16‑47/p.235
JMR‑1/p.125
M16‑10/p.232
Choong, Woong‑Seng M09‑62/p.200
N1‑212/p.103
278 Author Index M18‑11/p.242
Chou, Cheng‑Ying M17‑50/p.241
M17‑44/p.240
M17‑51/p.241
Chou, Hung‑Yi M17‑51/p.241
Chou, Hwai‑Pwu N1‑57/p.91
N14‑13/p.130
N14‑12/p.130
Chourasiya, Ghanshyam
N40‑8/p.185
Chowdhury, Shirazul N15‑5/p.155
Christian, James N1‑96/p.94
N1‑38/p.90
Christian, James F
N1‑46/p.90
N22‑6/p.160
Christophersen, Marc N14‑198/p.144
N18‑7/p.157
Chu, Jiyang M09‑42/p.199
Chu, Ming‑lee N14‑171/p.142
Chun, Se Young M17‑3/p.237
M17‑24/p.239
Chung, Kwangzoo M22‑19/p.262
M22‑12/p.261
Chung, MingHsien N14‑12/p.130
Chung, Yong Hyun M22‑5/p.260
M15‑51/p.230
M16‑28/p.233
M22‑4/p.260
M16‑43/p.234
M09‑51/p.199
Churilov, Alexei R03‑3/p.85
R12‑2/p.193
R03‑2/p.85
Ciambrone, Paolo N13‑2/p.122
Ciampi, Guido R03‑3/p.85
R03‑2/p.85
Ciaschini, Vincenzo N43‑9/p.187
N14‑71/p.134
N14‑72/p.134
N14‑80/p.135
Ciciriello, Fabio N14‑24/p.130
Ciemala, Michal N39‑2/p.183
Cindro, Vladimir N14‑110/p.137
N14‑185/p.143
Cinti, Maria Nerina M16‑39/p.234
Cirignano, Leonard R04‑19/p.107
R04‑13/p.107
R11‑3/p.193
R03‑4/p.85
R03‑2/p.85
R12‑5/p.194
R03‑3/p.85
Cirrone, Giuseppe Antonio P
N14‑176/p.142
M17‑15/p.238
M22‑24/p.262
N14‑177/p.143
M06‑6/p.189
N40‑4/p.184
N14‑165/p.141
N42‑6/p.186
HT‑2‑3/p.75
Cisbani, Evaristo M22‑6/p.260
Civinini, Carlo M17‑15/p.238
N14‑177/p.143
M06‑6/p.189
Clajus, Martin R15‑6/p.221
R04‑22/p.107
R05‑3/p.124
Claps, Gerardo N21‑4/p.159
He‑2‑5/p.225
Clark, John WM15‑55/p.230
Clark, Philip N46‑3/p.216
N43‑7/p.187
Clark, Steve N14‑6/p.129
Clarke, Shaun DN14‑77/p.135
N23‑2/p.161
N1‑92/p.94
N14‑81/p.135
N5‑8/p.117
N1‑56/p.91
N15‑2/p.155
N1‑95/p.94
N1‑50/p.91
Claus, Gilles N44‑4/p.215
Claus, Liam DN1‑99/p.94
N1‑84/p.93
Clemencic, Marco N14‑75/p.135
Clemens, Jean‑Claude M21‑16/p.257
M21‑9/p.256
Clemens, Uwe N1‑68/p.92
Clemett, Ceri DN1‑5/p.87
N1‑16/p.88
Clerk‑Lamalice, Julien M05‑7/p.188
Clinthorne, Neal H. M21‑28/p.258
N14‑185/p.143
N14‑110/p.137
Clinton, Justin R12‑6/p.194
Clonts, Lloyd GN1‑100/p.95
N1‑81/p.93
Cloquet, Christophe M09‑17/p.197
Co, Anne N5‑5/p.117
Cochran, Eric N14‑110/p.137
Coelli, Simone N1‑151/p.98
Coffer, Amy BN1‑221/p.103
N1‑220/p.103
Cola, Adriano R09‑7/p.170
Colafranceschi, Stefano N14‑137/p.139
Colaresi, James N14‑207/p.145
Colarieti‑Tosti, Massimiliano M10‑20/p.204
M10‑19/p.204
M18‑5/p.242
N14‑182/p.143
Colas, Paul N21‑3/p.159
Cole, Andrew He‑2‑6/p.225
Cole, Brian N14‑220/p.146
Coleman, Jonathon N14‑136/p.139
N39‑6/p.184
Colilli, Stefano M10‑60/p.207
Colin, Jean HT‑4‑3/p.77
M18‑79/p.247
Collamati, Francesco N14‑176/p.142
Collar, Juan IN12‑2/p.122
Collins, John CHe‑2‑1/p.225
Collins, Paula N33‑1/p.179
N24‑2/p.161
N14‑216/p.146
Colom, Ricardo J
N14‑99/p.136
M16‑42/p.234
Commichau, Volker R04‑55/p.110
Commisso, Robert J
N11‑2/p.121
N1‑42/p.90
N42‑5/p.186
He‑2‑7/p.225
N11‑3/p.121
Comtat, Claude M15‑28/p.228
M08‑2/p.190
M17‑19/p.238
Conceicao, Andre L
M18‑86/p.248
Conceicao, Raquel C
M10‑71/p.208
Conde, Pablo N1‑194/p.102
M16‑22/p.233
M09‑46/p.199
Condorelli, Giovanni N14‑166/p.141
N1‑111/p.95
Conforti di Lorenzo, Selma N4‑1/p.83
Connors, Benjamin J
N1‑91/p.94
Contarato, Devis N2‑2/p.81
N23‑7/p.161
N44‑5/p.215
Conte, Gennaro R04‑29/p.108
Conti, Maurizio M15‑31/p.228
M08‑6/p.190
M16‑8/p.232
Conti, Peter SM22‑29/p.263
M21‑13/p.257
Conway, Adam M
R12‑5/p.194
R04‑19/p.107
N1‑108/p.95
R08‑3/p.169
Conway, Damian M22‑32/p.263
Conwell, Richard M15‑12/p.227
M17‑28/p.239
M16‑27/p.233
Cook, William R09‑6/p.170
Cooke, Steven M10‑3/p.202
Cooper, Brian WR12‑7/p.194
He‑2‑7/p.225
Cooper, Daniel A
N15‑5/p.155
Cooper, Ren JN3‑7/p.82
Cooper, Reynold N15‑7/p.155
N1‑48/p.90
Cootes, Tim FM07‑8/p.190
M22‑50/p.264
Corbeil‑Therrien, Audrey N40‑2/p.184
N34‑2/p.180
Corde, Stephanie N37‑6/p.182
Cordier, Bertrand R04‑40/p.109
Corradi, Giovanni N14‑144/p.140
Correa, Jonathan He‑1‑3/p.224
N1‑76/p.93
Correcher, Carlos M09‑46/p.199
Corregidor, Vitoria R02‑2/p.84
Corsi, Francesco N14‑24/p.130
Corti, Gloria N46‑4/p.217
Cortina, Eduardo N14‑141/p.140
N14‑140/p.139
Corvo, Marco N14‑71/p.134
N14‑80/p.135
N43‑9/p.187
N14‑72/p.134
Cosentino, Luigi M16‑11/p.232
M10‑60/p.207
Costales, James N15‑5/p.155
Cot, Albert M09‑53/p.200
Cottitto, Juliano M15‑15/p.227
Couceiro, Miguel M09‑54/p.200
M10‑32/p.204
Coudray, Paul M16‑61/p.236
Coughlan, John N2‑5/p.82
Coughlin, Jennifer M07‑5/p.189
Cousins, Tom N1‑30/p.89
N1‑4/p.87
Coutrakon, George N14‑189/p.144
Couture, Aaron JN1‑164/p.99
Cowan, Thomas E
N20‑7/p.159
Cozzini, Cristina N1‑23/p.89
M18‑93/p.248
M18‑67/p.246
Crawford, Martin J
N7‑5/p.118
Crepaldi, Marco N14‑184/p.143
Crespi, Fabio Celso Luigi N1‑151/p.98
N1‑118/p.96
Crespo, Paulo M21‑12/p.257
M22‑13/p.261
M18‑64/p.246
M10‑32/p.204
M09‑54/p.200
M22‑7/p.260
N14‑168/p.142
M22‑6/p.260
Cress, Cory DN33‑7/p.180
Cresswell, John R
N8‑3/p.119
Crider, Benjamin P
N14‑100/p.137
Cristina, Pugliatti N14‑165/p.141
Cristobal, Gabriel M17‑27/p.239
Crocco, Jerome R04‑56/p.110
R02‑2/p.84
R08‑5/p.170
R04‑36/p.108
Cromaz, Mario N20‑2/p.158
Cronholm, L. Marie N1‑110/p.95
N3‑2/p.82
Cronin, Michael M22‑31/p.263
Crow, M LN1‑81/p.93
N1‑87/p.94
Csatlos, Margit N1‑151/p.98
Csebfalvi, Balazs M09‑5/p.196
Cucciati, Giacomo M10‑62/p.207
N28‑2/p.164
Cuciuc, Mihai N14‑61/p.133
Cui, Jingyu M17‑25/p.239
Cui, Xingzhu R04‑37/p.108
Cui, Y R16‑3/p.222
Cui, Yonggang R05‑2/p.124
R03‑4/p.85
R04‑62/p.110
R04‑8/p.106
R11‑2/p.193
R04‑11/p.107
R02‑3/p.84
R01‑3/p.84
JNMR‑5/p.126
Cullen, Ashley N14‑195/p.144
Cummings, Jane N14‑239/p.147
Cunningham, Ian A
R04‑48/p.109
M10‑24/p.204
M10‑13/p.203
M10‑12/p.203
Cuplov, Vesna M08‑1/p.190
M10‑23/p.204
Curado da Silva, Rui M
R04‑57/p.110
Curtarolo, Stefano N30‑3/p.178
Cusanno, Francesco M16‑11/p.232
M10‑60/p.207
Cussans, David N1‑19/p.88
N8‑2/p.119
Cussol, Daniel M18‑79/p.247
HT‑4‑3/p.77
Cussonneau, Jean‑Pierre N14‑31/p.131
M10‑34/p.205
Custelcean, Radu N26‑3/p.163
Cutajar, Dean N37‑6/p.182
Cutler, Cathy M20‑8/p.220
Cuttone, Giacomo M
M06‑6/p.189
N14‑176/p.142
N14‑177/p.143
N42‑6/p.186
M17‑15/p.238
HT‑2‑3/p.75
M22‑24/p.262
N40‑4/p.184
Czarnacki, Wiesław N34‑5/p.180
Czermak, Adam N39‑2/p.183
d
Dědič, Vaclav R08‑1/p.169
R10‑7/p.171
R04‑70/p.111
Da Ponte, Elias N14‑64/p.133
Author Index 279
Da Silva, Angela J
M15‑8/p.226
da Silva, Augusto M
M18‑85/p.248
da Silva, Nuno AM07‑6/p.190
Da Via, Cinzia N14‑154/p.140
N1‑233/p.104
N44‑7/p.215
Dabbs, Ben N8‑5/p.119
Dafinei, Ioan N1‑114/p.96
N33‑6/p.180
Dagliyan, Grant M21‑13/p.257
Dahal, Rajendra R12‑6/p.194
Dahlbom, Magnus M17‑63/p.241
M21‑13/p.257
M17‑26/p.239
Dahoumane, Mokrane N16‑2/p.156
Dai, ErPeng N14‑93/p.136
Dai, Ruibin M15‑62/p.230
Dai, Shu‑jhen N14‑171/p.142
Dai, Tiantian M21‑33/p.258
M10‑58/p.206
M17‑41/p.240
M10‑44/p.205
Daito, Izuru N1‑18/p.88
Dalgliesh, Robert N21‑1/p.159
Dalhbom, Magnus M10‑39/p.205
Dalla Betta, Gian‑Franco N44‑7/p.215
N14‑204/p.145
N1‑117/p.96
N1‑171/p.100
N14‑154/p.140
Dalla Torre, Silvia N14‑135/p.139
N13‑6/p.123
Dallmann, Nicholas A
N1‑166/p.100
Daly, Linda M22‑32/p.263
Dambacher, Markus R04‑3/p.106
R09‑2/p.170
R04‑53/p.110
R04‑39/p.108
R14‑5/p.195
D’Amico, Antonio N14‑94/p.136
D’Andragora, Alessio N1‑183/p.101
N6‑3/p.118
Danielsson, Hans N13‑1/p.122
Danon, Yaron R12‑6/p.194
Dao, He N14‑97/p.136
Dapp, Robin JNM‑3/p.125
Dar, Mushtaq AN1‑108/p.95
Darambara, Dimitra G
R15‑3/p.221
M10‑65/p.207
JMR‑2/p.125
Darbo, Giovanni N14‑154/p.140
N44‑7/p.215
Dasari, Paul M03‑4/p.167
M15‑53/p.230
M15‑54/p.230
Dasgupta, Shuddha S
N14‑135/p.139
Dathy, Corinne N1‑166/p.100
Daugherity, Michael S
N14‑160/p.141
Dauksta, E R04‑56/p.110
D’Auria, Saverio N18‑6/p.157
Dauvergne, Denis
HT‑2‑5/p.75
N16‑2/p.156
M22‑10/p.261
M18‑58/p.246
JNM‑5/p.126
M10‑9/p.203
Davatz, Giovanna He‑2‑3/p.225
N1‑12/p.88
David, Helena M
N20‑2/p.158
Davidson, Zoey S
M18‑10/p.242
Davis, Jeremy N14‑193/p.144
Davis, John FN11‑2/p.121
Dawood, Mohammad M21‑21/p.257
Day, Anthony RN14‑123/p.138
Dazeley, Steven N1‑90/p.94
N27‑4/p.164
De Bernardi, Elisabetta M17‑6/p.237
M22‑16/p.261
De Buck, Stijn M19‑8/p.220
de Faria, Luiz ON1‑123/p.96
De Filippo, Enrico N20‑6/p.159
N14‑217/p.146
De Gaspari, Massimiliano N6‑6/p.118
De Geronimo, Gianluigi N6‑8/p.118
N1‑183/p.101
N14‑55/p.133
N6‑1/p.117
N6‑3/p.118
JNMR‑5/p.126
R05‑2/p.124
R04‑7/p.106
De Guio, Federico N14‑147/p.140
de la Fuente, Francisco M09‑58/p.200
De La Taille, Christophe LC4‑2/p.127
M05‑5/p.188
M16‑45/p.234
M16‑65/p.236
N14‑8/p.129
N4‑1/p.83
De Leo, Raffaele M16‑11/p.232
M10‑60/p.207
De Lorenzo, Gianluca N16‑3/p.156
M16‑46/p.235
De Lucia, Erika N13‑2/p.122
N14‑176/p.142
De Lurgio, Patrick N1‑184/p.101
N23‑4/p.161
De Man, Bruno M09‑21/p.197
M09‑1/p.196
M18‑89/p.248
De Matteis, Marcello N14‑11/p.130
de Molina, Claudia M21‑51/p.260
De Napoli, Marzio N14‑176/p.142
N40‑4/p.184
de Notaristefani, Francesco M22‑17/p.262
M16‑39/p.234
De Nunzio, Giorgio N14‑73/p.134
de Oliveira, Rui N14‑133/p.139
De Robertis, Giuseppe N13‑2/p.122
De Rydt, Marieke JNM‑5/p.126
M10‑9/p.203
M22‑10/p.261
De Vincentis, Giuseppe M16‑39/p.234
deAlmeida, Carlos E
M18‑81/p.247
Debarbieux, Franck M21‑9/p.256
Debatin, Maurice M09‑6/p.196
Debenjak, Luka N1‑69/p.92
Decman, Dan R09‑4/p.170
DeCrescenzo, Giovanni R07‑4/p.169
Dedes, Georges M22‑10/p.261
JNM‑5/p.126
Dedes, Georgios M18‑58/p.246
M10‑9/p.203
Deen, Jamal M13‑1/p.218
Deermann, Dariusch N14‑219/p.146
Defendi, Ilario N21‑6/p.160
280 Author Index Defrise, Michel M09‑16/p.197
M04‑1/p.167
M04‑7/p.168
M09‑17/p.197
Degenhardt, Carsten M12‑2/p.192
Degerli, Yavuz N44‑4/p.215
N24‑7/p.162
deKemp, Robert A
M15‑44/p.229
Del Guerra, Alberto M22‑24/p.262
M16‑45/p.234
M05‑5/p.188
N14‑24/p.130
Del Prete, Domenico N43‑9/p.187
N14‑80/p.135
N14‑71/p.134
Del Sordo, Stefano R14‑2/p.195
R04‑57/p.110
Delagnes, Eric N14‑31/p.131
Delagrange, Hugues M10‑34/p.205
Della Frera, Adriano N16‑5/p.156
Della Volpe, Domenico N14‑112/p.137
Delprete, Domenico N14‑72/p.134
Delso, Gaspar M10‑70/p.208
DeMarchi, Danilo N14‑184/p.143
Demarteau, Marcel LC3‑5/p.127
Dendooven, Peter HT‑3‑1/p.76
M06‑3/p.189
M22‑13/p.261
M22‑8/p.261
Denes, Peter N2‑2/p.81
N23‑7/p.161
N44‑1/p.215
N44‑5/p.215
N6‑7/p.118
Deng, Junjun M18‑59/p.246
M21‑40/p.259
Deng, Li N14‑169/p.142
M09‑7/p.196
Deng, Shiming M22‑10/p.261
Deng, Xiao M21‑41/p.259
M10‑58/p.206
M17‑41/p.240
M21‑33/p.258
M10‑44/p.205
Deng, Zhi N1‑27/p.89
N4‑6/p.83
N14‑44/p.132
N1‑66/p.92
N14‑16/p.130
R04‑2/p.106
N14‑238/p.147
N14‑33/p.131
N16‑8/p.156
Dennerlein, Frank M09‑43/p.199
M15‑6/p.226
M17‑53/p.241
Denney Jr, Thomas S
M22‑67/p.265
Densmore, Adam R15‑7/p.221
R01‑1/p.84
Denyak, Valeriy N14‑78/p.135
Depauw, Nicolas HT‑4‑2/p.77
Deprez, Karel M16‑20/p.233
Deptuch, Grzegorz W
N14‑205/p.145
N9‑5/p.120
Derenzo, Stephen E
N1‑178/p.100
N10‑4/p.120
DeRosa, Maria N44‑8/p.215
Dersch, Uwe M16‑12/p.232
Dervan, Paul N14‑164/p.141
N25‑4/p.162
Derzon, Dora KN11‑5/p.121
N1‑99/p.94
N1‑84/p.93
Derzon, Mark SN11‑5/p.121
N1‑84/p.93
N1‑99/p.94
Desaulniers Lamy, Etienne N40‑2/p.184
Desco, Manuel M21‑51/p.260
M17‑7/p.237
M18‑77/p.247
M17‑17/p.238
Destefano, Nicholas E
N20‑5/p.159
Detwiler, Rebecca S
N3‑6/p.82
Deuerling‑Zheng, Yu M09‑9/p.196
DeVolpi, Alexander N27‑6/p.164
Dewaraja, Yuni K
M17‑24/p.239
DeWitt, Joel M09‑78/p.201
Dey, Joyoni M03‑4/p.167
M10‑49/p.206
M17‑58/p.241
M14‑4/p.219
Dey, Samrat M18‑40/p.244
M18‑45/p.245
Di Domenico, Antonio N13‑2/p.122
N14‑176/p.142
Di Filippo, Domenico N14‑144/p.140
Di Girgoli, Giuseppe M15‑4/p.226
Di Pietrantonio, Fabio R07‑5/p.169
Di Ruzza, Benedetto N14‑220/p.146
Di Simone, Alessandro N14‑80/p.135
Di Simone, Andrea N14‑71/p.134
N43‑9/p.187
N14‑72/p.134
Di Vara, Nicolas N28‑2/p.164
M10‑62/p.207
Di, Kun M02‑2/p.166
M21‑32/p.258
M09‑79/p.201
Dias, Marta FHT‑4‑2/p.77
Dias, Mauro SN1‑121/p.96
Diawara, Yacouba N1‑87/p.94
N1‑100/p.95
N1‑81/p.93
Diaz, Oliver N14‑183/p.143
M16‑21/p.233
Diblen, Faruk M22‑15/p.261
M22‑22/p.262
M06‑5/p.189
M06‑3/p.189
Dieguez, Ernesto R04‑56/p.110
R02‑2/p.84
R04‑36/p.108
R08‑5/p.170
Diehl, Edward N14‑231/p.147
Diemoz, Paul CM22‑24/p.262
Dierckx, Rudi AM22‑45/p.264
Dierre, Fabrice R04‑36/p.108
Dietzinger, Christoph N45‑3/p.216
N45‑4/p.216
Diez Cornell, Sergio N24‑6/p.162
DiFilippo, Frank P
M21‑8/p.256
Dimitrova, Ivelina S
N1‑112/p.95
M22‑37/p.263
N1‑115/p.96
Dinapoli, Roberto N2‑8/p.82
N4‑7/p.83
Dinelle, Katherine M05‑4/p.188
M22‑3/p.260
Ding, Dongzhou N1‑138/p.97
DINU, Nicoletta M17‑61/p.241
Dion, Michael PN36‑7/p.182
Dirks, Rebecca M23‑8/p.255
Disch, Christian R04‑3/p.106
R04‑39/p.108
R04‑53/p.110
R09‑2/p.170
R14‑5/p.195
Dissertori, Gnther N1‑133/p.97
Distler, Michael O
N1‑69/p.92
Djurcic, Zelimir N23‑4/p.161
Dobai, Jozsef GM10‑77/p.208
Dobos, Daniel N14‑212/p.145
N14‑216/p.146
Doering, Dionisio N23‑7/p.161
N2‑2/p.81
N20‑2/p.158
N44‑5/p.215
Doherty, D tN20‑2/p.158
Doi, Tomoka M18‑52/p.245
M18‑53/p.245
M18‑54/p.245
M18‑51/p.245
Doke, Tadayoshi N37‑8/p.183
Dokhale, Purushottam M21‑45/p.259
M09‑79/p.201
M02‑2/p.166
Doki, Takahiro R04‑30/p.108
Dolan, Jennifer L
N1‑92/p.94
N14‑77/p.135
Dolenec, Rok N14‑45/p.132
N17‑6/p.157
Dolinsky, Sergei M16‑36/p.234
Domenici, Danilo N13‑2/p.122
Donahue, Cornelius N1‑77/p.93
Donai, Takanori M16‑18/p.232
Donath, Tilman N6‑2/p.117
Donati, Modeste R10‑2/p.171
Dong, Hai N14‑188/p.144
Dong, Jing N13‑2/p.122
Dong, Yun M15‑38/p.229
M17‑50/p.241
Donnard, Jerome M10‑34/p.205
N14‑31/p.131
Donvito, Giacinto N14‑72/p.134
N14‑80/p.135
N43‑9/p.187
N14‑71/p.134
Doonan, Kate N14‑164/p.141
Dorenbos, Pieter N10‑2/p.120
N1‑154/p.99
N10‑1/p.120
N1‑163/p.99
Dorholt, Ole M16‑31/p.233
Dormand, Jamie N8‑3/p.119
Dorn, Markus N16‑6/p.156
Dorogov, Pjotr R04‑32/p.108
Dorokhov, Andrei N44‑4/p.215
Doroud, Katayoun M16‑61/p.236
Dorscheid, Ralf M12‑2/p.192
Dorvaux, Olivier N39‑2/p.183
dos Santos, Joaquim M
N1‑205/p.102
N13‑7/p.123
N1‑200/p.102
Douek, Philippe M09‑29/p.198
Downes, Simon N37‑6/p.182
Dozono, Masanori N31‑5/p.178
Drabo, Mebougna L
R08‑4/p.170
R04‑26/p.107
Dragone, Angelo N35‑3/p.181
N1‑238/p.105
N14‑42/p.132
N9‑3/p.120
N14‑43/p.132
N2‑7/p.82
N1‑237/p.105
Drake, Gary N23‑4/p.161
N14‑159/p.141
N1‑184/p.101
Dremlyuzhenko, Sergii R04‑46/p.109
Dressendorfer, Paul V
N46‑8/p.217
Driewer, Adrian N25‑3/p.162
Drouet, Sebastien N6‑4/p.118
Drumm, Clif N7‑6/p.118
Drury, Owen R12‑5/p.194
N26‑4/p.163
Du, Huini M18‑7/p.242
M12‑4/p.192
Du, Junwei M09‑79/p.201
M21‑32/p.258
M21‑45/p.259
Du, Qiang N14‑106/p.137
N14‑3/p.129
Du, Yong M15‑50/p.230
M10‑36/p.205
Duan, Chen M16‑56/p.235
Duarte Pinto, Serge N14‑134/p.139
Duarte, Diana DM16‑13/p.232
Dubbert, Joerg N13‑3/p.122
N14‑157/p.141
Dubeau, Jacques N1‑58/p.91
Dubos, Sebastien R04‑40/p.109
Dubrawski, Artur N1‑37/p.90
N1‑15/p.88
N1‑31/p.89
Duda, Brian N2‑7/p.82
N1‑236/p.105
Duenas Diaz, Jose’ A
N20‑6/p.159
Duenas, Jose AN14‑217/p.146
Dueppenbecker, Peter Michael M12‑1/p.191
M02‑3/p.166
M18‑2/p.242
M18‑3/p.242
Duff, Craig HR04‑16/p.107
Duffin, Susan N39‑4/p.184
Dughie, Erin MJMR‑6/p.125
Duh, Ting‑shien N14‑171/p.142
Dujardin, Christophe N1‑161/p.99
N41‑6/p.185
Dulinski, Wojciech N44‑4/p.215
Dulucq, Frederic N14‑8/p.129
N4‑1/p.83
Dumaye, Luc R10‑2/p.171
Dupont, Mathieu M21‑9/p.256
Durini, Daniel N34‑3/p.180
Durkee, Joe WN7‑1/p.118
Durko, Heather L
M21‑4/p.256
Durrant, Ray R05‑4/p.124
Dutta, Joyita M04‑5/p.167
Duval, Marie‑Alix M17‑61/p.241
Duval, Samuel M10‑34/p.205
N14‑31/p.131
Duvauchelle, Philippe R09‑5/p.170
Duxbury, Dominic M
N21‑2/p.159
N21‑1/p.159
N1‑61/p.91
Dwivedi, Shekhar M15‑8/p.226
Dyachenko, Liliya R04‑44/p.109
Dzahini, Daniel N14‑39/p.131
e
Author Index 281
Eary, Janet FM15‑2/p.226
Eberhardt, John E
N1‑219/p.103
Ebisawa, Toru N1‑103/p.95
Eckhart, Fretwurst N4‑7/p.83
Edelstein, William A
M10‑79/p.208
Edo, Yuki N14‑131/p.139
Edwards, Philip G
N12‑6/p.122
Egan, Christopher NR01‑1/p.223
Egarievwe, Stephen U
R04‑26/p.107
R08‑4/p.170
Egea, Javier N14‑5/p.129
Egger, Ann EN1‑33/p.89
Egri, Gyozo M21‑29/p.258
Eichhorn, Thomas N25‑5/p.162
Eickhoff, Wilderich R09‑2/p.170
R04‑39/p.108
Eiland, Daniel M15‑30/p.228
Ekjeen, Tawatchai M10‑36/p.205
el Berni, Mowafak N6‑4/p.118
El Bitar, Ziad M09‑36/p.198
M08‑1/p.190
El Fakhri, Georges M04‑5/p.167
M22‑23/p.262
Elhadidy, Hassan R04‑70/p.111
R08‑1/p.169
R04‑65/p.110
El‑hanany, Uri R15‑7/p.221
R01‑1/p.84
Ellis, Mark N1‑16/p.88
N1‑9/p.87
N8‑3/p.119
N1‑5/p.87
N14‑95/p.136
N15‑1/p.155
El‑Sharkawy, Abdel‑Monem M10‑79/p.208
Elson, Jay SN7‑1/p.118
Elston, Brian M08‑2/p.190
Ely, James HN3‑4/p.82
He‑1‑7/p.224
Ely, Scott N18‑7/p.157
Emanuele, Umberto N12‑1/p.121
Emery, Michael S
N11‑7/p.121
Emmet, William N14‑201/p.145
Emri, Miklos M10‑37/p.205
M10‑77/p.208
Endo, Takanori N1‑176/p.100
N1‑175/p.100
Endo, Takanori Endo N26‑5/p.163
Endres, Christopher J
M07‑5/p.189
Endrizzi, Marco M22‑24/p.262
Engels, Jan N46‑5/p.217
Engels, Ralf N1‑68/p.92
N21‑6/p.160
Enghardt, Wolfgang M16‑12/p.232
N20‑7/p.159
HT‑2‑2/p.75
M06‑7/p.189
JNM‑6/p.126
Engl, Albert N13‑3/p.122
Enomoto, Shuichi N1‑204/p.102
M16‑40/p.234
Enqvist, Andreas P
N1‑92/p.94
N14‑77/p.135
N5‑8/p.117
Eom, Sangheum M16‑54/p.235
M16‑58/p.235
Eranen, Simo N1‑179/p.100
Erbe, Marlitt M10‑10/p.203
Erdei, Gabor M21‑6/p.256
Erdinger, Florian N1‑230/p.104
N4‑8/p.83
Erickson, Anna N27‑10/p.164
Ericson, M. NN11‑7/p.121
Erikson, Luke EN15‑8/p.155
Eriksson, Lars AM08‑6/p.190
M16‑8/p.232
N30‑5/p.178
Eriksson, Marita M16‑8/p.232
Erlandson, Andrew N1‑30/p.89
N1‑4/p.87
Erlandsson, Kjell M23‑3/p.255
M15‑9/p.226
M22‑35/p.263
Ernst, Joseph MN8‑8/p.119
Erven, Andreas N1‑68/p.92
Erven, Willi N1‑68/p.92
Espagnon, Bruno N24‑7/p.162
Espana, Samuel M12‑3/p.192
M06‑5/p.189
M16‑20/p.233
M22‑22/p.262
Espinoza, Anthony N37‑6/p.182
Esposito, Michela N14‑183/p.143
N37‑3/p.182
Esser, Anselm N1‑69/p.92
Estrada, Juan N21‑7/p.160
Estryk, Daniel N14‑64/p.133
Etxebeste, Ane M05‑5/p.188
M16‑45/p.234
Etzion, Erez N31‑7/p.179
Evans, Alan N15‑4/p.155
Evans, Larry N1‑86/p.93
Evrard, Olivier N9‑8/p.120
Evseev, Ivan N14‑78/p.135
f
F. Ben Mimoun Bel Hadj, Faraah M16‑61/p.236
Fabbri, Andrea M22‑17/p.262
M16‑39/p.234
Fabbri, Riccardo N1‑68/p.92
Fabris, Lorenzo N1‑53/p.91
N11‑7/p.121
N8‑8/p.119
N8‑5/p.119
Facchinetti, Stefano N4‑8/p.83
Faccini, Riccardo N14‑176/p.142
N33‑6/p.180
Fadeyev, Vitaliy A
N14‑198/p.144
NR01‑2/p.223
N18‑7/p.157
Faerber, Christian N17‑3/p.156
Fagan‑Kelly, Stefan B
N20‑8/p.159
Fahimian, Benjamin M18‑47/p.245
Fahrig, Rebecca M14‑3/p.219
Fajardo, Pablo N1‑231/p.104
Fajt, Lukas R08‑1/p.169
Falcon, Carles M09‑53/p.200
Fallica, Giorgio N14‑166/p.141
N1‑187/p.101
N1‑111/p.95
Fan, Lei M22‑53/p.264
Fan, Peng M10‑18/p.203
Fan, Xingming N1‑1/p.87
Fan, Yi M18‑75/p.247
M17‑13/p.238
M10‑41/p.205
Fang, Liu N14‑97/p.136
Fanizzi, Giampiero N13‑2/p.122
Fantacci, Maria Evelina N14‑73/p.134
N43‑2/p.186
Fantechi, Riccardo N43‑6/p.187
Fantony, Jolene M
Farber, Aaron MN1‑215/p.103
Farella, Isabella R09‑7/p.170
Farina, Fabio M10‑62/p.207
Farinelli, Chiara N18‑2/p.157
Farncombe, Troy H
M17‑16/p.238
M09‑69/p.201
M10‑8/p.203
M15‑61/p.230
Farnia, Parastoo M22‑59/p.265
Farquhar, Ethan N11‑7/p.121
Farrell, Jason N39‑4/p.184
Farrell, Richard M05‑2/p.188
M02‑2/p.166
Farsoni, Abi TN14‑96/p.136
Fast, James EN1‑124/p.96
N15‑4/p.155
Fauler, Alex R09‑2/p.170
R14‑5/p.195
R04‑53/p.110
R15‑4/p.221
R15‑1/p.221
JNMR‑4/p.126
R10‑1/p.171
R04‑39/p.108
R04‑9/p.106
R04‑3/p.106
Faurie, Juilia M09‑13/p.197
Favetta, Marco M17‑15/p.238
HT‑2‑3/p.75
N42‑6/p.186
Fawad, U. N1‑147/p.98
Fayad, Hadi JM22‑34/p.263
M23‑5/p.255
M11‑8/p.191
Fearn, Tom M15‑37/p.229
Federici, Luca N14‑233/p.147
Feigelson, Robert S
N30‑4/p.178
N30‑3/p.178
Felblinger, Jacques M11‑8/p.191
Felici, Giulietto N13‑2/p.122
Felix, Nicolas M10‑62/p.207
Fella, Armando N14‑72/p.134
N43‑9/p.187
N14‑80/p.135
N14‑71/p.134
Feller, W. Bruce N1‑87/p.94
N5‑7/p.117
Feng, Bing M15‑16/p.227
Feng, Tao M10‑48/p.206
Feng, Vanessa N14‑192/p.144
R04‑24/p.107
Fensin, Michael L
N7‑1/p.118
Fernandes, Luis M
N1‑205/p.102
N1‑200/p.102
Fernandez Moroni, Guillermo N21‑7/p.160
Fernandez, Dan N1‑46/p.90
Fernandez, Philippe M09‑50/p.199
M22‑58/p.265
Feroci, Marco N6‑5/p.118
N36‑5/p.182
Ferraioli, Giampaolo M22‑51/p.264
Ferrando, Philippe R04‑57/p.110
R04‑40/p.109
Ferreira Marques, Rui N14‑168/p.142
M21‑12/p.257
M09‑54/p.200
Ferreira, Claudia S
M15‑56/p.230
Ferreira, Filipa IM15‑65/p.231
Ferreira, Hugo M10‑71/p.208
Ferreira, Nuno CM09‑54/p.200
M15‑56/p.230
M17‑19/p.238
Ferreira‑machado, Samara C
M18‑81/p.247
Ferrer, Carles N14‑141/p.140
N14‑140/p.139
Ferrero, Andrea M14‑7/p.219
Ferretti, Claudio N31‑7/p.179
Ferretti, Stefano M22‑24/p.262
Ferri, Alessandro N1‑206/p.102
Ferris, Kim FR12‑4/p.194
Ferroni, Fernando N14‑176/p.142
Fessler, Jeffrey AM17‑1/p.237
M17‑3/p.237
R04‑18/p.107
M17‑24/p.239
Ficorella, Francesco N45‑8/p.216
N14‑53/p.132
Fidrich, Marta M23‑2/p.255
Fiederle, Michael R04‑9/p.106
R14‑5/p.195
R15‑1/p.221
R15‑4/p.221
N1‑68/p.92
R10‑1/p.171
N10‑7/p.121
JNMR‑4/p.126
R04‑10/p.106
R04‑53/p.110
R09‑2/p.170
R04‑12/p.107
R04‑3/p.106
R04‑39/p.108
Fiedler, Fine M06‑5/p.189
M06‑7/p.189
M16‑12/p.232
N20‑7/p.159
HT‑2‑2/p.75
JNM‑6/p.126
Fields, G N35‑3/p.181
Fieseler, Michael M15‑52/p.230
M15‑59/p.230
Fieselmann, Andreas M09‑9/p.196
Fieux, Sylvain M21‑16/p.257
Finck, Christian HT‑4‑3/p.77
M18‑79/p.247
N39‑2/p.183
Finocchiaro, Paolo M16‑11/p.232
M10‑60/p.207
Fiore, Salvatore N14‑176/p.142
N33‑6/p.180
HT‑2‑8/p.76
Fiorina, Elisa N14‑73/p.134
Fiorini, Carlo M22‑20/p.262
N14‑53/p.132
N9‑8/p.120
N45‑8/p.216
N1‑120/p.96
N1‑156/p.99
N45‑7/p.216
N1‑158/p.99
N1‑119/p.96
N14‑54/p.133
N14‑109/p.137
N1‑202/p.102
Firsching, Markus R04‑52/p.109
Fischer, Horst N14‑224/p.146
Fischer, Peter N34‑7/p.180
N4‑8/p.83
N16‑7/p.156
N1‑230/p.104
N9‑7/p.120
N14‑37/p.131
N14‑32/p.131
N1‑231/p.104
M10‑56/p.206
Fishburn, Matthew W
N14‑26/p.130
Fisher‑Levine, Merlin N29‑4/p.177
Flach, Barbara M09‑37/p.198
Flaska, Marek N5‑8/p.117
N23‑2/p.161
N14‑77/p.135
N1‑95/p.94
N1‑92/p.94
N1‑56/p.91
N1‑89/p.94
Fleta, Celeste N14‑154/p.140
N25‑2/p.162
N1‑11/p.88
N14‑158/p.141
N14‑197/p.144
N14‑58/p.133
N5‑1/p.117
N14‑57/p.133
Flohr, Thomas M18‑48/p.245
Flynn, Alison N1‑49/p.91
Fochuk, Petro MR04‑46/p.109
R04‑44/p.109
R04‑27/p.108
R02‑3/p.84
R13‑2/p.194
Foley Kijewski, Marie M15‑27/p.228
Fontaine, Rejean M05‑7/p.188
N40‑2/p.184
N34‑2/p.180
M10‑47/p.206
M05‑6/p.188
Fonte, Paulo M10‑32/p.204
M09‑54/p.200
M21‑12/p.257
Ford, Michael AN1‑93/p.94
Foresta, Massimo M10‑60/p.207
Forma, Jussi M09‑11/p.196
Fornaro, Giulia M16‑61/p.236
Fornaro, Laura R04‑66/p.111
Forshaw, Dean N25‑4/p.162
N14‑164/p.141
Forson, Ama JM18‑50/p.245
Fougeron, Denis M21‑16/p.257
Fourguette, Dominique N1‑26/p.89
Fourmentel, Damien N1‑130/p.97
Foxe, Michael N14‑136/p.139
N39‑6/p.184
Fraboni, Beatrice R02‑1/p.84
R02‑2/p.84
Frach, Thomas M12‑2/p.192
Fradley, Kate IN1‑63/p.92
Fraga, Francisco N14‑168/p.142
Franc, Benjamin JNMR‑5/p.126
Franc, Jan R04‑27/p.108
R16‑2/p.221
R10‑7/p.171
R08‑1/p.169
R04‑8/p.106
R04‑65/p.110
R04‑70/p.111
Franca, Hugo N6‑6/p.118
Francalanza, Laura N14‑217/p.146
N20‑6/p.159
Franchini, Paolo N14‑71/p.134
N14‑72/p.134
N14‑80/p.135
N43‑9/p.187
Francia, Dominic N5‑3/p.117
Francis, Sarah AN33‑7/p.180
Francisco, Fraga N21‑6/p.160
Frank, John MN1‑166/p.100
Frank, Steven SN11‑7/p.121
Franke, Brian CN7‑5/p.118
French, Marcus JN1‑225/p.104
N2‑5/p.82
Freud, Nicolas M10‑9/p.203
M22‑10/p.261
M18‑58/p.246
Frey, Eric CM16‑19/p.233
M09‑82/p.202
M15‑21/p.227
M17‑38/p.240
M10‑36/p.205
M08‑5/p.190
M12‑7/p.192
Frey, Raymond N35‑3/p.181
Freytag, Dietrich N1‑238/p.105
N35‑3/p.181
N9‑3/p.120
N2‑7/p.82
Freytag, Mark N35‑3/p.181
Frezza, Ottorino N14‑36/p.131
Fricke, Stanley TM18‑70/p.247
M20‑7/p.220
Fried, Jack M10‑64/p.207
M18‑24/p.243
R04‑7/p.106
N1‑183/p.101
N6‑8/p.118
N43‑5/p.187
Friederich, Hannes He‑2‑3/p.225
N1‑12/p.88
Friedman, Peter S
N31‑7/p.179
Friese, Judah IN3‑6/p.82
Frisch, Benjamin M16‑61/p.236
M10‑62/p.207
Frisch, Henry M09‑62/p.200
M09‑61/p.200
Fritz, David MN1‑237/p.105
Fritz, Fabian N20‑7/p.159
Frizzi, Tommaso N1‑202/p.102
M22‑20/p.262
N9‑8/p.120
Frohwein, Lynn M21‑21/p.257
Frojdh, Anna N14‑218/p.146
Frojdh, Christer N14‑218/p.146
R10‑3/p.171
R15‑5/p.221
Frojdh, Erik R10‑3/p.171
R15‑5/p.221
Fronk, Ryan GN1‑97/p.94
He‑2‑7/p.225
Frontini, Emanuela R04‑58/p.110
Fu, Lin M18‑89/p.248
M09‑1/p.196
M09‑21/p.197
Fu, Min N14‑209/p.145
Fucci, Adolfo N14‑233/p.147
Fuduli, Iolanda N14‑196/p.144
Fuin, Niccolo M03‑6/p.167
M08‑3/p.190
Fujii, Kazuo N14‑199/p.145
Fujii, Yu N1‑69/p.92
Fujii, Yuki N22‑7/p.160
Fujimaki, Shu M16‑7/p.232
N27‑8/p.164
Fujimoto, Yutaka N1‑146/p.98
He‑2‑8/p.225
N1‑145/p.98
N26‑7/p.163
N1‑153/p.99
N1‑159/p.99
N1‑160/p.99
N1‑149/p.98
N1‑142/p.98
N1‑78/p.93
N1‑79/p.93
Fujiwara, Mamoru N1‑18/p.88
Fujiwara, Takeshi N31‑3/p.178
Fukazawa, Yasushi N28‑8/p.165
Fukuchi, Tomonori M16‑40/p.234
N1‑204/p.102
Fukuda, Kentaro N1‑145/p.98
He‑2‑8/p.225
N1‑159/p.99
N1‑146/p.98
N1‑78/p.93
Fukuda, Masafumi N42‑1/p.186
N14‑1/p.129
Fukumoto, Nobu N1‑83/p.93
Fukushi, Masahiro M16‑18/p.232
Fulton, Roger M10‑52/p.206
M21‑47/p.259
M15‑67/p.231
M15‑64/p.231
M17‑55/p.241
M18‑87/p.248
M15‑47/p.229
Fung, Edward KM02‑5/p.166
Fung, George SM10‑36/p.205
Author Index 283
M10‑48/p.206
M15‑50/p.230
Fung, Jennifer M05‑2/p.188
Funk, Loren LN1‑87/p.94
N1‑81/p.93
Furenlid, Lars RM16‑67/p.236
M03‑1/p.166
M18‑43/p.245
M21‑4/p.256
Furfaro, Emiliano N33‑6/p.180
Furukawa, Yasunori N1‑149/p.98
Furukawa, Yukito N23‑5/p.161
R10‑5/p.171
Furumiya, Tetsuo M09‑64/p.200
Furuta, Masafumi M09‑64/p.200
Fusayasu, Takahiro N14‑129/p.139
Fuse, Tetsuto N37‑8/p.183
Futami, Yoshisuke N1‑142/p.98
He‑2‑8/p.225
g
Gabarda, Salvador M17‑27/p.239
Gabrielli, Alessandro N29‑2/p.177
N14‑184/p.143
Gadea, Rafael N14‑99/p.136
Gaede, Frank N46‑5/p.217
Gaens, Michaela M07‑6/p.190
Gaertner, Klaus N40‑3/p.184
Gagnon, Daniel M18‑6/p.242
N14‑41/p.131
M15‑41/p.229
M12‑4/p.192
M09‑85/p.202
M10‑29/p.204
Gai, Moshe N20‑5/p.159
Gaioni, Luigi N44‑6/p.215
N14‑27/p.130
Gal, Janos N14‑182/p.143
M10‑38/p.205
Galambos, Paul C
N1‑84/p.93
N1‑99/p.94
Galbiati, Arnaldo R04‑29/p.108
Galbrun, Ernest M10‑2/p.202
Galea, Raphael N31‑6/p.178
Galkin, Sergey M16‑49/p.235
Gallagher, Craig N35‑3/p.181
Gallant, Grant N1‑30/p.89
N1‑4/p.87
Gallas Torreira, Abraham A
N14‑150/p.140
Gallezot, Jean‑Dominique M14‑5/p.219
Gallin‑Martel, Laurent N14‑39/p.131
Gallivanone, Francesca M15‑4/p.226
Galloway, Michelle L
N14‑82/p.135
Galt, James RM18‑39/p.244
Galvez, Jose’ LR04‑57/p.110
Galvis‑Alonso, Orfa Yineth M21‑10/p.256
M21‑24/p.258
Gammino, Santo N42‑6/p.186
HT‑2‑3/p.75
Gan, K.K. N9‑1/p.119
Gandhi, Thulasi R01‑2/p.84
JMR‑4/p.125
Gandhi, Thulasidharan M16‑51/p.235
Ganin, Alexander M18‑25/p.243
Ganka, Thomas N45‑4/p.216
N45‑3/p.216
Gao, Fei M22‑65/p.265
Gao, Hao M09‑41/p.199
M09‑42/p.199
García‑Segundo, Crescencio M18‑83/p.248
Garcia Garcia, Eduardo N6‑6/p.118
Garcia, Carmen N14‑158/p.141
Garcia, Francisco N14‑121/p.138
N14‑197/p.144
N14‑58/p.133
N5‑1/p.117
N9‑2/p.119
Garcia, Raimundo M16‑22/p.233
Garcia‑Hernandez, Jose M
N1‑208/p.103
Garcia‑Sciveres, Maurice N31‑2/p.178
N31‑1/p.178
N5‑2/p.117
Gardner, Barbara N1‑53/p.91
Garduño, Edgar M18‑83/p.248
Garibaldi, Franco M16‑11/p.232
M10‑60/p.207
Garpebring, Anders M16‑5/p.231
Garutti, Erika LC4‑1/p.127
JNM‑2/p.125
Gary, Nathan R04‑41/p.109
Gascon, Martin N30‑4/p.178
N30‑3/p.178
Gaskin, Jessica AN1‑183/p.101
N14‑55/p.133
Gasparini, Leonardo N14‑167/p.142
N14‑172/p.142
Gatta, Maurizio N13‑2/p.122
Gaume, Romain M
N30‑3/p.178
Gauzzi, Paolo N14‑176/p.142
Gazit, Rotem N1‑30/p.89
N1‑4/p.87
Gebauer, Wolfgang N45‑4/p.216
Gebhardt, Pierre M18‑3/p.242
M10‑66/p.207
M12‑1/p.191
M11‑5/p.191
M09‑65/p.200
M02‑3/p.166
Gehre, Daniel R09‑3/p.170
Gektin, Alexander V
N1‑161/p.99
N1‑162/p.99
Gelain, Stefano N32‑6/p.179
Gelfandbein, Vladimir M13‑3/p.218
Gemme, C N14‑154/p.140
Gemmeke, Hartmut E
JNM‑3/p.125
Gendotti, Ulisse N1‑12/p.88
He‑2‑3/p.225
Gennai, Alberto N14‑15/p.130
Gennari, Roseli F
R04‑25/p.107
Genolini, Bernard N39‑2/p.183
Genoux, Aurelie M21‑16/p.257
George, Richard T
M22‑40/p.263
M15‑34/p.228
Georgiev, Georgi N1‑21/p.88
Georgiev, Strahil B
N1‑115/p.96
N1‑112/p.95
Geraci, Angelo N14‑53/p.132
N14‑54/p.133
N14‑109/p.137
Geraci, Elena N20‑6/p.159
N14‑217/p.146
Gerganov, Georgi V
N1‑21/p.88
M22‑37/p.263
M22‑54/p.264
Gerling, Mark N1‑59/p.91
N11‑5/p.121
N1‑107/p.95
Gesh, Chris JN5‑6/p.117
284 Author Index Gessler, Patrick N14‑237/p.147
Gevin, Olivier N14‑28/p.131
N14‑31/p.131
R10‑2/p.171
N14‑25/p.130
Ghaly, Michael M12‑7/p.192
M10‑36/p.205
M17‑38/p.240
M09‑82/p.202
Ghammraoui, Bahaa R09‑5/p.170
Ghebremedhin, Abiel N14‑189/p.144
Ghezzi, Alessio M10‑62/p.207
Ghithan, Sharif N14‑168/p.142
Giachero, Andrea N1‑209/p.103
N14‑98/p.136
N14‑11/p.130
Giacomini, Francesco N14‑72/p.134
N14‑71/p.134
N14‑80/p.135
N43‑9/p.187
Giacomini, Gabriele N1‑182/p.101
N14‑204/p.145
N14‑53/p.132
N45‑8/p.216
Giani’, S. N14‑217/p.146
N20‑6/p.159
Gianoli, Alberto N14‑72/p.134
N14‑71/p.134
N14‑80/p.135
N43‑9/p.187
Gianoli, Chiara M22‑16/p.261
Gianolli, Luigi M22‑52/p.264
Giaz, Agnese N1‑151/p.98
Gibbons, Paul N2‑3/p.81
Gigengack, Fabian M15‑52/p.230
M15‑35/p.228
M15‑43/p.229
Gil, Alejandro N14‑116/p.138
Gilardi, Maria Carla M22‑52/p.264
M15‑4/p.226
M10‑28/p.204
Gillam, John Edward M16‑65/p.236
M06‑5/p.189
M16‑62/p.236
M17‑5/p.237
M22‑15/p.261
M05‑5/p.188
N14‑107/p.137
Gimenez, Eva NR15‑5/p.221
N2‑3/p.81
N1‑226/p.104
R10‑3/p.171
Gindi, Gene M15‑42/p.229
Giordano, Raffaele N14‑112/p.137
N14‑94/p.136
N19‑5/p.158
N23‑1/p.161
Giordano, Valentina N40‑4/p.184
Giorgi, Filippo N29‑2/p.177
Girolami, Marco R04‑29/p.108
Gisquet‑Verrier, Pascale M21‑16/p.257
Giubilato, Piero N29‑1/p.177
Giuliani, Fausto M10‑60/p.207
Givens, Benjamin R
N38‑1/p.183
N38‑2/p.183
Glaser, Thomas N8‑4/p.119
Glass, Zachary AM18‑39/p.244
Glavin, Martin M10‑71/p.208
Glaysher, Paul N1‑19/p.88
Glenn, Andrew M
N1‑173/p.100
N1‑105/p.95
Glick, Stephen JR15‑6/p.221
M16‑21/p.233
Glodo, Jarek N1‑38/p.90
N1‑169/p.100
N1‑168/p.100
N41‑1/p.185
He‑2‑4/p.225
Glodo, Jaroslaw N1‑10/p.88
Gloster, Colin PR04‑57/p.110
Gnade, Bruce N1‑71/p.92
Gnani, Dario N6‑7/p.118
Gnatyuk, Volodymyr R04‑43/p.109
Goddard, James S
M15‑66/p.231
Godinez, Felipe M05‑2/p.188
M14‑7/p.219
Goehlich, Andreas N34‑3/p.180
Goeltl, Leonard He‑2‑3/p.225
Goertzen, Andrew L
M21‑25/p.258
M10‑26/p.204
M10‑42/p.205
M16‑23/p.233
M16‑35/p.234
M16‑37/p.234
Goetchy, Alain R10‑2/p.171
Goettlicher, Peter N4‑7/p.83
Goffe, Mathieu N44‑4/p.215
Gogami, Toshiyuki N1‑69/p.92
Gokhale, Sasmit S
R04‑71/p.111
Gola, Alberto N1‑206/p.102
M21‑5/p.256
N14‑32/p.131
N1‑203/p.102
Goldschmidt, Benjamin M09‑73/p.201
M02‑3/p.166
M11‑5/p.191
Goldsmith, John N1‑59/p.91
Golnik, Christian M16‑12/p.232
HT‑2‑2/p.75
JNM‑6/p.126
Golosio, Bruno N37‑5/p.182
Golovko, Victor N1‑30/p.89
N1‑4/p.87
Gomes, Itacil N27‑6/p.164
Gomez Rodrıguez, Mar N1‑69/p.92
Gomez‑Flores, Wilfrido M18‑60/p.246
M18‑61/p.246
Goncalves, Fernando N16‑4/p.156
Gong, Kuang M18‑42/p.245
Gonnier, Christian N1‑130/p.97
Gonzalez, Antonio Jose M16‑42/p.234
M09‑46/p.199
M16‑22/p.233
N1‑194/p.102
Gonzalez, Marjorie M07‑5/p.189
M07‑7/p.190
Gonzalez, Vicente N14‑5/p.129
Goorden, Marlies C
M05‑4/p.188
M17‑10/p.238
Gopalakrishnan, Anusha N14‑159/p.141
N1‑184/p.101
Goral, Adrian N14‑104/p.137
Gordon, Isky M15‑11/p.227
Gorriz Saez, Juan Manuel
M10‑14/p.203
M22‑44/p.264
M22‑33/p.263
Gorzellik, Matthias N14‑224/p.146
Gostilo, Vladimir R03‑5/p.85
Goto, Sachiko M18‑53/p.245
M18‑54/p.245
M18‑51/p.245
M18‑52/p.245
Gotti, Claudio N14‑11/p.130
N14‑98/p.136
N1‑209/p.103
Gould, Robert GM16‑51/p.235
M18‑17/p.243
Gouvea, Andrea L
N1‑200/p.102
N1‑205/p.102
Gozani, Tsahi N1‑40/p.90
N1‑157/p.99
Graafsma, Heinz R15‑4/p.221
N4‑7/p.83
N1‑231/p.104
Graber‑Bolis, Jonathan M21‑16/p.257
Grace, Carl RN6‑7/p.118
Graeser, Matthias M09‑66/p.201
Graf, Norman N14‑85/p.135
N14‑83/p.135
N46‑5/p.217
N14‑84/p.135
Graff, Robert TR12‑5/p.194
R08‑3/p.169
R04‑19/p.107
Grammens, Frank D
M18‑39/p.244
Granero, Domingo N14‑5/p.129
Granja, Carlos HT‑3‑7/p.76
JNMR‑3/p.126
Grant, Alexander M
M16‑9/p.232
Grass, Michael M09‑29/p.198
Grassi, Marco N6‑5/p.118
Gravel, Paul M22‑61/p.265
M22‑55/p.264
Green, Kevin M15‑5/p.226
Green, Michael V
M15‑14/p.227
M17‑7/p.237
Greenall, Ashley N25‑4/p.162
Greene, Peter M09‑82/p.202
Greer, Peter BM22‑9/p.261
Gregoire, Marie‑Claude M21‑31/p.258
M10‑51/p.206
M14‑1/p.218
M21‑49/p.259
Gregor, Ingrid‑Maria NP3‑3/p.217
NP1‑1/p.81
Gregor, Jens N14‑68/p.134
M10‑1/p.202
Greiffenberg, Dominic N4‑7/p.83
N2‑8/p.82
N2‑6/p.82
Grenier, P JN14‑154/p.140
Grenier, Philippe N44‑7/p.215
Grichine, Vladimir N14‑88/p.136
Gridin, Sergii N1‑161/p.99
Griesmer, Jerome M10‑3/p.202
M10‑4/p.202
Griffin, Ryan HN44‑8/p.215
Griffiths, Jennifer A
M15‑37/p.229
Grill, Roman R08‑1/p.169
R10‑7/p.171
R13‑2/p.194
R04‑70/p.111
R04‑65/p.110
R04‑47/p.109
Grimm, Oliver R04‑55/p.110
Grindlay, Jonathan R09‑6/p.170
R05‑5/p.124
Grinstein, Sebastian N14‑154/p.140
N44‑7/p.215
Grkovski, Milan N14‑185/p.143
M21‑28/p.258
Grodzicka, Martyna N22‑3/p.160
N34‑5/p.180
N30‑2/p.178
N1‑148/p.98
Grodzicki, Krystian N34‑5/p.180
Grogg, Kira M22‑23/p.262
Gronewald, Markus N4‑7/p.83
Gros Daillon, Eric NR01‑3/p.223
Grosicar, Borut N14‑110/p.137
M21‑28/p.258
N14‑185/p.143
Grossiord, Jean Yves N24‑7/p.162
Grttner, Mandy M09‑66/p.201
Grushko, Eugene R04‑43/p.109
Gruslys, Audrunas M22‑46/p.264
Grybos, Pawel N14‑104/p.137
N14‑38/p.131
N9‑5/p.120
Gu, Xianfeng M22‑53/p.264
Gu, Yi JMR‑3/p.125
Gu, Zheng M11‑2/p.191
M10‑40/p.205
M09‑81/p.201
M09‑80/p.201
Gualtieri, Eugene M10‑64/p.207
M15‑27/p.228
Guardiola, Consuelo N14‑197/p.144
N14‑58/p.133
N5‑1/p.117
Guatelli, Susanna N14‑193/p.144
N14‑195/p.144
N44‑3/p.215
Guazzoni, Chiara M21‑17/p.257
N14‑217/p.146
N20‑6/p.159
N14‑67/p.134
N40‑6/p.185
Gueorguiev, Andrey R12‑2/p.193
N1‑38/p.90
N1‑10/p.88
Guerard, Bruno N1‑76/p.93
He‑1‑3/p.224
Gueth, Pierre M08‑1/p.190
Guglielmetti, Alessandra N14‑34/p.131
Guida, Roberto N14‑127/p.138
N14‑132/p.139
N14‑151/p.140
N14‑126/p.138
Guilloux, Fabrice N24‑7/p.162
Guilloux, Gerard N24‑7/p.162
Guimbal, Philippe N1‑130/p.97
Gul, Rubi R16‑3/p.222
Gullberg, Grant T
M21‑35/p.258
M18‑27/p.244
M09‑36/p.198
M22‑30/p.263
M09‑68/p.201
M15‑30/p.228
M18‑17/p.243
Gulyas, Janos N1‑151/p.98
Gulyas, Laszlo M10‑77/p.208
Gundacker, Stefan M16‑61/p.236
Gundiah, Gautam N1‑178/p.100
Gunji, Taku N4‑4/p.83
N35‑2/p.181
N1‑193/p.102
N31‑5/p.178
N14‑130/p.139
Gunter, Donald N8‑7/p.119
N45‑6/p.216
N1‑52/p.91
N14‑86/p.135
Gunter, Donald L
N8‑6/p.119
Guo, Jianjun M18‑25/p.243
Gurley, Mike M15‑12/p.227
Gusak, Leon R15‑7/p.221
Author Index 285
R01‑1/p.84
Guttman, Nir N31‑7/p.179
Guvenis, Albert M10‑46/p.206
Gwosch, Klaus N14‑181/p.143
N37‑4/p.182
HT‑3‑7/p.76
JNMR‑3/p.126
h
Häggström, Ida M16‑5/p.231
Ha, Jang Ho R04‑35/p.108
R04‑34/p.108
R04‑33/p.108
R04‑51/p.109
Ha, Sungsoo M17‑8/p.237
Haas, Stefan N14‑112/p.137
Haba, Hiromitsu M16‑40/p.234
N1‑204/p.102
Haba, Junji N42‑1/p.186
Haberer, Thomas HT‑1‑3/p.75
Habl, Matthias R04‑52/p.109
Hadi, abdul‑fattah mohamad N14‑31/p.131
Haefner, Andrew N14‑86/p.135
N45‑6/p.216
N1‑52/p.91
Haenschke, Daniel R04‑9/p.106
Haese‑Seiller, Martin N1‑109/p.95
Hafezian, Soroush M15‑15/p.227
Hage‑Ali, Mohamed R04‑60/p.110
Hagen, Charlotte K
M22‑24/p.262
Haghighat, Alireza M10‑30/p.204
Hagmann, Chris N14‑136/p.139
N39‑6/p.184
Hahn, Daniel N1‑163/p.99
Hahn, Ferdinand N14‑132/p.139
N14‑127/p.138
Haider, Stefan N14‑132/p.139
N14‑127/p.138
Haines, Douglas K
N14‑92/p.136
N14‑207/p.145
Hajima, Ryoichi N1‑18/p.88
Hakmana Witharana, Sampath S
N1‑58/p.91
Haldar, Justin PM17‑33/p.239
M07‑1/p.189
Hall, Neal M23‑4/p.255
Haller, Gunter N2‑7/p.82
Haller, Gunther N14‑43/p.132
N1‑238/p.105
N14‑42/p.132
N9‑3/p.120
N35‑3/p.181
N1‑237/p.105
Hallett, William A
M07‑8/p.190
M22‑50/p.264
Hall‑Wilton, Richard J
N1‑109/p.95
N21‑8/p.160
He‑1‑3/p.224
He‑1‑1/p.224
N1‑73/p.92
Halsall, Rob N2‑5/p.82
Halstead, Matthew R
N14‑6/p.129
Halsted, Philip M14‑6/p.219
Hamada, Margarida M
R04‑25/p.107
Hamagaki, Hideki N1‑193/p.102
N14‑129/p.139
N14‑130/p.139
N31‑5/p.178
N35‑2/p.181
N4‑4/p.83
Hamann, Elias JNMR‑4/p.126
R04‑10/p.106
R04‑9/p.106
R15‑4/p.221
R10‑1/p.171
Hamawy, Lara M21‑2/p.256
Hamel, Matthieu N41‑5/p.185
Hamel, Michael C
N1‑56/p.91
N23‑2/p.161
Hamill, J JM23‑1/p.255
Hamman, Elias N10‑7/p.121
Hammel, Michael C
N1‑95/p.94
Hammig, Mark D
R04‑63/p.110
R04‑61/p.110
N22‑6/p.160
Hamze, Hasar M21‑49/p.259
Han, AReum N14‑17/p.130
Han, Bong Soo M18‑88/p.248
Han, Hao M17‑13/p.238
Han, Hyuksu R04‑71/p.111
Han, Jong Chul M15‑18/p.227
M10‑12/p.203
R04‑49/p.109
Han, Mincheol N7‑3/p.118
N14‑65/p.134
Han, Seokmin M22‑71/p.266
Han, Xiao M17‑22/p.238
M17‑23/p.239
M20‑2/p.220
Haneishi, Hideaki M16‑29/p.233
M10‑21/p.204
M06‑2/p.188
Hannan, Bruce W
N1‑81/p.93
N1‑100/p.95
Hans Krueger, Hans N4‑7/p.83
Hansch, Walter N45‑3/p.216
Hansen, Adam EM10‑68/p.207
Hansen, Karsten N4‑8/p.83
N1‑230/p.104
Hansen, T‑E N14‑154/p.140
Hansson, Conny C
N1‑163/p.99
R03‑5/p.85
Hanus, Martin N1‑165/p.99
Hanzouli, Houda M22‑49/p.264
Hao, Jia M17‑46/p.240
M18‑71/p.247
Hara, K. N14‑45/p.132
Hara, Koji N17‑6/p.157
Harada, Masahide N13‑8/p.123
Hardcastle, Nicholas N14‑196/p.144
Harding, Geoffrey N1‑23/p.89
Harion, Tobias N16‑6/p.156
N14‑37/p.131
Harkness, Laura J
N8‑3/p.119
R04‑16/p.107
Harper, Terance R08‑4/p.170
Harrawood, Brian P
N28‑9/p.165
Harrington, D. M18‑69/p.247
Harrison, Fiona R09‑6/p.170
Harrison, Jonathan N33‑2/p.179
Harrison, Mark N1‑155/p.99
Harrison, Robert L
M10‑31/p.204
M08‑2/p.190
Hart, Matthew N2‑5/p.82
Hart, Philip AN1‑238/p.105
N2‑7/p.82
N9‑3/p.120
N1‑237/p.105
Hartmann, Bernadette
HT‑3‑7/p.76 N14‑181/p.143
JNMR‑3/p.126
HT‑2‑6/p.76
N37‑4/p.182
Hartmann, Robert 286 Author Index N40‑6/p.185
Hartsough, Neal E
R01‑2/p.84
JMR‑4/p.125
M16‑51/p.235
Haruyama, Tomiyoshi N22‑7/p.160
Hasani Bidgoli, Javad M22‑59/p.265
Hasegawa, Kyoko N43‑4/p.187
Hasegawa, Tomoyuki M15‑1/p.226
Hasegawa, Yoji N1‑192/p.101
Hasegawa, Yuusuke M16‑48/p.235
N14‑162/p.141
Hashimoto, Daisuke M18‑57/p.246
Hashimoto, Makoto M16‑52/p.235
Hashimoto, Takashi N31‑5/p.178
Hasi, Jasmine N14‑154/p.140
N1‑233/p.104
N44‑7/p.215
Hassan, W+A3245alid M21‑2/p.256
Hast, Carsten N42‑3/p.186
Hatakeyama, Yoshikiyo N1‑217/p.103
Hatazawa, Jun M21‑1/p.256
M16‑7/p.232
Hatsui, Takaki N1‑227/p.104
N2‑1/p.81
N44‑2/p.215
N23‑5/p.161
Hatt, Mathieu M22‑49/p.264
Hattori, Kaori N13‑8/p.123
Hatzistratis, Dimitris S
R15‑2/p.221
Hau, Ionel N1‑167/p.100
Hauf, Steffen N28‑6/p.165
N14‑65/p.134
N7‑3/p.118
N14‑240/p.136
N28‑7/p.165
Haughton, Iain N44‑7/p.215
Hauser, Marc N25‑3/p.162
Hausladen, Paul A
N8‑5/p.119
N29‑6/p.177
Hawe, David M22‑31/p.263
Hawrami, Rastgo N1‑38/p.90
N1‑169/p.100
N1‑168/p.100
He‑2‑4/p.225
N41‑1/p.185
Hayakawa, Hikaru N1‑152/p.98
Hayakawa, Takehito N1‑18/p.88
Hayano, Hitoshi N42‑1/p.186
Hayashi, ShinIchi N4‑4/p.83
N35‑2/p.181
Hayes, John WN1‑43/p.90
Hayward, Jason P
N8‑8/p.119
N8‑5/p.119
N30‑6/p.178
N29‑6/p.177
N1‑214/p.103
He, Dao N1‑66/p.92
He, H. M18‑69/p.247
He, Li N14‑16/p.130
He, Lisheng R04‑22/p.107
He, Yihui R04‑5/p.106
He, Zhanying N21‑3/p.159
He, Zhong R14‑1/p.194
R11‑3/p.193
R04‑7/p.106
R04‑54/p.110
R04‑23/p.107
JMR‑6/p.125
R04‑20/p.107
NR01‑8/p.223
R04‑15/p.107
R14‑3/p.195
R14‑4/p.195
R04‑14/p.107
R04‑13/p.107
R04‑18/p.107
Hecht, Adam AR07‑6/p.169
Hedges, Michael T
N5‑2/p.117
N31‑1/p.178
N31‑2/p.178
Heenan, Richard K
N1‑63/p.92
Heering, Arjan N1‑213/p.103
Hegner, Benedikt N43‑1/p.186
Hegyesi, Gyula N14‑182/p.143
M10‑38/p.205
N14‑119/p.138
M21‑27/p.258
Heidbuechel, Hein M19‑8/p.220
Heidel, Klaus N20‑7/p.159
M16‑12/p.232
Heifets, Michael N14‑20/p.130
Heilbrun, Marta M17‑52/p.241
Heinzer, Susanne M15‑13/p.227
Helfenbein, Eric M03‑4/p.167
Helmbrecht, Stephan M06‑7/p.189
HT‑2‑2/p.75
Henderson, Robert K
N40‑1/p.184
Hendricks, John S
N7‑1/p.118
Hendricks, Thane N15‑7/p.155
N1‑48/p.90
N3‑7/p.82
Hendrix, Val N14‑87/p.135
Henrich, Beat N4‑7/p.83
N2‑8/p.82
Henriquet, Pierre JNM‑5/p.126
Henrotin, Sebastien M22‑20/p.262
Henry, Michael D
N1‑84/p.93
N1‑99/p.94
Heo, SeungUk R04‑69/p.111
Heo, Sung Kyn M16‑60/p.236
Herbach, Claus‑Michael N8‑4/p.119
Herbst, Ryan N14‑43/p.132
N1‑238/p.105
N14‑42/p.132
N2‑7/p.82
N9‑3/p.120
N1‑237/p.105
N35‑3/p.181
Herder, Jan‑Willem D
N36‑5/p.182
Herholz, Karl M22‑56/p.265
Herman, Cedric N1‑167/p.100
Hermann, Sven M15‑43/p.229
Hernandez, Andrew M
M22‑30/p.263
M16‑51/p.235
Hernandez, Liczandro M09‑46/p.199
N1‑194/p.102
Hernanz, Margarita R04‑57/p.110
Herpst, Robert R11‑2/p.193
Herraiz, Joaquin L
M17‑7/p.237
Herrero, Vicente N14‑99/p.136
M16‑42/p.234
Herrmann, Florian N14‑224/p.146
Herrmann, Sven N2‑7/p.82
N1‑238/p.105
N9‑3/p.120
N1‑237/p.105
Hertel, Nolan EN1‑91/p.94
Herten, Gregor N31‑4/p.178
Hertenberger, Ralf N14‑157/p.141
N13‑3/p.122
Hertlein, Markus N14‑179/p.143
Hertz, Kristin LN15‑3/p.155
Herv, Serge R10‑2/p.171
Herzog, Hans M15‑33/p.228
M09‑15/p.197
M07‑6/p.190
Hess, Andreas M09‑44/p.199
Hesser, Juergen M09‑6/p.196
Heußer, Thorsten M15‑32/p.228
Heuer, Rolf‑Dieter LC1‑1/p.86
NP1‑2/p.81
Heung‑ho, Lee N1‑180/p.101
Heuscher, Dominic J
M20‑4/p.220
Heuser, Johann M
N25‑6/p.162
Hidalgo, Pedro R02‑2/p.84
Hidas, Dean AN24‑5/p.162
Hidvegi, Attila N14‑237/p.147
Hiess, Arno N1‑73/p.92
Higgins, William R03‑2/p.85
R03‑3/p.85
Higuchi, M. N14‑45/p.132
Higuchi, Masahiro N17‑6/p.157
Higuchi, Mikio N39‑7/p.184
Higuchi, Takahiro M10‑48/p.206
Hill, Cassie N15‑1/p.155
N11‑2/p.121
N1‑16/p.88
N1‑9/p.87
Hines, Kim‑Eigard M16‑31/p.233
M09‑45/p.199
Hino, Masahiro N1‑103/p.95
Hinrichs, Paul N1‑126/p.97
Hinshelwood, David D
N42‑5/p.186
N1‑16/p.88
Hinz, Rainer M22‑56/p.265
M07‑8/p.190
M22‑50/p.264
Hiragi, Kazuyoshi N28‑8/p.165
Hirano, Yoshiyuki N14‑191/p.144
M10‑54/p.206
M22‑2/p.260
M22‑14/p.261
M18‑31/p.244
M18‑29/p.244
M09‑76/p.201
M16‑71/p.236
M16‑16/p.232
M06‑2/p.188
M12‑5/p.192
M10‑21/p.204
M16‑15/p.232
M13‑5/p.218
M16‑70/p.236
Hiromura, Makoto N1‑204/p.102
M16‑40/p.234
Hirono, Toko R10‑5/p.171
N23‑5/p.161
Hirose, Satoshi N1‑69/p.92
Hirsemann, Helmut N4‑7/p.83
Hisao, Sato N4‑2/p.83
Hitomi, Keitaro R04‑28/p.108
R11‑5/p.193
R03‑1/p.85
Hnatowicz, Vladimir N1‑65/p.92
Hobor, Sandor M21‑29/p.258
Hobson, Peter RM16‑55/p.235
Hodges, Jason PN1‑81/p.93
N1‑100/p.95
Hoeche, Daniel N1‑109/p.95
Hoehr, Cornelia M22‑3/p.260
Hoff, Gabriela N14‑240/p.136
N14‑65/p.134
N7‑8/p.118
N14‑74/p.134
N14‑76/p.135
N28‑5/p.165
N28‑6/p.165
N7‑3/p.118
N7‑4/p.118
Hoff, James N9‑5/p.120
N4‑5/p.83
Hoffman, August N39‑4/p.184
Hoffman, Calem R
N20‑2/p.158
Hoffman, John M
M22‑62/p.265
Hoffmann, Dieter H
N14‑240/p.136
N28‑6/p.165
N28‑7/p.165
Hoffmann, Jan N14‑121/p.138
N9‑2/p.119
Hofmann, Christian M18‑72/p.247
Hofmann, Hannes G
M09‑43/p.199
Hofmann, Thomas N14‑179/p.143
R04‑52/p.109
Hoglund, Carina He‑1‑1/p.224
He‑1‑3/p.224
N1‑73/p.92
N21‑8/p.160
Hohberg, Melanie M21‑19/p.257
M17‑30/p.239
Hohlmann, Marcus N1‑32/p.89
Holbrook, Britt N35‑3/p.181
Holland, Christopher E
N15‑3/p.155
Holland, Justin M
N1‑201/p.102
Holloway, Lois M22‑9/p.261
Holm, Scott N14‑205/p.145
Holm, Soeren M10‑68/p.207
Holmberg, Daniel M15‑24/p.227
Holmes, Steve NP3‑1/p.217
Holslin, Daniel N1‑54/p.91
Holtkamp, Norbert LC5‑2/p.127
Homma, Yasuhiro N14‑131/p.139
Honda, Yosuke N42‑1/p.186
Hong, Cheol Pyo M18‑88/p.248
Hong, Huicong R12‑5/p.194
Hong, Inki M17‑2/p.237
M15‑31/p.228
Hong, Jaesub R05‑5/p.124
R09‑6/p.170
Hong, Keunsung N14‑17/p.130
Hong, Key Jo M09‑60/p.200
M11‑3/p.191
Hong, Seong Jong M10‑69/p.208
Honscheid, Klaus N14‑185/p.143
N14‑110/p.137
Hood, William N1‑53/p.91
Hopp, Torsten JNM‑3/p.125
Hoppe, Eric WN14‑123/p.138
Horbatsch, Marko N14‑91/p.136
Hori, Junichi N1‑83/p.93
Hori, Toshitada N1‑18/p.88
Hori, Yasuto N35‑2/p.181
Horigome, Toshio N2‑1/p.81
Horisberger, Roland N2‑8/p.82
Hornback, Donald E
He‑2‑1/p.225
Hornegger, Joachim M17‑53/p.241
M15‑19/p.227
M17‑56/p.241
M10‑56/p.206
M09‑9/p.196
M09‑43/p.199
M19‑8/p.220
Author Index 287
Horowitz, Mark A
M09‑67/p.201
Horstmann, Christian N1‑109/p.95
Horswell, Ian N2‑3/p.81
Hoschl, Pavel R10‑7/p.171
R04‑70/p.111
Hose, Jrgen N1‑211/p.103
Hoshi, Yoshimoto N14‑128/p.139
Hoshor, Cory BN1‑42/p.90
Hosoya, Takaaki N1‑103/p.95
Hossain, Anwar R02‑3/p.84
R05‑2/p.124
R11‑2/p.193
R04‑8/p.106
R04‑62/p.110
R04‑26/p.107
R03‑4/p.85
R01‑3/p.84
JNMR‑5/p.126
R04‑11/p.107
R16‑3/p.222
Hossain, Jakir M09‑82/p.202
Hossain, Mosaddek M11‑7/p.191
Hossbach, Todd W
N1‑124/p.96
Hou, Bob M10‑76/p.208
Houben, Andreas N1‑68/p.92
Houzet, Dominique M09‑19/p.197
Howard, Jon M22‑50/p.264
M07‑8/p.190
Howe, Roger TN14‑46/p.132
Howell, Calvin R
N14‑190/p.144
N14‑188/p.144
Hoy, Les N8‑4/p.119
Hsiao, Ing‑Tsung M17‑44/p.240
M17‑11/p.238
Hsieh, Chi‑wen N14‑171/p.142
Hsu, Ching‑Han M09‑38/p.198
Hu, Dongming M21‑22/p.257
M18‑1/p.242
M18‑4/p.242
Hu, Guangshu N14‑170/p.142
Hu, Zhihao M16‑2/p.231
Huang, Hsuan‑Ming M17‑11/p.238
Huang, Jian M22‑32/p.263
Huang, Jing M18‑91/p.248
Huang, Kuan‑Chih R12‑6/p.194
Huang, Lu N1‑92/p.94
Huang, Meng N1‑66/p.92
Huang, Po‑Chia M09‑38/p.198
Huang, Qi WN1‑80/p.93
Huang, Qiu M18‑27/p.244
Huang, Shih‑ying M16‑51/p.235
Huang, Weiqi N1‑85/p.93
Huber, Jennifer M18‑11/p.242
Huddleston, David He‑2‑7/p.225
N1‑97/p.94
Hudin, Nicolas M17‑61/p.241
Hudson, Louise R04‑16/p.107
Huedo, Eduardo N14‑70/p.134
Huesman, Ronald H
M18‑11/p.242
M09‑36/p.198
Hugg, James WM17‑62/p.241
M18‑12/p.243
M10‑79/p.208
Huggins, Peter N1‑15/p.88
N1‑31/p.89
N1‑37/p.90
Hughes, Emlyn N14‑220/p.146
Hughes, Lindsey M21‑13/p.257
Hughes, Thomas N8‑3/p.119
Hugonnard, Patrick M10‑5/p.202
Hu‑Guo, Christine N44‑4/p.215
Huh, Duchang M10‑53/p.206
Huh, Sam SN1‑52/p.91
N14‑86/p.135
N1‑48/p.90
N14‑185/p.143
N8‑6/p.119
N8‑7/p.119
N3‑7/p.82
Huh, Yoonsuk M18‑15/p.243
M10‑78/p.208
M09‑84/p.202
Huh, Young M10‑53/p.206
Hull, Carter DN1‑201/p.102
Hull, Giulia N39‑2/p.183
Hullinger, Derek N40‑7/p.185
Hultman, Lars N1‑73/p.92
N21‑8/p.160
Hunt, Alan WN11‑4/p.121
N1‑45/p.90
N1‑44/p.90
Hunter, Stanley D
N36‑7/p.182
Hunter, William C
M21‑50/p.260
M10‑31/p.204
M21‑46/p.259
M03‑1/p.166
Hurford, Gordon R04‑55/p.110
Hurley, Aaron M22‑31/p.263
Hurley, Ford R04‑24/p.107
HT‑3‑2/p.76
N14‑192/p.144
N14‑174/p.142
N14‑78/p.135
Hurley, R FN14‑189/p.144
Hurst, Donald EN11‑7/p.121
Hurst, Gemma N14‑139/p.139
Huse, Torkjell N25‑4/p.162
Husher, Erin IR07‑6/p.169
Hutcheson, Anthony L
N15‑1/p.155
N11‑6/p.121
N42‑5/p.186
Hutton, Brian FM17‑37/p.240
M15‑9/p.226
M04‑6/p.168
M09‑24/p.197
M17‑58/p.241
M23‑3/p.255
M22‑35/p.263
Hutton, Brian HM08‑3/p.190
M03‑6/p.167
Huynh, Duc‑Dat R10‑2/p.171
Hwang, Sung Ha M16‑60/p.236
Hydomako, R. N1‑30/p.89
Hydomako, Richard N1‑4/p.87
Hynds, Daniel N14‑216/p.146
i
Iacchetti, Antonio N45‑7/p.216
Iacoangeli, Francesco N14‑2/p.129
Iarocci, Enzo N14‑176/p.142
Ichihara, Takashi M15‑34/p.228
M22‑39/p.263
M22‑40/p.263
Ida, Takahiro M16‑40/p.234
N1‑204/p.102
Ide, Kiyotaka N1‑95/p.94
N23‑2/p.161
N1‑56/p.91
Igarashi, Youichi N14‑223/p.146
Ignatyev, Konstantin M22‑24/p.262
Iguchi, Tetsuo N27‑5/p.164
N1‑152/p.98
N1‑78/p.93
N1‑83/p.93
N1‑79/p.93
Ihsani, Alvin M09‑69/p.201
Iijima, Toru N14‑45/p.132
Iinuma, Hiromi N14‑214/p.146
Ikeda, Hirokazu N4‑4/p.83
N4‑2/p.83
M16‑25/p.233
Il Park, Jai R04‑61/p.110
Iliev, Martin N1‑21/p.88
Illa, Jose N45‑2/p.216
Illan, Ignacio AM22‑44/p.264
Ilya, Tatsuaki M12‑8/p.192
Im, Ki Chun M10‑78/p.208
Imamura, Ryo M16‑52/p.235
Imamura, Toshifumi N1‑193/p.102
N36‑4/p.182
N44‑2/p.215
Imbert, Laetitia M10‑2/p.202
Imrek, Jozsef N14‑119/p.138
M21‑27/p.258
N14‑182/p.143
Inadama, Naoko M10‑61/p.207
M09‑76/p.201
M12‑5/p.192
M16‑15/p.232
M16‑70/p.236
M13‑5/p.218
M16‑71/p.236
M18‑29/p.244
M18‑31/p.244
M22‑2/p.260
N14‑191/p.144
M16‑59/p.236
M16‑16/p.232
Inaniwa, Taku M22‑2/p.260
M06‑2/p.188
Innes, Derek RM18‑16/p.243
M21‑36/p.259
Insa, Christophe N24‑7/p.162
Inuzuka, Masahide N14‑129/p.139
Inzalaco, Anthony N1‑55/p.91
Ionita, Ciprian N
M10‑58/p.206
M17‑41/p.240
Ionita, CiprianN. M10‑44/p.205
Irving, Thomas C
N1‑234/p.104
Isern, Jordi R04‑57/p.110
Ishida, Masaki M22‑39/p.263
Ishidu, Sumito N1‑78/p.93
Ishii, Keizo M13‑6/p.218
R03‑1/p.85
R11‑5/p.193
Ishii, Satomi N27‑8/p.164
Ishikawa, Yoshitaka M16‑17/p.232
N12‑6/p.122
M16‑25/p.233
Ishisaki, Yoshitaka N14‑52/p.132
Ishitsu, Takafumi R08‑2/p.169
Iskra, Peter N45‑4/p.216
N45‑3/p.216
Isobe, Takashi M18‑28/p.244
Isocrate, Roberto N14‑22/p.130
Ispiryan, Mikayel M17‑8/p.237
M10‑35/p.205
Itagaki, Kennosuke N4‑2/p.83
Ito, Hiroshi M13‑5/p.218
M06‑2/p.188
M10‑21/p.204
M16‑16/p.232
M16‑70/p.236
M16‑71/p.236
M09‑76/p.201
M17‑42/p.240
M12‑5/p.192
M18‑31/p.244
M16‑15/p.232
M22‑14/p.261
M22‑2/p.260
N14‑191/p.144
M18‑29/p.244
Ito, Masatoshi M18‑26/p.243
M18‑20/p.243
Ito, Mikiko M18‑30/p.244
Ito, Shigeki M18‑20/p.243
M18‑26/p.243
Ito, Tetsu R10‑4/p.171
Ivan, Adrian M18‑25/p.243
M16‑36/p.234
Ivanenko, Svetlana V
N14‑103/p.137
N14‑101/p.137
N14‑102/p.137
Ivanov, Alexey N14‑63/p.133
Ivanov, Oggie N14‑41/p.131
M18‑6/p.242
M09‑85/p.202
Ivanov, Victor R04‑56/p.110
R04‑32/p.108
Ivanova, Alina AN14‑103/p.137
N14‑102/p.137
N14‑101/p.137
Iwaki, Satoru N13‑8/p.123
Iwamoto, Toshiyuki N22‑7/p.160
Iwamoto, Yosuke N1‑140/p.98
Iwanczyk, Jan SM16‑51/p.235
R01‑2/p.84
Iwanowska, Joanna N1‑67/p.92
Iwasaki, Masahiko N14‑214/p.146
Iwata, Atsushi N44‑2/p.215
N36‑4/p.182
N1‑193/p.102
Iwata, Shuichi N14‑45/p.132
N17‑6/p.157
Iwona, Pawelczak N1‑173/p.100
Iwwamoto, Kei M17‑63/p.241
Izaki, Kenji N39‑7/p.184
Izzo, Vincenzo N14‑112/p.137
N14‑94/p.136
j
Jaakko, Harkonen N1‑179/p.100
Jaaskelainen, Kimmo N44‑4/p.215
Jablonski, Luke F
N14‑48/p.132
Jack, Stefanie N4‑7/p.83
Jackson, Carl M13‑2/p.218
M21‑32/p.258
Jackson, Lori AHe‑2‑7/p.225
Jackson, Michael HT‑1‑2/p.75
N37‑6/p.182
Jackson, Stewart L
N1‑16/p.88
N15‑1/p.155
Jackson, Stuart LN1‑5/p.87
N1‑9/p.87
N11‑3/p.121
N1‑42/p.90
He‑2‑7/p.225
N42‑5/p.186
N11‑2/p.121
Jacobsson, Richard N17‑2/p.156
Jacques, Simon NR01‑1/p.223
Jaegle, Igal N31‑1/p.178
N31‑2/p.178
Jaekel, Oliver HT‑3‑7/p.76
N14‑181/p.143
JNMR‑3/p.126
N37‑4/p.182
HT‑2‑6/p.76
Jagust, William M01‑2/p.166
Jain, Amit M10‑58/p.206
M10‑44/p.205
Jakieła, Rafał R04‑45/p.109
R04‑50/p.109
R11‑1/p.193
Jakobs, Karl N25‑3/p.162
Jakubek, Jan HT‑3‑7/p.76
N14‑181/p.143
R04‑59/p.110
N1‑106/p.95
NR01‑5/p.223
JNMR‑3/p.126
N37‑4/p.182
R15‑1/p.221
Jakubek, Martin R15‑1/p.221
Jambawalikar, S. M18‑69/p.247
James, Michael R
N7‑1/p.118
James, Ralph BR13‑2/p.194
R04‑62/p.110
R01‑3/p.84
JNMR‑5/p.126
R11‑2/p.193
R16‑2/p.221
R08‑4/p.170
R05‑2/p.124
R02‑3/p.84
R16‑3/p.222
R04‑44/p.109
R14‑6/p.195
R04‑8/p.106
R04‑27/p.108
R04‑26/p.107
R03‑4/p.85
R04‑11/p.107
Jamshidi, Parniya M18‑80/p.247
Jan, Sebastien M08‑1/p.190
Janacek, Jiri M22‑47/p.264
Janecek, Martin M18‑11/p.242
Jang, Kwang Eun M22‑43/p.264
Jang, Sun Young M15‑18/p.227
Janik, Rudolf N14‑121/p.138
Janssens, Robert V
N20‑2/p.158
Janulyte, Aurika N1‑130/p.97
Janvier, Baptiste M17‑61/p.241
M21‑16/p.257
Jarman, Kenneth D
N8‑1/p.119
Jarron, Pierre M16‑61/p.236
Jason, Newby N1‑173/p.100
Jastrząb, Michal N39‑2/p.183
Jatekos, Balazs M21‑6/p.256
Jaworski, Jason M
JMR‑6/p.125
R04‑18/p.107
NR01‑8/p.223
Jeanguillaume, Christian M09‑13/p.197
Jeglot, Jimmy N14‑51/p.132
Jendrysik, Christian N34‑6/p.180
Jenkins, David N39‑2/p.183
Jentzsch, Jennifer N14‑216/p.146
Jeon, J. A N1‑218/p.103
Jeon, Pil‑Hyun M18‑56/p.246
M09‑33/p.198
M20‑3/p.220
Jeon, Sang June N1‑141/p.98
Jeon, Sungchae N1‑224/p.104
M10‑53/p.206
Jeon, Tae Joo M22‑68/p.265
Jeong, Chiyoung M22‑19/p.262
Jeong, Jinwoong N14‑17/p.130
Jeong, Kye Young M17‑59/p.241
M17‑45/p.240
Jeong, Manhee R04‑63/p.110
Jeong, Tae Moon N29‑5/p.177
Jerebko, Anna M15‑6/p.226
Jeremie, Andrea LC4‑4/p.127
Jevaud, Michel M21‑16/p.257
Jewett, Cybele N1‑30/p.89
N1‑4/p.87
Jeynes, Chris NR01‑3/p.223
Jha, Abhinav KM03‑1/p.166
Jian, Yiqiang M09‑55/p.200
M15‑36/p.228
Jian, Yuchuan M22‑26/p.262
M17‑18/p.238
Jiang, Dengrong M09‑41/p.199
Jiang, Hao N14‑93/p.136
Jiang, Hua N1‑147/p.98
Jiang, Xiaoyi M15‑43/p.229
M21‑21/p.257
M15‑35/p.228
M15‑59/p.230
Jiao, Pengfei M09‑26/p.197
Jie, Wanqi R04‑5/p.106
Jimenez, Stephen M
N20‑8/p.159
Jin, Xiao M02‑5/p.166
M14‑5/p.219
M19‑1/p.219
M15‑36/p.228
Jin, Yongjie M17‑43/p.240
M10‑15/p.203
Jo, Woo Jin M16‑28/p.233
M22‑4/p.260
Joe, Okla R04‑49/p.109
M15‑18/p.227
Joerg, Philipp N14‑224/p.146
Joergensen, Jakob H
M17‑36/p.239
M17‑34/p.239
Joern, Schwandt N4‑7/p.83
Johansen, Tor Magnus R04‑23/p.107
Johansson, Lennart M16‑5/p.231
Johns, Russell CN7‑1/p.118
Johnson, Benjamin B
N15‑3/p.155
Johnson, Erik BN1‑96/p.94
N1‑46/p.90
N22‑6/p.160
N1‑122/p.96
Johnson, Ian N2‑8/p.82
Johnson, James T
N1‑45/p.90
N1‑174/p.100
N11‑1/p.121
Johnson, Karen L
M15‑54/p.230
M03‑4/p.167
Johnson, Lindsay C
M10‑11/p.203
M05‑3/p.188
Johnson, Marvin N4‑5/p.83
Johnson, Nathan H
N3‑3/p.82
Johnson, Robert P
R04‑24/p.107
N14‑192/p.144
M09‑78/p.201
Johnson, Tammie JNMR‑5/p.126
Johnson, Tony N46‑5/p.217
Johnson, W NHe‑2‑7/p.225
Jones, Charles N1‑39/p.90
Jones, Dominique R04‑26/p.107
Jones, Dumont M
R12‑4/p.194
Jones, Edward M10‑71/p.208
Jones, John M15‑23/p.227
Jones, Martin N8‑3/p.119
Jonkmans, G. N1‑30/p.89
Jonkmans, Guy N1‑4/p.87
Joo, Koan Sik N1‑141/p.98
Joo, Sung‑Kwan M10‑67/p.207
Joo, Yo Han M18‑36/p.244
Jordan, David VN1‑104/p.95
Jordan, Kelly R04‑71/p.111
Jorgensen, Jakob H
M09‑32/p.198
Jorion, Bruno N20‑1/p.158
Jorjadze, Vasily N31‑6/p.178
Joseph, John MN2‑2/p.81
N44‑5/p.215
N20‑2/p.158
N23‑7/p.161
Joshi, Tenzing HN39‑6/p.184
N14‑136/p.139
Jost, Beat N19‑1/p.158
Joti, Yasumasa N23‑5/p.161
Joung, Jinhun M09‑51/p.199
M16‑43/p.234
N1‑20/p.88
Jovanovic, Igor N14‑202/p.145
N14‑136/p.139
N39‑6/p.184
R12‑3/p.193
Jover Maas, Gabriel Author Index 289
N45‑2/p.216
Joy, Ashley N1‑225/p.104
N2‑5/p.82
Joyce, Malcolm JN1‑110/p.95
N1‑102/p.95
N1‑13/p.88
N5‑4/p.117
N1‑207/p.102
N1‑129/p.97
N1‑62/p.91
Jrgensen, Carl BR09‑1/p.170
Jtkos, Balzs N14‑172/p.142
Judenhofer, Martin S
M02‑2/p.166
M11‑7/p.191
Judson, Daniel SN8‑3/p.119
Juhan, Valerie M10‑62/p.207
Julien, Manuel G
N36‑3/p.181
Jun, Dang M10‑62/p.207
Jung, Jae WM10‑7/p.203
Jung, Ji woong M18‑15/p.243
Jung, Jin Ho M10‑78/p.208
M18‑14/p.243
M09‑84/p.202
M18‑15/p.243
M18‑13/p.243
Jung, Jiwoong M09‑84/p.202
M10‑78/p.208
M18‑14/p.243
Jung, Won‑Gyun M22‑5/p.260
Jung, YoungJun M21‑48/p.259
Juramy, Claire N14‑51/p.132
k
Kabuki, Shigeto N13‑8/p.123
Kachelrieß, Marc M14‑3/p.219
M18‑72/p.247
M09‑44/p.199
M09‑37/p.198
M09‑47/p.199
M15‑32/p.228
M22‑1/p.260
M10‑33/p.205
M18‑48/p.245
Kachkanov, V. R07‑5/p.169
Kachulis, Chris N20‑5/p.159
Kacperski, Krzysztof M17‑4/p.237
Kadrmas, Dan JM09‑34/p.198
M23‑6/p.255
M09‑86/p.202
M22‑30/p.263
M07‑2/p.189
M22‑62/p.265
Kadyk, John AN31‑2/p.178
N5‑2/p.117
N31‑1/p.178
Kagan, Harris N14‑110/p.137
N14‑185/p.143
M21‑28/p.258
Kahl, David MN31‑5/p.178
Kahled, Safat N38‑1/p.183
Kahn, Bernd N26‑1/p.163
Kaibuki, Futoshi M18‑57/p.246
Kaino, Masatomo R04‑30/p.108
Kaiser, Werner JNM‑3/p.125
Kajitani, Tsutomu M18‑53/p.245
M18‑54/p.245
Kajiwara, Taiju N1‑51/p.91
Kakuno, Hidekazu N14‑45/p.132
N17‑6/p.157
Kakurai, Takuya N14‑214/p.146
Kalicy, Grzegorz N14‑156/p.141
Kalinka, Gabor N14‑182/p.143
M21‑27/p.258
Kaliszek, Wojciech R04‑50/p.109
R11‑1/p.193
R04‑45/p.109
Kalliopuska, Juha J
N1‑179/p.100
NR01‑1/p.223
NR01‑5/p.223
Kam, Soohwa M15‑18/p.227
Kamada, Kei N1‑175/p.100
N26‑5/p.163
N1‑177/p.100
M16‑25/p.233
N1‑176/p.100
M16‑17/p.232
Kameoka, Satoru HT‑4‑4/p.77
Kameshima, Takashi N2‑1/p.81
N23‑5/p.161
Kamińska, Agata R11‑1/p.193
R04‑45/p.109
Kamieniecki, Krzysztof N15‑5/p.155
Kamiyama, Takashi N1‑75/p.93
Kampmann, Reinhard N1‑109/p.95
Kanai, Yasukazu M21‑1/p.256
Kanaki, Kalliopi He‑1‑1/p.224
Kanamaru, Taro M13‑6/p.218
Kandlakunta, Praneeth N1‑28/p.89
N42‑2/p.186
Kaneda, Michiru N14‑232/p.147
Kaneko, Daisuke N22‑7/p.160
Kaneko, Junichi H
N39‑7/p.184
Kang, Bong Keun M18‑36/p.244
Kang, Dong‑Goo M15‑20/p.227
M22‑71/p.266
M15‑22/p.227
M18‑62/p.246
Kang, Dong‑Uk N1‑144/p.98
N1‑195/p.102
N1‑196/p.102
N14‑29/p.131
Kang, Han Gyoo M10‑69/p.208
Kang, Jihoon M18‑13/p.243
Kang, Joo Hyun M18‑38/p.244
M15‑51/p.230
M15‑63/p.230
Kang, Jungwon M16‑54/p.235
M16‑58/p.235
Kang, Kejun N14‑106/p.137
M18‑71/p.247
M17‑46/p.240
Kang, Sunghoon M15‑20/p.227
M15‑22/p.227
Kang, Taehoon N22‑6/p.160
Kang, Zhitao N26‑1/p.163
Kanno, Ikuo M16‑52/p.235
Kao, Chien‑Min N14‑166/p.141
M09‑40/p.199
M09‑61/p.200
M09‑62/p.200
M17‑51/p.241
M17‑50/p.241
M16‑72/p.237
N1‑111/p.95
Kao, Chun‑Hao M17‑50/p.241
Kao, Yu‑Jiun M17‑50/p.241
Kapadia, Anuj JM09‑70/p.201
N14‑90/p.136
N28‑9/p.165
Kaplan, Alexis CN1‑92/p.94
Kaplan, Mitchell S
M18‑82/p.248
Kapusta, Maciej N30‑2/p.178
Karakatsanis, Nicolas A
M15‑66/p.231
Karakatsanis, Nikolaos A
M22‑64/p.265
Karamat, Muhammad Irfan M17‑16/p.238
Karcher, Gilles M10‑2/p.202
Kargar, Alireza R12‑2/p.193
R03‑3/p.85
R12‑5/p.194
290 Author Index R03‑2/p.85
Karim, Karim SN14‑180/p.143
Karlsson, Mikael M16‑5/p.231
Karp, Joel SM10‑64/p.207
M15‑27/p.228
M13‑4/p.218
M08‑4/p.190
M17‑40/p.240
M18‑10/p.242
M12‑6/p.192
Karpikov, Alexander M07‑4/p.189
Kasai, Hiroki N1‑227/p.104
N44‑1/p.215
Kasinski, Krzysztof N14‑38/p.131
Kassu, Aschalew R08‑4/p.170
Katagiri, Masaki N1‑103/p.95
He‑2‑2/p.225
Kataoka, Jun N12‑6/p.122
M16‑25/p.233
M16‑17/p.232
Katharina, Schumacher M02‑3/p.166
Kato, Eriko N4‑2/p.83
Kato, Katsuhiko M21‑1/p.256
Kato, Katuhiko M16‑7/p.232
Kato, Takuya M16‑25/p.233
M16‑17/p.232
Kauczor, Hans‑Ulrich M10‑25/p.204
Kaul, Madhuri M13‑4/p.218
Kaushik, Sandeep M15‑49/p.229
Kavalakuru, Pradeep N4‑8/p.83
Kavatsyuk, Myroslav N32‑4/p.179
Kavianipour, Hossein N23‑3/p.161
Kawabata, Nobuyuki M16‑25/p.233
Kawabata, Yuya N1‑79/p.93
Kawachi, Naoki N27‑8/p.164
M16‑7/p.232
Kawaguchi, Hiroshi M10‑54/p.206
Kawaguchi, Noriaki N1‑146/p.98
He‑2‑8/p.225
N1‑145/p.98
N1‑78/p.93
N1‑159/p.99
N1‑153/p.99
Kawai, Hideyuki N14‑45/p.132
M16‑48/p.235
M16‑70/p.236
N1‑217/p.103
N17‑6/p.157
M16‑71/p.236
N14‑162/p.141
Kawarabayashi, Jun N27‑5/p.164
N1‑152/p.98
N1‑83/p.93
Kawasaki, Takeo N14‑45/p.132
N17‑6/p.157
Kawase, Morihiro R10‑5/p.171
Kawashima, Kazuki N28‑3/p.164
Kawashima, Takushi M18‑51/p.245
M18‑52/p.245
M18‑53/p.245
Kawrakow, Iwan M22‑37/p.263
M22‑54/p.264
Kay, Holger N14‑237/p.147
Kay, Randolph RN1‑84/p.93
N1‑99/p.94
Kaye, Sonal JNR01‑8/p.223
Kaye, William RR04‑13/p.107
NR01‑8/p.223
R14‑4/p.195
Kazantsev, Daniil M04‑6/p.168
M09‑24/p.197
M15‑9/p.226
Kazas, Ioannis R15‑2/p.221
Kazkaz, Kareem N39‑6/p.184
N14‑136/p.139
Keen, Rochelle M17‑62/p.241
Keereman, Vincent M15‑7/p.226
Keillor, Martin EN14‑123/p.138
Keller, Sune HM15‑28/p.228
M10‑68/p.207
Kemmerling, Gunther N1‑68/p.92
M16‑50/p.235
N21‑6/p.160
Kempe, Mathias N20‑7/p.159
Kendall, Paul N8‑3/p.119
Kenney, Christopher J
N14‑154/p.140
N1‑235/p.105
N9‑3/p.120
N2‑7/p.82
N1‑238/p.105
N44‑7/p.215
N1‑236/p.105
N14‑46/p.132
N1‑233/p.104
N1‑237/p.105
Kensek, Ronald P
N7‑5/p.118
Kerkil, Choi M09‑1/p.196
Ketchum, Wesley N32‑6/p.179
Khaled, Alia SM09‑8/p.196
Khaled, Safat AN38‑2/p.183
Khalid, Farah FN9‑5/p.120
N14‑205/p.145
Khan, Abdul JN14‑92/p.136
N14‑207/p.145
Khan, Akram N14‑184/p.143
Khan, Mohammad A
N14‑152/p.140
Khaplanov, Anton He‑1‑3/p.224
He‑1‑1/p.224
N1‑73/p.92
N1‑76/p.93
Khilchenko, Aleksander D
N14‑102/p.137
N14‑101/p.137
N14‑103/p.137
Khoo, T LN20‑2/p.158
Kiani, Saeed M15‑11/p.227
Kibedi, T. N1‑127/p.97
Kida, Katsuhiro M18‑52/p.245
M18‑53/p.245
M18‑51/p.245
M18‑54/p.245
Kiesling, Christian N4‑3/p.83
N40‑3/p.184
Kiessling, Fabian M09‑3/p.196
M10‑66/p.207
M09‑65/p.200
M09‑2/p.196
M12‑1/p.191
M21‑5/p.256
M09‑73/p.201
M02‑3/p.166
Kiff, Scott DN1‑59/p.91
N1‑107/p.95
Kii, Toshiteru N1‑18/p.88
Kikuchi, Kei M15‑1/p.226
Kikuchi, Masae N1‑142/p.98
Kikuchi, Yohei M13‑6/p.218
Kikuchi, Yosuke N31‑5/p.178
Kikuzawa, Nobuhiro N1‑18/p.88
Killicarslan, Kemalettin M16‑66/p.236
Kim, Bae‑Hyung M18‑84/p.248
Kim, Byung Il M22‑68/p.265
M15‑51/p.230
M17‑59/p.241
M15‑63/p.230
Kim, Byung Tae M18‑15/p.243
Kim, Chan Hyeong N14‑65/p.134
N1‑199/p.102
N7‑3/p.118
N14‑178/p.143
Kim, Chang LM16‑57/p.235
M18‑25/p.243
Kim, Chankyu N14‑29/p.131
N1‑74/p.92
N1‑196/p.102
Kim, Chorong N1‑224/p.104
Kim, Dae‑Hong M18‑56/p.246
M20‑3/p.220
M09‑33/p.198
Kim, Dae‑Hyun M22‑19/p.262
Kim, Ealgoo KM09‑60/p.200
M11‑3/p.191
Kim, Eunhee N1‑69/p.92
Kim, Eunhwa N14‑17/p.130
Kim, Geehyun R04‑61/p.110
Kim, Gyeong Yun M09‑49/p.199
Kim, H. J. N1‑147/p.98
N1‑137/p.97
Kim, Hadong R04‑13/p.107
R03‑4/p.85
R12‑5/p.194
R11‑3/p.193
R03‑3/p.85
R04‑19/p.107
R12‑2/p.193
R03‑2/p.85
Kim, Han Soo R04‑51/p.109
R04‑35/p.108
R04‑34/p.108
R04‑33/p.108
Kim, Hang Keun M18‑36/p.244
M18‑37/p.244
Kim, Heejong N14‑166/p.141
M16‑72/p.237
M09‑62/p.200
M09‑40/p.199
N1‑111/p.95
M09‑61/p.200
Kim, Hee‑Joung M18‑38/p.244
M09‑33/p.198
M18‑65/p.246
M20‑3/p.220
M16‑47/p.235
M16‑10/p.232
M18‑56/p.246
M22‑66/p.265
M10‑55/p.206
JMR‑1/p.125
Kim, Ho Kyung M16‑60/p.236
M10‑12/p.203
R04‑49/p.109
M10‑24/p.204
M15‑18/p.227
M10‑13/p.203
R04‑48/p.109
Kim, Hyoungtaek N14‑29/p.131
N1‑197/p.102
N1‑144/p.98
Kim, Hyunduk N1‑144/p.98
N1‑196/p.102
N1‑197/p.102
N14‑29/p.131
Kim, Hyungtaek N1‑197/p.102
N1‑196/p.102
Kim, Hyun‑Il M16‑43/p.234
M22‑4/p.260
M16‑28/p.233
Kim, I Jong N29‑5/p.177
Kim, Ji Hye M17‑45/p.240
M17‑59/p.241
Kim, Ji na M16‑69/p.236
R04‑68/p.111
Kim, Jin seon M16‑69/p.236
Kim, Jin Su M22‑66/p.265
M18‑38/p.244
M21‑48/p.259
Kim, JinSun R04‑69/p.111
Kim, Jong Guk M21‑48/p.259
M10‑78/p.208
M22‑68/p.265
Kim, Jongyul N14‑29/p.131
N1‑196/p.102
N1‑74/p.92
N1‑144/p.98
N1‑197/p.102
Kim, Joo Young M22‑19/p.262
Kim, Jung‑Ha M18‑87/p.248
Kim, Ki‑Hyun R16‑3/p.222
R04‑8/p.106
R02‑3/p.84
R05‑2/p.124
R03‑4/p.85
R01‑3/p.84
R11‑2/p.193
R04‑62/p.110
R04‑11/p.107
JNMR‑5/p.126
Kim, Kwangdon M09‑51/p.199
Kim, Kyeong Min M22‑68/p.265
M18‑38/p.244
M17‑59/p.241
M15‑63/p.230
M15‑51/p.230
M21‑48/p.259
M22‑66/p.265
M10‑67/p.207
Kim, Kyu Bom M18‑15/p.243
M10‑78/p.208
M09‑84/p.202
Kim, Kyung Min M10‑78/p.208
Kim, Kyung Sang M17‑48/p.240
Kim, Min Hwan M15‑63/p.230
Kim, Myeong Seob N1‑141/p.98
Kim, Myung Soo N1‑196/p.102
N14‑29/p.131
N1‑144/p.98
N1‑195/p.102
Kim, Ryun Kyung M10‑53/p.206
Kim, Sangsu M18‑14/p.243
M09‑84/p.202
M10‑78/p.208
Kim, Seonghoon N14‑178/p.143
Kim, Seong‑Yun R11‑5/p.193
R03‑1/p.85
Kim, Soo Mee M09‑49/p.199
Kim, Sug‑Whan N1‑218/p.103
Kim, SungHun R04‑69/p.111
Kim, Sunghwan N1‑137/p.97
N1‑147/p.98
Kim, SungSu M18‑62/p.246
Kim, Suyoung R03‑2/p.85
Kim, Tae Woo M16‑60/p.236
Kim, Ye‑Seul M09‑33/p.198
M18‑65/p.246
Kim, Yewon N14‑29/p.131
N1‑196/p.102
N1‑144/p.98
Kim, Yongkwon N1‑20/p.88
Kim, Young Bo M18‑36/p.244
M18‑37/p.244
Kim, Young Soo R04‑33/p.108
R04‑51/p.109
R04‑34/p.108
Kim, Young Su N1‑199/p.102
Kim, Youngil M18‑84/p.248
Kim, Youngjae N14‑17/p.130
Kim, Young‑Kee N32‑6/p.179
Kimura, Akinori N43‑4/p.187
HT‑4‑4/p.77
Kinahan, Paul EM08‑2/p.190
M15‑3/p.226
Kinane, Christy J
N21‑1/p.159
Kinashi, Yuko N1‑82/p.93
Kindem, Joel N26‑4/p.163
N6‑3/p.118
M15‑12/p.227
King, Andrew PM09‑75/p.201
King, Michael AN1‑40/p.90
M14‑4/p.219
M17‑58/p.241
M15‑54/p.230
M15‑53/p.230
M03‑4/p.167
M16‑34/p.234
Kinlaw, Mathew T
N1‑45/p.90
Author Index 291
N11‑4/p.121
N1‑128/p.97
Kino, Koichi N1‑75/p.93
Kinouchi, Shoko M16‑16/p.232
M06‑2/p.188
M10‑21/p.204
M17‑42/p.240
M22‑14/p.261
Kippen, R MN36‑3/p.181
Kiraly, Beata N14‑182/p.143
M21‑27/p.258
Kirchgessner, Manfred N4‑8/p.83
Kirchgessner, Michael N1‑230/p.104
Kirihara, Les JN15‑8/p.155
Kirihara, Yoichi N2‑1/p.81
N44‑2/p.215
Kirilova, Nikolina N1‑21/p.88
Kirstein, Oliver N1‑73/p.92
He‑1‑1/p.224
Kis, Sandor AM10‑37/p.205
M10‑77/p.208
M10‑38/p.205
Kishihara, Hiroyuki R04‑30/p.108
Kishimoto, Aya M16‑17/p.232
M16‑25/p.233
Kishimoto, Shunji N14‑173/p.142
Kishimoto, Yuji N13‑8/p.123
N37‑8/p.183
Kitagawa, Kakuya M22‑39/p.263
Kitaguchi, Masaaki N1‑103/p.95
Kitamura, Hisashi N28‑8/p.165
Kitamura, Keishi M11‑6/p.191
M09‑64/p.200
Kittelmann, Thomas N1‑73/p.92
He‑1‑1/p.224
Kitto, Michael EN14‑207/p.145
Kiyanagi, Yoshiaki N1‑75/p.93
Kiyomichi, Akio N44‑2/p.215
N2‑1/p.81
N23‑5/p.161
Klamra, Włodzimierz N1‑139/p.97
Klanner, Robert N4‑7/p.83
Klausen, Thomas L
M10‑68/p.207
Kleczek, Rafal N14‑38/p.131
Klein, Benjamin N1‑91/p.94
Klein, Ran M15‑44/p.229
Kleinfelder, Stuart A
N19‑3/p.158
Kleipa, Volker N14‑121/p.138
N9‑2/p.119
N25‑6/p.162
Klimenko, Alexei V
N1‑164/p.99
Kline, Craig He‑2‑1/p.225
N1‑81/p.93
N1‑100/p.95
Klyuev, Alexander N4‑7/p.83
Klyuzhin, Ivan SM07‑7/p.190
Kmiecik, Maria N39‑2/p.183
Knapitsch, Arno N28‑2/p.164
JNMR‑2/p.126
Knaup, Michael M10‑33/p.205
M09‑47/p.199
M09‑44/p.199
M18‑72/p.247
Knecht, Andreas N14‑35/p.131
Knoetig, Max LN22‑4/p.160
N1‑211/p.103
Knopp, Tobias M09‑66/p.201
M10‑10/p.203
Ko, Guen Bae M10‑69/p.208
M21‑38/p.259
Ko, In Ok M15‑51/p.230
Ko, Mincheol M10‑67/p.207
N1‑20/p.88
Kobashi, Keiji R08‑2/p.169
Kobayashi, Kazuo N2‑1/p.81
N44‑2/p.215
Kobayashi, Takuya N1‑83/p.93
Kobayashi, Tetsuya M11‑6/p.191
Kobayashi, Toru M18‑57/p.246
Koch, Andreas N1‑232/p.104
N2‑5/p.82
Kochanowska, Dominika M
R11‑1/p.193
R04‑50/p.109
R04‑45/p.109
Kochurikhin, Vladimir V
N1‑160/p.99
Kockelmann, Winfried N5‑7/p.117
Kocsis, Menyhert NR01‑4/p.223
Koehler, Christoph M19‑8/p.220
Koehler, William R11‑3/p.193
Koenig, Thomas R10‑1/p.171
Koenigsmann, Kay N14‑224/p.146
Koesters, Thomas M15‑35/p.228
M15‑52/p.230
M15‑59/p.230
M15‑43/p.229
Koffmane, Christian N40‑3/p.184
Kohout, Benedikt JNM‑3/p.125
Kohriki, Takashi N14‑214/p.146
Koike, Akifumi R04‑43/p.109
R10‑4/p.171
R08‑7/p.170
Kojima, Takahiro N1‑149/p.98
Kok, Angela HT‑3‑6/p.76
N14‑154/p.140
N44‑7/p.215
Kokubun, Motohide N28‑8/p.165
N12‑6/p.122
Kolb, Armin JNM‑7/p.126
M11‑7/p.191
M21‑26/p.258
Kolbasin, Vyacheslav N14‑63/p.133
Kolstein, Machiel M16‑46/p.235
Komai, Hidetoshi N14‑131/p.139
Komar, Vitalii R13‑2/p.194
Komarov, Sergey A
M18‑1/p.242
M21‑22/p.257
M16‑44/p.234
M20‑8/p.220
Komelonko, M. R04‑29/p.108
Kondo, T. R07‑1/p.169
Kondo, Yoshiyuki N1‑78/p.93
Kong, Yong N41‑2/p.185
N8‑4/p.119
Konik, Arda M15‑53/p.230
M03‑4/p.167
M17‑58/p.241
M14‑4/p.219
Konnno, Chikara N1‑140/p.98
Konorov, Igor M21‑19/p.257
Konov, Vitali R04‑29/p.108
Konstantinidis, Anastasios C
M15‑37/p.229
M16‑64/p.236
Kontos, Michael M18‑73/p.247
Kopach, Oleg R04‑44/p.109
R13‑2/p.194
Korbly, Stephen E
N15‑5/p.155
Kormoll, Thomas M16‑12/p.232
JNM‑6/p.126
HT‑2‑2/p.75
292 Author Index Korn, Georg HT‑2‑3/p.75
N42‑6/p.186
Kornhuber, Johannes M16‑32/p.233
Korpar, Samo N14‑45/p.132
N17‑6/p.157
N22‑1/p.160
Kortner, Oliver N14‑157/p.141
N13‑3/p.122
Koseki, Yuu N28‑8/p.165
Koshimuta, Satoshi N14‑129/p.139
Koshkin, V R04‑46/p.109
Koskinas, Marina F
N1‑121/p.96
Kosonen, Jari PM16‑60/p.236
Koss, Peter N14‑189/p.144
Kostamo, Esa N36‑6/p.182
Kostamo, Jari N36‑6/p.182
Kostamo, Pasi N36‑6/p.182
Kostenko, Alexander M22‑38/p.263
Kosyachenko, Leonid R04‑43/p.109
R04‑46/p.109
Kotasidis, Fotis A
M17‑49/p.240
M17‑31/p.239
M22‑36/p.263
M15‑14/p.227
M15‑13/p.227
M19‑3/p.219
Kotov, Nicholas A
R04‑61/p.110
Koua, Konin M05‑6/p.188
Kouzes, Richard T
He‑1‑7/p.224
N8‑1/p.119
N3‑4/p.82
Kowalski, Bogdan R11‑1/p.193
R04‑50/p.109
R04‑45/p.109
Kowarschik, Markus M09‑9/p.196
Koybasi, Ozhan HT‑3‑3/p.76
HT‑4‑2/p.77
R12‑3/p.193
Kozlov, Valentin N1‑139/p.97
Kozlowski, Piotr M21‑25/p.258
M16‑37/p.234
M10‑42/p.205
M10‑26/p.204
M16‑23/p.233
Kozlowski, Tadeusz N1‑67/p.92
Kozorezov, Alexander R03‑5/p.85
Kraemer, Karl WN10‑1/p.120
N10‑2/p.120
Krakowski, Tomasz N1‑67/p.92
Kramberger, Gregor N25‑2/p.162
Krapohl, David R10‑3/p.171
R15‑5/p.221
Krasznahorkay, Attila N1‑151/p.98
Krebs, Kenneth M
N1‑33/p.89
Kreidl, Christian N40‑3/p.184
Kreps, Andrew N20‑2/p.158
N23‑4/p.161
Kretzek, Ernst JNM‑3/p.125
Kreuels, Achim N41‑2/p.185
Krieger, Brad N44‑5/p.215
Krieger, Michael N9‑7/p.120
Krimmer, Jochen M10‑9/p.203
M22‑10/p.261
JNM‑5/p.126
M18‑58/p.246
N16‑2/p.156
Krings, T. N1‑127/p.97
Krishna, Ramesh M
R07‑2/p.169
R13‑4/p.194
Kristen, Andreas M21‑19/p.257
Krizan, Peter N14‑45/p.132
N17‑6/p.157
Krizsan, Aron KM18‑76/p.247
M10‑38/p.205
Kroha, Hubert KN13‑3/p.122
N14‑157/p.141
Kronland‑Martinet, Carine M21‑9/p.256
Kross, Brian JN14‑188/p.144
N14‑190/p.144
Kroupa, Martin R04‑59/p.110
Krucker, Samuel R04‑55/p.110
Krueger, Hans N40‑3/p.184
Krueger, Peter N1‑188/p.101
Kruschwitz, Craig A
R04‑31/p.108
Kube, Matthias N1‑134/p.97
Kubinova, Lucie M22‑47/p.264
Kubo, Hidetoshi N13‑8/p.123
Kubono, Shigeru N31‑5/p.178
Kucera, Miroslav N1‑165/p.99
Kuchling, Franz R04‑10/p.106
Kuczewski, Anthony J
N1‑237/p.105
Kudielka, Guido P
M18‑93/p.248
Kudo, Togo N44‑2/p.215
N2‑1/p.81
Kudrolli, Haris JNMR‑6/p.126
Kuehl, Thorsten N1‑109/p.95
Kuehn, Susanne N25‑1/p.162
N25‑3/p.162
Kuester, Mathias N8‑4/p.119
Kuestner, Tilmann M17‑30/p.239
Kugel, Harald M15‑59/p.230
Kuharski, Robert N1‑53/p.91
Kulis, Szymon LC3‑4/p.127
Kulisek, Jonathan A
N5‑6/p.117
N8‑1/p.119
Kumagai, Kazuaki M18‑26/p.243
M18‑20/p.243
Kumaki, Masafumi N14‑7/p.129
Kumar, Joseph R15‑7/p.221
Kumar, Suresh N39‑2/p.183
Kumita, Tetsuro N14‑45/p.132
N17‑6/p.157
Kunath, Daniela HT‑2‑2/p.75
Kuncic, Zdenka M22‑9/p.261
N14‑193/p.144
M18‑87/p.248
Kundu, Bijoy KM15‑17/p.227
Kundu‑Raychaudhuri, Smriti M05‑2/p.188
Kunecke, Ulrike R04‑36/p.108
Kunkel, Jochen N9‑2/p.119
Kunnen, George R
N1‑71/p.92
Kuntz, Jan M09‑37/p.198
M09‑47/p.199
Kunz, Patrik M22‑1/p.260
Kunz, Tobias N14‑224/p.146
Kunze, Jonas N43‑6/p.187
Kurita, Kazuyoshi N14‑30/p.131
Kuriyama, Naoya N44‑1/p.215
N1‑227/p.104
Kurnadi, Priscilla P
N3‑5/p.82
Kuroda, Ryunosuke N14‑7/p.129
Kurosawa, Shunsuke N1‑146/p.98
N1‑153/p.99
N1‑159/p.99
N1‑160/p.99
N13‑8/p.123
N1‑145/p.98
N1‑170/p.100
He‑2‑8/p.225
N1‑149/p.98
N1‑142/p.98
Kurz, Nikolaus N9‑2/p.119
N14‑121/p.138
Kusaka, Junichiro N1‑69/p.92
Kushpil, Svetlana N14‑211/p.145
Kuster, Markus N28‑7/p.165
N14‑240/p.136
N1‑232/p.104
N2‑5/p.82
N14‑65/p.134
N28‑6/p.165
N7‑3/p.118
Kutnij, Volodymyr R13‑2/p.194
Kutter, Thomas R04‑6/p.106
Kuvandjiev, Vladimir M22‑37/p.263
Kuvvetli, Irfan R04‑57/p.110
R09‑1/p.170
R14‑2/p.195
Kuwahara, Satoshi M18‑51/p.245
M18‑52/p.245
Kuwert, Torsten M16‑32/p.233
M15‑19/p.227
Kvashnin, Andrey N
N14‑103/p.137
N14‑102/p.137
N14‑101/p.137
Kwa, William M22‑3/p.260
Kwak, Cholho N14‑17/p.130
Kwak, Jungwon M22‑12/p.261
Kwan, Simon N40‑4/p.184
Kwon, Dae Hyuk M18‑36/p.244
Kwon, Inyong R04‑63/p.110
Kwon, Sun Il M21‑38/p.259
M03‑5/p.167
Kyme, Andre ZM17‑55/p.241
M21‑47/p.259
M18‑8/p.242
Kyriakou, Yiannis M19‑8/p.220
l
Lőrincz, Emőke N14‑172/p.142
L. Herraiz, Joaquin M17‑27/p.239
M22‑60/p.265
La Guidara, Elena N14‑217/p.146
N20‑6/p.159
La Licata, Chiara N1‑182/p.101
La Malfa, G. HT‑2‑3/p.75
La Riviere, Patrick J
M04‑8/p.168
M20‑1/p.220
M20‑6/p.220
La Rosa, Alessandro N1‑182/p.101
Labalme, Marc HT‑4‑3/p.77
M18‑79/p.247
Labanti, Claudio N6‑5/p.118
Labov, Simon EN1‑31/p.89
N1‑37/p.90
N1‑15/p.88
Lacalamita, Nicola N13‑2/p.122
Lacasta, Carlos M16‑65/p.236
N14‑158/p.141
M16‑45/p.234
M05‑5/p.188
N14‑185/p.143
M17‑5/p.237
M21‑28/p.258
N14‑110/p.137
N14‑107/p.137
Lacerda, Flvio WN1‑121/p.96
Lacy, Jeffrey LHe‑1‑6/p.224
N1‑34/p.89
N1‑98/p.94
N1‑41/p.90
Laforest, Richard M09‑20/p.197
M10‑57/p.206
Lai, Adriano N1‑210/p.103
Lai, Alessandra N1‑210/p.103
Lai, Chia‑Lin M16‑30/p.233
Lai, Ching‑Hung N44‑7/p.215
Lai, Xiao Chun M16‑26/p.233
Lai, Yongfang N20‑4/p.158
Lajtos, Imre M10‑37/p.205
Lake, Patrick WN11‑5/p.121
N1‑99/p.94
N1‑84/p.93
Lakshmanan, Manu N
N28‑9/p.165
laktineh, Imad bN14‑145/p.140
N38‑3/p.183
Lalaiants, Aleksandr M16‑49/p.235
Lall, Terry JNMR‑5/p.126
R04‑11/p.107
Lam, Peter CN3‑5/p.82
Lam, Simon M16‑53/p.235
Lam, Stephanie N30‑3/p.178
N30‑4/p.178
Lamanna, Gianluca N43‑6/p.187
Lamare, Frederic M22‑58/p.265
M09‑50/p.199
Lamba, Dhruv M09‑82/p.202
Lambert, John N14‑63/p.133
Lambropoulos, Charalambos P
R04‑43/p.109
R15‑2/p.221
Lami, Stefano N13‑4/p.122
Lan, Allan KN16‑8/p.156
Lan, Allen M11‑1/p.191
M21‑7/p.256
Lan, Kejian AN1‑190/p.101
JNM‑4/p.125
N14‑238/p.147
Lander, Richard N35‑3/p.181
Landgraf, Ulrich N31‑4/p.178
Landoni, Claudio M22‑52/p.264
Lang, Christian HT‑2‑4/p.75
Lang, Philipp MN28‑7/p.165
N14‑240/p.136
N28‑6/p.165
Langley, Abigail N1‑189/p.101
Laniece, Philippe M21‑16/p.257
Lankenau, Michael M15‑47/p.229
Lankes, Konrad M11‑7/p.191
Lanni, Francesco N39‑4/p.184
Lantos, Judit M04‑3/p.167
M21‑29/p.258
Lanzalone, Gaetano N20‑6/p.159
N14‑217/p.146
Larocque, Liane N1‑26/p.89
Larsen, Nicole AN20‑5/p.159
Larsson, Anne M16‑5/p.231
M15‑24/p.227
Lasaygues, Philippe M10‑62/p.207
Lau, Frances WM09‑67/p.201
M21‑36/p.259
M18‑16/p.243
Laub, Thomas W
N7‑5/p.118
Laubach, Mitchell N1‑214/p.103
Laube, kristin HT‑2‑2/p.75
M06‑7/p.189
Lauhakangas, Rauno N14‑121/p.138
Laurence, Thomas M10‑3/p.202
M10‑4/p.202
Laurent, Philippe R04‑57/p.110
Lauritsch, Guenter M19‑8/p.220
M17‑53/p.241
Lauritsen, Torben L
N20‑2/p.158
Laver, Nicholas R
R13‑5/p.194
Lavietes, Anthony Author Index 293
N1‑110/p.95
N3‑2/p.82
Law, Marilyn PM17‑60/p.241
Lawrence, Christopher C
N5‑8/p.117
Lazurik, Valentine T
N14‑79/p.135
Lazzarini, Laura R07‑3/p.169
Le Mer, Isabelle R10‑2/p.171
Le Pogam, Adrien M22‑49/p.264
M09‑50/p.199
Leabad, Medhi M17‑39/p.240
M19‑7/p.220
Leahy, Richard M
M04‑5/p.167
M19‑2/p.219
M07‑1/p.189
M17‑33/p.239
M21‑8/p.256
M22‑29/p.263
Leas, Byron EN11‑6/p.121
Lebbolo, Herv N14‑51/p.132
Lebbou, Kheirreddine N41‑6/p.185
Lechner, Peter N1‑230/p.104
N1‑228/p.104
Lecomte, Roger M05‑7/p.188
M21‑41/p.259
M21‑33/p.258
M05‑6/p.188
M10‑47/p.206
Lecoq, Paul RM10‑62/p.207
M16‑61/p.236
N28‑2/p.164
N41‑6/p.185
JNMR‑2/p.126
Ledoux, Robert JN15‑5/p.155
Lee, Chae Yeong M16‑28/p.233
M22‑4/p.260
Lee, Chang‑Lae M20‑3/p.220
M09‑33/p.198
M18‑56/p.246
Lee, Chung‑chi N14‑171/p.142
Lee, Dae Hee N1‑197/p.102
N14‑29/p.131
N1‑196/p.102
N1‑195/p.102
Lee, Dong Hoon M18‑88/p.248
Lee, Dongwon N1‑88/p.94
Lee, Edward HN1‑71/p.92
Lee, Hakjae M16‑58/p.235
M16‑43/p.234
M10‑67/p.207
M16‑54/p.235
Lee, Han Rim N14‑178/p.143
Lee, Ho M18‑47/p.245
Lee, Hoseok N14‑17/p.130
Lee, Hye Young N1‑218/p.103
Lee, I YN20‑2/p.158
Lee, Jae Hak M22‑43/p.264
Lee, Jae Sung M09‑49/p.199
M10‑69/p.208
M03‑5/p.167
M18‑30/p.244
M21‑38/p.259
Lee, JaeMock M16‑24/p.233
Lee, Jeng‑hung N14‑171/p.142
Lee, Jeongtae N14‑29/p.131
N1‑197/p.102
Lee, Jhih‑shian M15‑25/p.228
M16‑33/p.234
Lee, Ji yun M16‑69/p.236
Lee, Jih‑Shian M16‑30/p.233
Lee, Jik N1‑218/p.103
Lee, Jiseoc M22‑12/p.261
Lee, Jongha M22‑43/p.264
Lee, Julie SR03‑3/p.85
Lee, Kangeui M18‑62/p.246
M22‑43/p.264
Lee, Kisung M16‑43/p.234
M09‑51/p.199
M10‑67/p.207
M16‑54/p.235
M16‑58/p.235
M22‑4/p.260
N1‑20/p.88
M10‑53/p.206
Lee, Kyo Chul M15‑63/p.230
Lee, Kyu Hong R04‑35/p.108
Lee, Man Woo M18‑88/p.248
Lee, Mi No M09‑30/p.198
Lee, Min Sun M18‑30/p.244
Lee, Pyoung Hean M18‑37/p.244
Lee, Richard M22‑3/p.260
Lee, Sanghyeb M10‑1/p.202
Lee, Sangwon M18‑13/p.243
Lee, Se Byeong M22‑12/p.261
M22‑19/p.262
N28‑3/p.164
Lee, SeoungDeok M22‑43/p.264
M16‑24/p.233
M18‑62/p.246
Lee, Seung Wan M10‑55/p.206
Lee, Seung Wook N1‑74/p.92
Lee, Seunghun M18‑84/p.248
Lee, Seungjoon N14‑190/p.144
N14‑188/p.144
M18‑9/p.242
Lee, Seung‑Wan JMR‑1/p.125
M16‑10/p.232
M16‑47/p.235
Lee, Soo‑Jin M09‑31/p.198
M09‑30/p.198
Lee, Tae Sup M21‑48/p.259
Lee, Tae‑Bum M10‑53/p.206
Lee, Taek‑Soo M08‑5/p.190
Lee, Taewon M09‑52/p.199
M18‑68/p.246
Lee, Taewoong N1‑191/p.101
Lee, Wonho N1‑191/p.101
M22‑68/p.265
Lee, Yeon Kyung M22‑66/p.265
Lee, Yong Jin M15‑63/p.230
M15‑51/p.230
Lee, Yoon Jin R04‑68/p.111
Lee, Young Jin M10‑55/p.206
Lee, Young Kyu R04‑68/p.111
Lee, Young Sub M18‑38/p.244
Lee, Young‑Jin M16‑47/p.235
M16‑10/p.232
Lefevre, Thibaut LC4‑3/p.127
Legere, Jason SN1‑26/p.89
N36‑3/p.181
N14‑48/p.132
LeGeyt, Ben CM18‑10/p.242
Legoupil, Samuel M21‑2/p.256
Lehmann Miotto, Giovanna N46‑1/p.216
Lehmann, Dorothee N14‑156/p.141
Lehnert, Wencke M10‑51/p.206
Lehovich, Andre N3‑5/p.82
Leite, Joao PM21‑24/p.258
Lemaire, Olivier M10‑34/p.205
N14‑31/p.131
Lemke, Henrik T
N1‑237/p.105
Lenci, Steve LC5‑5/p.128
Lentering, Ralf N8‑4/p.119
N41‑2/p.185
Leon, Jonathan D
N14‑35/p.131
Leonora, Emanuele N40‑4/p.184
N14‑165/p.141
Lerch, Michael N37‑7/p.183
N14‑193/p.144
Lerch, Michael LN44‑3/p.215
N14‑195/p.144
N14‑196/p.144
N14‑194/p.144
Lerch, Micheal N1‑216/p.103
Lerche, Christoph W
M10‑74/p.208
M11‑5/p.191
M09‑73/p.201
Leslie, Dawn EM16‑55/p.235
Leslie, Nakae N1‑173/p.100
Letang, Jean‑Michel M10‑9/p.203
M18‑58/p.246
M22‑10/p.261
294 Author Index Leterrier, Laurent N6‑4/p.118
Letourneau, Etienne M09‑23/p.197
Leung, Ka‑Ngo N42‑4/p.186
N1‑101/p.95
Levato, Tadzio N42‑6/p.186
HT‑2‑3/p.75
Levi, Giuseppe M09‑18/p.197
Levin, Craig SM16‑14/p.232
M15‑62/p.230
M13‑2/p.218
M21‑39/p.259
JMR‑3/p.125
M21‑42/p.259
M21‑37/p.259
M21‑36/p.259
M18‑16/p.243
M09‑63/p.200
M11‑3/p.191
M03‑3/p.167
M17‑25/p.239
M09‑83/p.202
M09‑67/p.201
M08‑7/p.190
M09‑60/p.200
M16‑9/p.232
Levin, Daniel SN31‑7/p.179
Levorato, Stefano N14‑135/p.139
Lewellen, Thomas K
M18‑45/p.245
M10‑31/p.204
M21‑50/p.260
M08‑2/p.190
M18‑40/p.244
Lewis, James M10‑76/p.208
Lewis, John HM22‑11/p.261
Lewis, Joseph M22‑56/p.265
Li, Bingxuan M16‑2/p.231
Li, Chung‑Yi N14‑13/p.130
Li, H. M18‑69/p.247
Li, Hongdi M03‑8/p.167
M21‑30/p.258
Li, Huanying N41‑7/p.185
Li, Jianmin N14‑106/p.137
Li, Jin N14‑124/p.138
N1‑66/p.92
N20‑4/p.158
Li, Juexin N14‑4/p.129
Li, Liang M09‑28/p.198
N1‑7/p.87
N1‑3/p.87
M09‑26/p.197
M22‑41/p.263
M17‑46/p.240
M18‑71/p.247
M09‑27/p.198
M09‑42/p.199
M09‑41/p.199
Li, Quanzheng M04‑5/p.167
M19‑2/p.219
M22‑29/p.263
M07‑1/p.189
Li, Shaorui N6‑1/p.117
N1‑183/p.101
N6‑8/p.118
N14‑55/p.133
Li, Syue‑Wei N14‑146/p.140
Li, Xiang N1‑1/p.87
Li, Xin M17‑38/p.240
Li, Xiyun M09‑35/p.198
Li, Yanzhao M16‑3/p.231
Li, Yichen N31‑6/p.178
N39‑4/p.184
Li, Yuanjing N20‑4/p.158
M22‑70/p.266
N14‑124/p.138
N1‑66/p.92
Li, Yulan N20‑4/p.158
N14‑124/p.138
N1‑66/p.92
Li, Yusheng M12‑6/p.192
M17‑40/p.240
Li, Yuxiong N14‑4/p.129
Li, Zheng N14‑55/p.133
N14‑206/p.145
N1‑183/p.101
liang, xiaohua R04‑37/p.108
Liang, Yicheng M10‑43/p.205
Liang, Zhengrong M09‑59/p.200
M17‑13/p.238
M18‑69/p.247
M18‑91/p.248
M18‑92/p.248
M22‑42/p.264
M22‑53/p.264
Liao, Can N1‑64/p.92
Liao, Hongen M10‑63/p.207
M12‑8/p.192
Licciulli, Francesco N14‑24/p.130
Licho, Robert M16‑34/p.234
Liemann, Gerhard N34‑6/p.180
Lim, Hyun Keong M10‑78/p.208
Lim, Poay Hoon M22‑63/p.265
Lim, Sang Moo M15‑51/p.230
M15‑63/p.230
M18‑38/p.244
M21‑48/p.259
M22‑66/p.265
M22‑68/p.265
Lim, Young Kyung M22‑12/p.261
M22‑19/p.262
Lima, Joao AM22‑40/p.263
M15‑34/p.228
Limousin, Olivier N14‑25/p.130
N14‑28/p.131
R04‑57/p.110
R04‑40/p.109
R04‑55/p.110
R10‑2/p.171
Lin, Chia‑Yu M09‑38/p.198
Lin, Chih‑hsun N14‑171/p.142
Lin, Li M16‑3/p.231
N14‑93/p.136
Lin, Ming‑Chao M09‑38/p.198
Lin, Qin M18‑69/p.247
Lin, Yanguang M21‑8/p.256
M04‑5/p.167
M07‑1/p.189
M17‑33/p.239
Lind, Randall N11‑7/p.121
Lindsay, Cliff M15‑54/p.230
Links, Jonathan M
M12‑7/p.192
Lintereur, Azaree T
N3‑4/p.82
He‑1‑7/p.224
Lionberger, Carl N20‑2/p.158
Lionheart, William R
M17‑49/p.240
Lipp, John N2‑3/p.81
Lipsanen, Harri N36‑6/p.182
Lipton, Ronald N4‑5/p.83
Lister, Christopher( Kim) N20‑2/p.158
Litichevskyi, Vladyslav M16‑49/p.235
Little, Kevin JM04‑8/p.168
Liu, Chen‑Yi M21‑25/p.258
M16‑37/p.234
Liu, Chi M02‑5/p.166
M07‑4/p.189
M15‑3/p.226
M19‑1/p.219
Liu, Chih‑Chieh JNM‑7/p.126
M11‑7/p.191
M21‑26/p.258
Liu, Guanghui N1‑143/p.98
Liu, Huafeng M22‑65/p.265
Liu, Hui M10‑80/p.208
M10‑59/p.207
M17‑43/p.240
Liu, Jingjing M16‑2/p.231
Liu, Jun M09‑48/p.199
Liu, Qian N1‑143/p.98
Liu, Shihao N14‑93/p.136
Liu, Shih‑Mim N14‑221/p.146
Liu, Snelin N1‑27/p.89
Liu, Ted N32‑6/p.179
Liu, Tiankuan N31‑6/p.178
Liu, Wei N14‑12/p.130
Liu, Wenyang M22‑27/p.262
Liu, Ya qM17‑43/p.240
Liu, Yan M17‑13/p.238
M09‑59/p.200
Liu, Yaqiang M10‑15/p.203
M10‑18/p.203
M10‑44/p.205
M10‑59/p.207
M17‑41/p.240
M18‑32/p.244
N14‑44/p.132
M10‑80/p.208
Liu, Yi NN1‑85/p.93
N14‑16/p.130
N4‑6/p.83
R04‑2/p.106
Liu, Yinong N14‑238/p.147
N16‑8/p.156
Liu, Yongjian M20‑8/p.220
Liu, Yuanyuan N1‑7/p.87
M18‑55/p.246
Liu, Z. N1‑30/p.89
Liu, Zhe N1‑25/p.89
Liu, Zhen M09‑48/p.199
Liu, Zhiyi N1‑4/p.87
Liuzzi, Raffaele N13‑2/p.122
Livieratos, Lefteris M21‑29/p.258
M09‑53/p.200
Livingstone, Jayde N44‑3/p.215
N14‑194/p.144
Ljungberg, Michael M15‑24/p.227
Llopart, Xavi N1‑226/p.104
Llosá, Gabriela N14‑110/p.137
N14‑185/p.143
M16‑45/p.234
N14‑107/p.137
M16‑62/p.236
M05‑5/p.188
M17‑5/p.237
M16‑65/p.236
Lo Cicero, Francesca N14‑36/p.131
Lo Nigro, Salvatore N14‑217/p.146
N20‑6/p.159
Lo Presti, Domenico N40‑4/p.184
N14‑177/p.143
N14‑165/p.141
N1‑2/p.87
M17‑15/p.238
M06‑6/p.189
Loddo, Flavio M16‑11/p.232
M10‑60/p.207
N13‑2/p.122
Lodge, Martin AM22‑64/p.265
Lodomez, Sarah M18‑2/p.242
Loef, Edgar VN1‑96/p.94
Loefgren, Johan M10‑68/p.207
Loeher, Bastian M22‑18/p.262
Loeliger, Teddy N6‑2/p.117
Loevenich, Heinz N1‑68/p.92
Lohstroh, Annika N1‑189/p.101
NR01‑3/p.223
Loizidou, Marilena M21‑17/p.257
Lombardo, Ivano N14‑217/p.146
N20‑6/p.159
Lonardo, Alessandro N14‑36/p.131
Long, Anwen M16‑3/p.231
N14‑93/p.136
Long, Zhiling N1‑39/p.90
Longhitano, Fabio N40‑4/p.184
N14‑165/p.141
Longo, Stefano N43‑9/p.187
N14‑71/p.134
N14‑72/p.134
N14‑80/p.135
Lonn, Albert HM15‑49/p.229
M23‑2/p.255
M15‑46/p.229
Looker, Quinn NR01‑6/p.223
Lopes, Luís M21‑12/p.257
Lopes, Maria CM22‑7/p.260
M18‑64/p.246
M22‑6/p.260
Lopes, Ricardo N14‑78/p.135
Lopes, Tiago N13‑7/p.123
N14‑133/p.139
Lopez Torres, Ernesto N14‑73/p.134
Lopez, Hector N1‑46/p.90
Lopinski, Gregory N44‑8/p.215
Lorca, David N14‑116/p.138
Lordi, Vincenzo R11‑4/p.193
R02‑4/p.84
Lorenz, Eckart JNM‑7/p.126
Loria, Dario N20‑6/p.159
N14‑217/p.146
Lorincz, Emoke M21‑6/p.256
M10‑6/p.202
Loris, Inace M09‑17/p.197
Los, Sergey M09‑61/p.200
N1‑111/p.95
N1‑187/p.101
N14‑166/p.141
Lou, Kai JNM‑4/p.125
M08‑8/p.190
Lou, Tak Pui M22‑25/p.262
Loukas, Dimitris R15‑2/p.221
Lourenco, Jose Carlos N14‑78/p.135
Loutchanski1, Anatoli R04‑32/p.108
Lozano, Manuel N14‑158/p.141
N25‑2/p.162
N14‑57/p.133
N14‑58/p.133
N5‑1/p.117
N14‑197/p.144
Lu, Guo‑Neng M22‑10/p.261
Lu, Haiting N14‑3/p.129
Lu, Hongbing M22‑42/p.264
Lu, Jian‑Qiang R12‑6/p.194
Lu, Junguang N1‑72/p.92
Lu, Lingjun N14‑44/p.132
Lu, Pinghe R01‑1/p.84
R15‑7/p.221
Lu, Yihuan M15‑42/p.229
Lucaci‑Timoce, Angela N35‑6/p.181
Lucchesi, Donatella N32‑6/p.179
Lucchini, Marco T
N41‑6/p.185
N28‑2/p.164
Lucentini, Maurizio M10‑60/p.207
Luckey, David N1‑133/p.97
Ludewigt, Bernhard A
N1‑44/p.90
N27‑9/p.164
Luebke, Joerdis R04‑12/p.107
Lugiez, Francis R10‑2/p.171
Lui, Qian N14‑135/p.139
Luitz, Steffen N14‑72/p.134
N14‑71/p.134
N43‑9/p.187
N14‑80/p.135
Luke, Paul NN29‑3/p.177
N14‑82/p.135
R03‑3/p.85
Lundy, Richard P
N15‑8/p.155
Luo, Jie R04‑2/p.106
Luo, Weidong M17‑26/p.239
Luo, Zhifei N1‑27/p.89
Luppi, Eleonora N43‑9/p.187
N14‑80/p.135
N14‑72/p.134
N14‑71/p.134
Łusakowska, ElŁbieta R04‑50/p.109
Lustig‑Yaeger, Jacob N14‑192/p.144
R04‑24/p.107
Lutz, Gerhard N1‑230/p.104
Lux, Silvere JMR‑5/p.125
Lux, Thorsten N45‑2/p.216
Luxen, Andre M21‑15/p.257
Author Index 295
M21‑18/p.257
Lydon, Don N1‑122/p.96
Lynch, Candace N1‑55/p.91
Lyoo, Chul Hyoung M22‑68/p.265
Lyoussi, Abdallah N1‑130/p.97
N27‑1/p.163
m
Ma, Jianhua M18‑69/p.247
M18‑92/p.248
M18‑91/p.248
Ma, Jie N6‑1/p.117
Ma, Juanhua M09‑59/p.200
Ma, Tianyu M17‑43/p.240
M10‑15/p.203
M21‑33/p.258
N14‑44/p.132
M18‑32/p.244
M10‑59/p.207
M08‑8/p.190
M10‑44/p.205
M10‑80/p.208
M17‑41/p.240
Maalmi, Jihane N6‑4/p.118
Macafee, Scott M09‑78/p.201
N14‑192/p.144
N14‑186/p.143
R04‑24/p.107
Macaloney, Graeme R01‑1/p.84
R15‑7/p.221
Macchiolo, Anna N33‑3/p.179
MacDonald, Lawrence R
M17‑26/p.239
M10‑31/p.204
Mace, Emily KN14‑123/p.138
Macera, Daniele N6‑5/p.118
Macias‑Montero, Jose G
N16‑3/p.156
Mackewn, Jane E
M11‑5/p.191
M14‑6/p.219
M21‑29/p.258
M10‑74/p.208
Madani, Jamal H
N1‑239/p.105
Madar, Igal M15‑50/p.230
Madden, Amanda N1‑26/p.89
Madden, Timothy N20‑2/p.158
Maddock, Robert N1‑9/p.87
N11‑2/p.121
N15‑1/p.155
Maeda, Yoshikazu HT‑4‑4/p.77
Maerk, Julia M21‑16/p.257
Magalotti, Daniel N14‑200/p.145
Magana, Quetzalcoatl M09‑70/p.201
Magazzu’, Guido N4‑5/p.83
Magdics, Milan M04‑3/p.167
M09‑5/p.196
M09‑72/p.201
Maggiore, Mario N42‑6/p.186
HT‑2‑3/p.75
Magill, Martin PN1‑30/p.89
N1‑4/p.87
Magoon, Stephen N14‑234/p.147
Mahadik, Sanish N14‑159/p.141
N1‑184/p.101
Mahdi, Kinan M18‑93/p.248
Mahler, George JNMR‑5/p.126
Maia, Jorge MR04‑57/p.110
Maier, Andreas M17‑53/p.241
M09‑43/p.199
Maino, Matteo N14‑98/p.136
N14‑11/p.130
N1‑209/p.103
Maintas, Dimitrios M17‑12/p.238
Maiolino, Concettina N14‑217/p.146
N20‑6/p.159
Mair, Lamar OM18‑70/p.247
Maitrejean, Serge M19‑7/p.220
M17‑39/p.240
Maity, Tapan KN40‑8/p.185
Maj, Adam N39‑2/p.183
Maj, Piotr N14‑104/p.137
N9‑5/p.120
Majcher, Amanda N14‑202/p.145
Majewski, Stanislaw M09‑61/p.200
M10‑76/p.208
M16‑68/p.236
M16‑72/p.237
Majkrzak, Charles F
N1‑88/p.94
Major, Peter M21‑29/p.258
Makeev, Andrey R15‑6/p.221
Maki, Akihiro N22‑7/p.160
Malakhov, Nail R01‑2/p.84
JMR‑4/p.125
Malaney, James M18‑25/p.243
M16‑57/p.235
Malchow, Russell L
N1‑43/p.90
Malcovati, Piero N6‑5/p.118
Malfa, Giuseppe N42‑6/p.186
Malik, Azhar HM10‑17/p.203
Maliszewskyj, Nicholas C
N1‑88/p.94
Malo, Jean‑Yves N1‑130/p.97
Maltz, Jonathan S
N14‑86/p.135
N45‑6/p.216
N8‑7/p.119
N1‑52/p.91
N8‑6/p.119
Manazza, Alessia N44‑6/p.215
Mandai, Shingo N34‑4/p.180
Mandal, Krishna C
R07‑2/p.169
R13‑4/p.194
Mandelli, Beatrice N14‑210/p.145
N14‑132/p.139
N14‑127/p.138
N14‑126/p.138
Maneuski, Dzmitry R15‑5/p.221
Manfredini, Alessandro N14‑157/p.141
N13‑3/p.122
Manger, Leo N1‑236/p.105
Manghisoni, Massimo N44‑6/p.215
N14‑27/p.130
N4‑8/p.83
Manhart, Michael T
M09‑9/p.196
Manjeshwar, Ravindra M
M10‑73/p.208
M19‑5/p.219
M23‑7/p.255
Mankoff, David A
M22‑32/p.263
Mann, Alexander B
M21‑19/p.257
Mann, Gregory JM18‑6/p.242
N14‑41/p.131
M09‑85/p.202
Mann, Joshua DR04‑14/p.107
NR01‑8/p.223
Mannheim, Julia G
M10‑72/p.208
Manso, Franck N24‑7/p.162
Manti, Lorenzo HT‑2‑3/p.75
N42‑6/p.186
Mantlik, Frederic M15‑26/p.228
Manuel, Fantoba N1‑179/p.100
Manueski, Dzmitry R10‑3/p.171
Manzali, Matteo N43‑9/p.187
N14‑72/p.134
N14‑71/p.134
Manzin, Giuliana N21‑6/p.160
Mao, Peter R05‑5/p.124
Mao, Rihua N25‑8/p.162
N41‑7/p.185
N1‑172/p.100
Mao, Samuel SN1‑101/p.95
Mao, Yanfei M17‑57/p.241
Marafini, Michela N14‑176/p.142
N1‑114/p.96
Maranville, Brian B
N1‑88/p.94
Marchal, Julien P
N2‑3/p.81
N1‑226/p.104
M10‑13/p.203
R04‑48/p.109
M10‑12/p.203
Marchant, Jeffrey N1‑213/p.103
Marchini, Laura R02‑1/p.84
R13‑3/p.194
R09‑1/p.170
R08‑6/p.170
Marchiori, Giovanni N1‑182/p.101
Marcinkowski, Radoslaw M12‑3/p.192
Mares, Jiri AN1‑165/p.99
Margarone, Daniele R12‑1/p.193
N42‑6/p.186
N29‑5/p.177
HT‑2‑3/p.75
Margaryan, Amur N1‑69/p.92
Margato, Luis N21‑6/p.160
Margulis, Pavel N14‑20/p.130
Marie, Pierre‑Yves M10‑2/p.202
Marinelli, Marco M22‑17/p.262
R07‑5/p.169
Marino, Nahema M22‑24/p.262
Markiewicz, Pawel J
M22‑36/p.263
M15‑57/p.230
M22‑69/p.266
M17‑49/p.240
Markosyan, Gary N41‑4/p.185
Markovic, Bojan N16‑1/p.156
Marleau, Peter N27‑4/p.164
N1‑90/p.94
N11‑5/p.121
N1‑14/p.88
N1‑107/p.95
Marone, Alessandro N1‑119/p.96
N1‑158/p.99
M22‑20/p.262
Maros, Istvan M09‑13/p.197
Marques, Rui FM10‑32/p.204
Marrakchi, Ghanem NR01‑3/p.223
Marras, Alessandro N14‑200/p.145
N4‑7/p.83
Marsden, Edward He‑2‑6/p.225
Marsden, Paul KM18‑3/p.242
M18‑2/p.242
M10‑74/p.208
M21‑29/p.258
M14‑6/p.219
M02‑3/p.166
M15‑45/p.229
M09‑75/p.201
M11‑5/p.191
Martel, Ismael N20‑6/p.159
N14‑217/p.146
Martens, Michael N14‑166/p.141
Marti Fuster, Berta M09‑53/p.200
Martignac, Jérôme R10‑2/p.171
Martin, A N1‑87/p.94
Martin, Christopher S
N1‑34/p.89
N1‑41/p.90
N1‑98/p.94
He‑1‑6/p.224
Martin, Elena N14‑140/p.139
N14‑141/p.140
Martin, Jose DN14‑5/p.129
Martin, Jurkovic N21‑6/p.160
Martin, Philip NN1‑16/p.88
N1‑5/p.87
N11‑2/p.121
Martin‑Chassard, Gisele N4‑1/p.83
N14‑8/p.129
Martinez Garbino, Lucio N14‑64/p.133
Martinez, Francisco J
M22‑44/p.264
Martinez, H PN1‑105/p.95
Martinez, Juan N1‑54/p.91
Martins, Joo FR04‑25/p.107
Martins, Luis M15‑56/p.230
Martins, Paulo M09‑54/p.200
M21‑12/p.257
Martisikova, Maria HT‑2‑6/p.76
HT‑3‑7/p.76
JNMR‑3/p.126
N14‑181/p.143
N14‑194/p.144
N37‑4/p.182
R04‑59/p.110
Martn, Carlos N45‑2/p.216
Martnez, Ricardo N16‑3/p.156
Martoiu, Victor Sorin N32‑7/p.179
Martone, Peter M10‑76/p.208
Martos, Julio M16‑22/p.233
Marty, Wilfried R04‑40/p.109
Marubashi, Kenta N14‑162/p.141
Maruhashi, Akira N1‑82/p.93
Maruhashi, Kenta M16‑48/p.235
Maruyama, Shusuke N1‑79/p.93
Marzocca, Cristoforo N14‑24/p.130
Mascarenhas, Nicholas N3‑2/p.82
N1‑110/p.95
Masciantonio, Giuseppe N36‑8/p.182
Mase, Keiichi M16‑48/p.235
N14‑162/p.141
Maslyanchuk, Olena R04‑43/p.109
Maspero, Matteo N12‑7/p.122
Massarotti, Paolo N14‑144/p.140
Massey, Thomas N
N5‑8/p.117
Mastroianni, Stefano N12‑3/p.122
Masuda, Kai N1‑18/p.88
N1‑51/p.91
Masunaga, Shinichiro N1‑82/p.93
Matarrese, Gianvito N14‑24/p.130
Matea, Iolanda N39‑2/p.183
Matej, Samuel M17‑8/p.237
M10‑35/p.205
M12‑6/p.192
M17‑40/p.240
Matela, Nuno M10‑71/p.208
Mathews, Aswin J
M18‑1/p.242
M16‑44/p.234
M21‑22/p.257
Mathez, Herve N16‑2/p.156
M22‑10/p.261
N24‑7/p.162
Mathieu, Cedric N39‑2/p.183
Mathy, Francoise M17‑39/p.240
M19‑7/p.220
Mato, Pere N43‑1/p.186
Matsubara, Hiroaki N31‑5/p.178
Matsuda, Takeshi LC3‑1/p.127
Matsufuji, Naruhiro HT‑4‑4/p.77
Matsumoto, Haruhisa N37‑8/p.183
Matsumoto, Mikio M15‑1/p.226
Matsumoto, Takahiro M16‑59/p.236
Matsumoto, Tetsuro N1‑83/p.93
Matsunaga, Yusuke N12‑6/p.122
Matsuoka, Masanori LC6‑2/p.128
Matsuyama, Shigeo M13‑6/p.218
Mattedi, Francesca N14‑204/p.145
Mattei, Ilaria N14‑176/p.142
Matteuzzi, Clara N1‑209/p.103
Matthews, Jayme M01‑3/p.166
Matthews, Julian C
M15‑5/p.226
M15‑57/p.230
M17‑31/p.239
M17‑49/p.240
M19‑3/p.219
M15‑14/p.227
M22‑36/p.263
M22‑69/p.266
Mattila, Marco N36‑6/p.182
Mattingly, John K
N14‑59/p.133
N14‑77/p.135
Mattson, Kegan He‑2‑7/p.225
Matysiak, Witold N1‑58/p.91
Maurizio, Boscardin N1‑179/p.100
Mavrokoridis, Kostas N39‑6/p.184
N14‑136/p.139
Mawlawi, Osama M15‑55/p.230
Mayo‑Garcia, Rafael N14‑70/p.134
Mazumdar, Indranil N39‑2/p.183
Mazza, Gianni N16‑4/p.156
Mazzillo, Massimo M03‑3/p.167
N1‑111/p.95
N14‑166/p.141
N1‑187/p.101
Mazzocco, Marco N14‑113/p.137
Mazzuca, Elisabetta N1‑171/p.100
McAuley, Grant A
JNM‑8/p.126
N28‑4/p.164
McBroom, Gary M18‑25/p.243
McCabe, Deirdre M22‑57/p.265
McCall, Karen N3‑7/p.82
N15‑7/p.155
N1‑48/p.90
McCall, M. N1‑30/p.89
McClanahan, Timothy N1‑86/p.93
McClish, Mickel N1‑166/p.100
McClory, John W
N1‑93/p.94
N14‑6/p.129
N33‑7/p.180
McConchie, Seth N11‑7/p.121
McConnell, Mark L
N1‑26/p.89
N14‑48/p.132
N36‑3/p.181
McCormick, Jeremy N46‑5/p.217
McCown, Jay N1‑39/p.90
McDaniel, David L
M16‑36/p.234
M16‑57/p.235
M18‑25/p.243
McGrath, John N
R13‑5/p.194
R04‑60/p.110
R02‑5/p.84
McGregor, Douglas S
N1‑97/p.94
R12‑7/p.194
N5‑3/p.117
N1‑94/p.94
N1‑42/p.90
He‑2‑7/p.225
McHale, Stephen R
N1‑93/p.94
McKenna, Joseph T
N18‑5/p.157
McKenna, Mike N1‑213/p.103
McKenney, Shawn C
N3‑5/p.82
McKinney, Gregg W
N7‑2/p.118
N7‑1/p.118
McKinny, Kevin S
N3‑3/p.82
McKinsey, Daniel N
N1‑157/p.99
N20‑5/p.159
McKisson, Jack E
N1‑125/p.96
N14‑188/p.144
N14‑190/p.144
McKisson, John M18‑9/p.242
N14‑190/p.144
N14‑188/p.144
McLean, Lance N3‑7/p.82
N15‑7/p.155
N1‑48/p.90
McMillan, John He‑2‑6/p.225
McMillan, Kyle N1‑14/p.88
M06‑4/p.189
McNamara, Aimee L
M22‑9/p.261
McNeil, Sarah M
M10‑8/p.203
McPhate, Jason B
N5‑7/p.117
McQuaid, Sarah M15‑27/p.228
McTigue, Hannah N1‑26/p.89
McVittie, Patrick J
N2‑2/p.81
N23‑7/p.161
Mdina, Patrice N39‑2/p.183
Mead, Joseph N1‑237/p.105
Meddi, Franco M16‑11/p.232
M10‑60/p.207
Medeiros, Adriana S
N1‑123/p.96
Medvids, A R04‑56/p.110
Mehdi, Chambit N39‑2/p.183
Mehranian, Abolfazl M18‑78/p.247
M17‑29/p.239
Mei, Ye N14‑56/p.133
Meikle, Steven RM15‑67/p.231
M21‑47/p.259
M10‑52/p.206
M14‑1/p.218
M15‑64/p.231
M17‑55/p.241
M18‑8/p.242
M21‑49/p.259
M21‑31/p.258
Meinken, George JNMR‑5/p.126
Mejia, Israel N1‑71/p.92
Mejia, Jorge M21‑11/p.256
M21‑24/p.258
M21‑10/p.256
Melcher, Charles L
N30‑5/p.178
Author Index 297
N1‑132/p.97
M16‑8/p.232
Mellado, Bruce N14‑159/p.141
N1‑184/p.101
Mellor, Matthew P
N1‑102/p.95
N1‑129/p.97
N1‑207/p.102
Menard, Laurent M17‑61/p.241
Mendes, Luís M09‑54/p.200
M15‑56/p.230
M17‑19/p.238
Meneses, Anderson A
M18‑49/p.245
Menesguen, Yves R04‑40/p.109
Meng, Bowen M18‑47/p.245
Meng, Ling‑Jian M16‑26/p.233
M18‑44/p.245
R05‑4/p.124
R04‑67/p.111
Menge, Peter RN1‑135/p.97
Mengesha, Wondwosen N1‑60/p.91
N1‑107/p.95
Menichelli, David N14‑187/p.143
Menkara, Hisham N26‑2/p.163
Menke, Sven N25‑7/p.162
Menouni, Moshine M21‑16/p.257
Mensah, Serge M10‑62/p.207
Menshikov, Alexander JNM‑3/p.125
Menzel, Uta N1‑211/p.103
Merhof, Dorit M16‑32/p.233
Merkel, Harald N1‑69/p.92
Merlin, Jeremie A
N14‑138/p.139
Merlin, Thibaut M09‑50/p.199
Meroli, Stefano N14‑200/p.145
Mertelmeier, Thomas M15‑6/p.226
Mesquita, Carlos H
R04‑25/p.107
Metcalfe, Peter N14‑196/p.144
Metzler, Scott DM18‑21/p.243
M21‑43/p.259
M12‑6/p.192
M03‑7/p.167
M17‑40/p.240
Meuris, Aline R10‑2/p.171
R04‑55/p.110
R04‑57/p.110
R04‑40/p.109
Meyer, Tom M16‑61/p.236
Mezza, Davide N40‑6/p.185
Mibe, Tsutomu N14‑214/p.146
Michailian, Argin M06‑4/p.189
Michalek, Jan M22‑47/p.264
Michalowska, Alicja N14‑28/p.131
N14‑25/p.130
Michalski, Christoph N14‑224/p.146
Michel, Christian M16‑8/p.232
M17‑2/p.237
Michel, John MN1‑166/p.100
Michel, Maugan N30‑1/p.177
Michimasa, Shin’ichiro N31‑5/p.178
Michko, A R04‑56/p.110
Mickum, G SN1‑91/p.94
Mihailescu, Lucian N1‑52/p.91
N45‑6/p.216
N8‑6/p.119
N8‑7/p.119
N3‑7/p.82
N14‑86/p.135
M22‑25/p.262
N1‑48/p.90
Mihalczo, John T
N11‑7/p.121
Mihara, Satoshi N22‑7/p.160
Mikeli, Maria M09‑77/p.201
M16‑41/p.234
M18‑73/p.247
Mikhaylova, Katya M16‑46/p.235
Mikkelsen, Sindre R04‑23/p.107
Mikkola, Esko ON9‑4/p.120
Miklavec, Mojca M22‑18/p.262
Mikuz, Marko M21‑28/p.258
N14‑185/p.143
N14‑110/p.137
Milani, Enrico R07‑5/p.169
Milano, Luciano R14‑2/p.195
Milhoretto, Edney N14‑78/p.135
Millard, Thomas P
M22‑24/p.262
Miller, Brian WM21‑10/p.256
M03‑1/p.166
Miller, Cameron A
N1‑50/p.91
Miller, Eric CN14‑77/p.135
N1‑92/p.94
Miller, Erin AN8‑1/p.119
Miller, Michael A
M10‑4/p.202
Miller, Michael L
N14‑35/p.131
Miller, Stuart RN26‑2/p.163
N1‑234/p.104
M13‑3/p.218
Miller, William H
N1‑42/p.90
R12‑7/p.194
He‑2‑7/p.225
Million, Benedicte N1‑119/p.96
N1‑151/p.98
N1‑118/p.96
Milovanovic, Marko N25‑2/p.162
Mimura, Hidenori R08‑7/p.170
R10‑4/p.171
Min, Byung Jun M22‑19/p.262
M22‑12/p.261
Min, Chul Hee M22‑23/p.262
Min, Eungi M16‑54/p.235
N1‑20/p.88
Min, Jonghwan M18‑68/p.246
Minami, Shizu N14‑121/p.138
Mini, Giuliano R04‑29/p.108
Minniti, Triestino N14‑217/p.146
N20‑6/p.159
Miranda, Ana CM21‑11/p.256
Mirzoyan, Razmik N22‑4/p.160
N1‑211/p.103
Misawa, Tsuyoshi N1‑51/p.91
Mishra, Pankaj M22‑11/p.261
Miskimen, Rory N1‑122/p.96
Mistry, Prina N15‑1/p.155
N1‑9/p.87
Mitchell, Dean JN14‑59/p.133
Mitchell, Gregory S
M21‑34/p.258
Mitchell, Lee JN1‑16/p.88
N15‑1/p.155
N1‑5/p.87
N42‑5/p.186
N1‑40/p.90
N11‑6/p.121
Mitev, Krasimir K
N1‑21/p.88
M22‑54/p.264
N1‑115/p.96
N1‑112/p.95
M22‑37/p.263
Mitra, Debasis M15‑30/p.228
M21‑35/p.258
Mitra, Joyeeta MM03‑4/p.167
Mitsuda, Kazuhisa N14‑52/p.132
Miuchi, Kentaro N13‑8/p.123
N37‑8/p.183
Miura, Noriyuki N44‑1/p.215
Miura, Takamasa M16‑17/p.232
Miwa, Kenta M15‑1/p.226
Miwa, Toshiyuki M18‑41/p.244
Mix, Michael JNMR‑4/p.126
Miyakawa, Natsuki N45‑4/p.216
Miyake, Masayasu M18‑26/p.243
M18‑20/p.243
Miyamoto, Jun R04‑6/p.106
Miyaoka, Robert S
M18‑45/p.245
M21‑50/p.260
M21‑46/p.259
M18‑40/p.244
Miyasaka, Hiromasa R05‑5/p.124
Miyatake, Hiroki M15‑1/p.226
Miyoshi, Toshinobu N1‑227/p.104
N42‑1/p.186
N44‑1/p.215
Mizuno, Tsunefumi N28‑8/p.165
Mkrtchyan, Hamlet N14‑142/p.140
Mller, Andreas M16‑12/p.232
HT‑2‑2/p.75
Mo, Chuan N21‑3/p.159
Mocek, Tomas N29‑5/p.177
Moch, David N1‑230/p.104
Modersitzki, Jan M15‑35/p.228
M15‑43/p.229
Modgil, Dimple M20‑1/p.220
Moein Azad, Samad M18‑46/p.245
Mohamad Hadi, Abdul Fattah M10‑34/p.205
Mohammednur, Abdella M13‑6/p.218
Mohapatra, Sucheta M21‑44/p.259
Mohr, Wolfgang N31‑4/p.178
Mohy‑ud‑Din, Hassan M15‑66/p.231
M22‑64/p.265
Mok, Greta SM14‑2/p.219
M16‑38/p.234
M15‑21/p.227
Molina Perez, Jorge N14‑62/p.133
Molina, Jorge N21‑7/p.160
Moliner, Laura N1‑194/p.102
M09‑46/p.199
Molnar, Jozsef M21‑27/p.258
N14‑119/p.138
N14‑182/p.143
Mondragon‑Contreras, Luis N1‑208/p.103
Moneta, Lorenzo N14‑89/p.136
Mongelli, Maurizio N13‑2/p.122
Monnet, Olivier JMR‑5/p.125
Monno, Emilio M10‑60/p.207
Montemont, Guillaume M17‑39/p.240
JMR‑5/p.125
M19‑7/p.220
R09‑5/p.170
Montemurro, Giuseppe V
M21‑17/p.257
N14‑217/p.146
Monzo, Jose MN14‑99/p.136
M16‑42/p.234
Moock, Verena M
M18‑83/p.248
Moon, M. K. N1‑147/p.98
Moon, Steven N8‑3/p.119
Moor, Andrew PM16‑6/p.231
Moore, Jared WM18‑43/p.245
Moore, Ronald M17‑62/p.241
Moore, Stephen C
M15‑58/p.230
M10‑45/p.206
M15‑27/p.228
M21‑43/p.259
M22‑60/p.265
Mora, Francisco J
M16‑42/p.234
Moralles, Mauricio M10‑22/p.204
Moravec, Pavel R10‑7/p.171
R04‑70/p.111
Morel, Christian M21‑9/p.256
M21‑16/p.257
M08‑1/p.190
Morel, Fredric N44‑4/p.215
Morello, Gianfranco N13‑2/p.122
Moresco, Rosa Maria M15‑4/p.226
Moretti, Federico N26‑7/p.163
Morgan, Brendan E
N1‑30/p.89
N1‑4/p.87
Morganti, Silvio N1‑114/p.96
Mori, Hisashi R10‑4/p.171
Mori, Toshinori N22‑7/p.160
Mori, Wakana N14‑45/p.132
N17‑6/p.157
Morigi, Maria Pia M09‑18/p.197
M21‑3/p.256
Morishima, Kunihiro N27‑5/p.164
Morita, Takeshi N1‑217/p.103
Moritake, Takashi N14‑173/p.142
Moriya, Takahiro M16‑15/p.232
M13‑5/p.218
M18‑41/p.244
M18‑28/p.244
Morone, Maria Cristina N7‑7/p.118
Moroni, Luigi N40‑4/p.184
Morozov, Andrei N21‑6/p.160
Morris, Scott JN15‑8/p.155
Morsani, Fabio N44‑6/p.215
N29‑2/p.177
Morse, D. HN42‑4/p.186
Morse, John N2‑7/p.82
N1‑237/p.105
Morse, William N39‑4/p.184
Morteau, Eric M10‑34/p.205
N14‑31/p.131
Mory, Cyril M09‑29/p.198
Moser, Hans‑Guenther N34‑6/p.180
N33‑3/p.179
N40‑3/p.184
Moses, Edward INP2‑2/p.81
Moses, William W
N1‑212/p.103
M18‑11/p.242
M09‑62/p.200
Moshe, M. BN31‑7/p.179
Mosher, David N11‑3/p.121
N42‑5/p.186
Moskaleva, Alexandra N35‑3/p.181
Moszyński, Marek N1‑139/p.97
N34‑5/p.180
N1‑148/p.98
N22‑3/p.160
N1‑131/p.97
N1‑67/p.92
N30‑2/p.178
Motakef, Shariar N1‑136/p.97
R13‑1/p.194
N10‑5/p.120
Motomura, Shinji M16‑40/p.234
N1‑204/p.102
Motoyoshi, Makoto N44‑1/p.215
Motuk, Erdem N14‑108/p.137
Moulin, Jean‑Francois N1‑109/p.95
Mowrer, Matthew N14‑40/p.131
Mozenson, Olga N44‑8/p.215
Mozin, Vladimir N14‑136/p.139
N1‑44/p.90
Mozzanica, Aldo N2‑8/p.82
N4‑7/p.83
Mrowka, Stanley N1‑60/p.91
N11‑5/p.121
Muehlbauer, Joerg N1‑188/p.101
Muelhens, Oliver M12‑2/p.192
Mueller, Andreas JNM‑6/p.126
Mueller, Felix N40‑3/p.184
Mueller, Kerstin M19‑8/p.220
Mueller, Klaus M17‑8/p.237
Mueller, Martin N1‑109/p.95
Mueller, Stefan PM10‑45/p.206
Mueller, Walter F
N25‑6/p.162
Muenstermann, Daniel N14‑216/p.146
N33‑4/p.180
Mueskes, Stefan N1‑68/p.92
Mukherjee, Joyeeta M
M16‑34/p.234
M17‑58/p.241
Mukhopadhyay, Sanjoy R04‑1/p.106
Mukhurov, Nikolai I
N1‑188/p.101
Mullen, Gregory E
M21‑29/p.258
Mullens, James A
N11‑7/p.121
Muller, Hans N32‑7/p.179
Muller, Ulrich N1‑69/p.92
Mullick, Rakesh M23‑2/p.255
M15‑49/p.229
Mulligan, Padhraic L
N1‑28/p.89
N42‑2/p.186
N5‑5/p.117
Mullins, John TR14‑6/p.195
R02‑5/p.84
Mulnix, Tim M14‑5/p.219
M15‑36/p.228
M02‑5/p.166
M07‑4/p.189
M19‑1/p.219
Mundler, Olivier M10‑62/p.207
Munro, Peter RM22‑24/p.262
Muraglia, M. N1‑130/p.97
Muramatsu, S. R07‑1/p.169
Muraro, Silvia N14‑176/p.142
Murat, Pasha M09‑61/p.200
Murat, Pavel N1‑111/p.95
N14‑166/p.141
M16‑72/p.237
Murayama, Hideo M16‑15/p.232
M15‑1/p.226
M09‑76/p.201
M18‑31/p.244
M16‑59/p.236
M16‑29/p.233
M16‑16/p.232
M22‑2/p.260
M13‑5/p.218
M10‑61/p.207
M12‑5/p.192
Murayama, Hitoshi LC1‑4/p.86
Murer, David N1‑12/p.88
He‑2‑3/p.225
Murphy, Donald P
N1‑42/p.90
N42‑5/p.186
Murphy, John WN1‑71/p.92
Murtas, Fabrizio He‑2‑5/p.225
N21‑4/p.159
Musa, Luciano N6‑6/p.118
Musico, P. M16‑11/p.232
Mussgiller, Andreas N24‑1/p.161
Muzi, Mark M22‑32/p.263
Muzykov, Peter G
R07‑2/p.169
Mycielski, Andrzej R04‑45/p.109
R04‑50/p.109
R11‑1/p.193
Myers, Eliot RN1‑42/p.90
He‑2‑7/p.225
Myjak, Mitchell J
N15‑8/p.155
Myronakis, Marios E
R15‑3/p.221
M10‑65/p.207
JMR‑2/p.125
n
Naaman, Charles M21‑33/p.258
M21‑41/p.259
Nacev, Alek M20‑7/p.220
Nachtrab, Frank R04‑52/p.109
N14‑179/p.143
Nadler, Jason N26‑1/p.163
Naeem, Syed FN14‑81/p.135
Nagamatsu, Aiko N37‑8/p.183
Naganawa, Naotaka N27‑5/p.164
Nagano, Tatsuya M18‑57/p.246
Nagano, Terumasa N22‑2/p.160
Nagao, Sho N1‑69/p.92
Nagarkar, Vivek V
N26‑2/p.163
N1‑234/p.104
M13‑3/p.218
JNMR‑6/p.126
Nagata, Shinji N1‑160/p.99
Nagatomo, Yoshiki N44‑1/p.215
N1‑227/p.104
Nagy, Ferenc M21‑27/p.258
N14‑119/p.138
N14‑182/p.143
M10‑37/p.205
Nakajima, Yasunori M06‑2/p.188
Nakamori, Takeshi N12‑6/p.122
M16‑17/p.232
M16‑25/p.233
Nakamura, Mitsuhiro N27‑5/p.164
Nakamura, Satoshi N
N1‑69/p.92
Nakamura, Shigeyuki M16‑17/p.232
Nakamura, Sigeyuki M16‑25/p.233
Nakamura, Takashi N14‑199/p.145
Nakamura, Tatsuya N1‑70/p.92
N1‑140/p.98
N1‑103/p.95
Nakamura, Yasuaki M10‑16/p.203
N14‑175/p.142
Nakanishi, Satoru M10‑41/p.205
M18‑75/p.247
Nakano, Masahiro M22‑39/p.263
Nakano, Takashi N14‑162/p.141
Nakano, Toshiyuki N27‑5/p.164
Nakashima, Shinya N36‑4/p.182
Nakayama, Hirofumi N14‑162/p.141
M16‑48/p.235
Nakazawa, Dante R
N1‑167/p.100
N1‑35/p.89
Nakazawa, Masayuki M09‑64/p.200
Nakonechnyi, Igor R13‑2/p.194
Author Index 299
Nam, Sang Hee R04‑68/p.111
M16‑69/p.236
R04‑69/p.111
Nam, Woo Hyun M17‑59/p.241
M17‑45/p.240
Namba, S. R07‑1/p.169
Nambiar, Neena N6‑8/p.118
Nam‑ho, Lee N1‑180/p.101
Namito, Yoshihito N14‑199/p.145
Nanal, Vandana N39‑2/p.183
Napolitano, Marco N14‑144/p.140
Narayanan, Manoj M10‑4/p.202
Narita, Shinya N14‑128/p.139
Nasr, Amgad KN1‑229/p.104
Natali, Dario N45‑7/p.216
Natori, Hiroaki N22‑7/p.160
Natsume, Takahiro M22‑40/p.263
M22‑39/p.263
Nause, Jeff N1‑91/p.94
Navab, Nassir M10‑75/p.208
M09‑48/p.199
Navalpakkam, Bharath K
M15‑19/p.227
Navarro, Jorge N27‑2/p.163
Nazari, Ali N9‑4/p.120
Neal, John SN26‑3/p.163
Neff, Stephan N28‑7/p.165
Negm, Hani N1‑18/p.88
Neher, Christian N35‑3/p.181
Neichi, Kazushi N14‑128/p.139
Nelms, Nick N14‑53/p.132
Nelson, Art JR12‑5/p.194
R08‑3/p.169
R04‑19/p.107
Nelson, Karl EN1‑37/p.90
N1‑31/p.89
N1‑53/p.91
N1‑15/p.88
Nelson, Kyle AN5‑3/p.117
N1‑94/p.94
Nelson, Timothy N35‑3/p.181
LC2‑4/p.86
Nemati, Ebrahim M13‑1/p.218
Nemeth, Gabor M21‑29/p.258
Nenonen, Seppo NR01‑1/p.223
Neo, Yoichiro R10‑4/p.171
Neshovska, Galina N1‑21/p.88
Nessi‑Tedaldi, Francesca N35‑4/p.181
N1‑133/p.97
Neuer, Marcus N41‑2/p.185
Neuman, Bartosz P
M17‑32/p.239
Neves, Jorge M10‑62/p.207
Newby, Jason N8‑5/p.119
Newcombe, Jane N37‑3/p.182
Newcomer, F MM18‑10/p.242
Ng, M. N1‑127/p.97
Ng, Ying WN38‑2/p.183
Nguyen, Long N26‑4/p.163
Nguyen, Mahn Hung N1‑20/p.88
Nguyen, Van‑Giang M09‑31/p.198
Nicholls, Tim N2‑3/p.81
N2‑5/p.82
Nico, Francois R10‑2/p.171
Niculae, Adrian N1‑156/p.99
Niemi, Jari M09‑11/p.196
Niessen, Katherine N14‑166/p.141
Nigg, David WN27‑2/p.163
Nikkel, James N1‑157/p.99
Nikl, Martin N1‑176/p.100
N1‑165/p.99
N1‑177/p.100
N26‑5/p.163
N1‑175/p.100
Niko, Hisako N21‑6/p.160
Nikolic, Rebecca J
R12‑5/p.194
N1‑108/p.95
R04‑19/p.107
R08‑3/p.169
Nilsson, Bjorn He‑1‑1/p.224
Nilsson, Hans‑Erik R15‑5/p.221
Ninkovic, Jelena N40‑3/p.184
N34‑6/p.180
Nino, Juan CR04‑71/p.111
Niraula, Madan R07‑1/p.169
Nishida, S. N14‑45/p.132
Nishida, Shohei N17‑6/p.157
Nishiguchi, Hajime N22‑7/p.160
Nishikawa, Keiko N1‑217/p.103
Nishikido, Fumihiko M16‑70/p.236
M16‑15/p.232
M10‑21/p.204
N14‑191/p.144
M22‑2/p.260
M18‑31/p.244
M16‑71/p.236
M18‑29/p.244
N14‑173/p.142
M13‑5/p.218
M12‑5/p.192
M10‑61/p.207
M16‑16/p.232
M09‑76/p.201
M06‑2/p.188
M16‑59/p.236
Nishimoto, Kei N1‑149/p.98
Nishimura, Hironobu N13‑8/p.123
Nishio, Teiji HT‑4‑4/p.77
N28‑3/p.164
Nishiyama, Shuske N39‑7/p.184
Nisius, Richard N33‑3/p.179
Nitanda, Fumino N1‑149/p.98
Nitta, Munetaka M16‑70/p.236
M13‑5/p.218
M16‑71/p.236
Niu, Ming M16‑2/p.231
Niu, Tianye M15‑10/p.226
M09‑25/p.197
Niu, Xiaofeng M15‑41/p.229
M15‑38/p.229
M10‑29/p.204
M17‑9/p.237
Nobe, Takuya N14‑229/p.147
Noel, Alain M10‑2/p.202
Noel, Scott N1‑30/p.89
N1‑4/p.87
Noeldgen, Holger M16‑50/p.235
Nogueira, Liebert P
M18‑81/p.247
Noh, Sung Jin R04‑68/p.111
R04‑69/p.111
Nolan, Paul JN18‑5/p.157
N8‑3/p.119
Noo, Frederic M17‑52/p.241
M17‑56/p.241
M17‑53/p.241
M20‑4/p.220
M17‑54/p.241
Noonan, Philip JM07‑8/p.190
M22‑50/p.264
Nordby, Martin N2‑7/p.82
Norlin, Borje R10‑3/p.171
Norman, Daren R
N1‑35/p.89
Normand, Stephane N41‑5/p.185
N30‑1/p.177
Norsworthy, Mark A
N1‑50/p.91
Novak, Gabor M23‑2/p.255
Novak, Roman M22‑18/p.262
Novotny, Rainer W
N35‑1/p.181
Nowack, Aaron N1‑60/p.91
Nowak, Gregor N1‑109/p.95
Nowak, Sebastian N14‑157/p.141
300 Author Index Nowakowski, Piotr R04‑45/p.109
R11‑1/p.193
Nowicki, Suzanne F
N36‑7/p.182
N1‑86/p.93
Nsiah‑Akoto, Irene M18‑50/p.245
Nukariya, Atsushi N14‑129/p.139
Nutbeam, Sian LN1‑22/p.88
Nuyens, Dieter M19‑8/p.220
Nuyts, Johan LM09‑16/p.197
M18‑87/p.248
M04‑7/p.168
M04‑1/p.167
Nyaga, Agata M21‑17/p.257
Nye, Jonathon AM18‑39/p.244
Nygard, Einar R01‑2/p.84
JMR‑4/p.125
Nykoniuk, Yevhen R13‑2/p.194
Nyui, Yoshiyuki M16‑18/p.232
o
Oakes, Thomas M
He‑2‑7/p.225
N1‑42/p.90
Oakham, G. N1‑30/p.89
Oakham, Gerald N1‑4/p.87
Obata, Takayuki M10‑61/p.207
M10‑54/p.206
Oberling, Michael B
N20‑2/p.158
Occhipinti, Michele N1‑158/p.99
OCHI, Atsuhiko N14‑131/p.139
O’Connor, Paul M10‑64/p.207
M18‑24/p.243
N14‑43/p.132
Ocsovaine Steinbach, Cecilia M10‑6/p.202
Oda, Keiichi M15‑1/p.226
Odaka, Hirokazu N28‑8/p.165
Odille, Freddy M11‑8/p.191
O’Dougherty, Patrick N1‑10/p.88
Oelfke, Uwe R10‑1/p.171
Oelhafen, Markus M22‑1/p.260
Offerman, Erik S. M22‑38/p.263
Ogawa, Koichi M16‑18/p.232
M18‑57/p.246
Ogawa, Satoru N14‑45/p.132
N17‑6/p.157
Oger, Tugdual M10‑34/p.205
N14‑31/p.131
Ogorodnik, Yaroslav R12‑2/p.193
R03‑2/p.85
Oh, Chang Hyun M10‑78/p.208
Oh, Hyun‑Hwa M18‑62/p.246
Oh, Kyung min M16‑69/p.236
OHalloran, Martin M10‑71/p.208
Ohata, Toru N23‑5/p.161
N23‑6/p.161
R10‑5/p.171
Ohgaki, Hideaki N1‑51/p.91
Ohi, Junichi M09‑64/p.200
Ohmoto, Takafumi N44‑2/p.215
N1‑193/p.102
N36‑4/p.182
Ohno, Masanori N28‑8/p.165
Ohta, Masayuki N28‑8/p.165
Ohtaka, Masahiko M16‑52/p.235
Okamoto, Tamotsu R04‑30/p.108
Okihara, Masao N44‑2/p.215
N1‑227/p.104
N44‑1/p.215
Oktay, M BM23‑6/p.255
M07‑2/p.189
M09‑34/p.198
Oku, Takayuki N13‑8/p.123
Okwechime, Ifechukwude O
R04‑26/p.107
Olcott, Peter DM21‑42/p.259
M11‑3/p.191
M09‑63/p.200
M08‑7/p.190
M16‑9/p.232
Olesinski, Stephan N1‑23/p.89
Oliveira, Carlos C
M18‑85/p.248
Oliveira, Luciano F
M21‑24/p.258
Oliveira, Luis FM18‑49/p.245
Oliveira, Rui dN14‑131/p.139
Oliver, Bryan N11‑5/p.121
Oliver, Josep FM05‑5/p.188
M15‑39/p.229
M17‑5/p.237
M16‑62/p.236
M16‑45/p.234
Olives‑Mallory, Kelsey N31‑1/p.178
N31‑2/p.178
N5‑2/p.117
Olivo, Alessandro M16‑64/p.236
M22‑24/p.262
Olschner, Fred R03‑2/p.85
R03‑3/p.85
Omachi, Chihiro HT‑4‑4/p.77
O’Malley, John N11‑2/p.121
N1‑5/p.87
N1‑9/p.87
N15‑1/p.155
Omer, Mohamed N1‑18/p.88
Omodani, Motohiko N44‑2/p.215
N1‑227/p.104
Omura, Tomohide M16‑15/p.232
M18‑28/p.244
M18‑41/p.244
Onabe, Hideaki M16‑52/p.235
Onderisinova, Zuzana N1‑165/p.99
O’Neal, Sean N26‑4/p.163
ONeill, Kevin M13‑2/p.218
Ong, D. N1‑30/p.89
Ono, Koji N1‑82/p.93
Ono, Shun N44‑2/p.215
N2‑1/p.81
Onodera, Toshiyuki R04‑28/p.108
R03‑1/p.85
R11‑5/p.193
Ootani, Wataru N22‑7/p.160
Opposits, Gabor M10‑37/p.205
M10‑77/p.208
Orchard, Gloria M
N39‑3/p.184
Orduna, Thierry R04‑40/p.109
Orero, Abel M09‑46/p.199
N1‑194/p.102
Orio, Filippo N1‑114/p.96
Orita, Tadashi N14‑175/p.142
N14‑23/p.130
Orrell, John LN1‑124/p.96
Orsi, Silvio N36‑1/p.181
Orsilini Cencelli, Valentino M16‑39/p.234
Orsini, Fabienne N24‑7/p.162
N44‑4/p.215
Orsolini Cencelli, Valentino M22‑17/p.262
Ortigao, Catarina M15‑56/p.230
M15‑29/p.228
Ortuno, Juan Enrique M22‑24/p.262
Osborne, Dustin R
M10‑1/p.202
O’Shea, Val N2‑5/p.82
R15‑5/p.221
R10‑3/p.171
Ostapov, Sergii R04‑44/p.109
O’Suilleabhin, Liam D
M22‑31/p.263
O’Sullivan, Finbarr M22‑31/p.263
M15‑2/p.226
M22‑32/p.263
O’Sullivan, Janet M15‑2/p.226
O’Sullivan, Joseph A
M16‑44/p.234
M21‑22/p.257
M18‑1/p.242
Osvet, Andres R04‑36/p.108
Oszlanszki, Attila M18‑76/p.247
Ota, Shinsuke N31‑5/p.178
Ote, Kibo M18‑28/p.244
Ott, Sebastian N13‑3/p.122
Ouamara, Hamid M21‑9/p.256
Ouedraogo, Serge A
N1‑173/p.100
Oumano, Michael HT‑4‑2/p.77
Ourselin, Sebastien M17‑37/p.240
M22‑35/p.263
M15‑9/p.226
M09‑24/p.197
M08‑3/p.190
M03‑6/p.167
M23‑3/p.255
Ouspenski, Vladimir N1‑135/p.97
N26‑6/p.163
Ouyang, Xiaoping N14‑4/p.129
Ovchinnikov, Oleg M05‑3/p.188
Ovechkina, Lena M13‑3/p.218
Overholt, Matthew N1‑136/p.97
R13‑1/p.194
Overman, Cory T
N1‑124/p.96
N14‑123/p.138
Owens, Alan N1‑163/p.99
R03‑5/p.85
Oxley, David CHT‑3‑1/p.76
M06‑3/p.189
M22‑8/p.261
M22‑13/p.261
Ozaki, Kyosuke N2‑1/p.81
Ozaki, Masanobu N28‑8/p.165
Ozsahin, Ilker M16‑46/p.235
p
Padovani, Enrico N15‑2/p.155
N14‑77/p.135
Paerker, Sherwood N44‑7/p.215
Paganetti, Harald M22‑23/p.262
Pagano, Angelo N20‑6/p.159
N14‑217/p.146
Pagano, Emanuele V
N14‑217/p.146
N20‑6/p.159
Paganoni, Anna Maria N14‑66/p.134
Paganoni, Marco M16‑61/p.236
N28‑2/p.164
M10‑62/p.207
Page, Ryan FM06‑1/p.188
Paglia, Claudio N14‑144/p.140
Pain, Frederic M21‑16/p.257
Pakou, Athena N14‑113/p.137
Palamakumbura, Senerath N26‑2/p.163
Palladino, Vito N14‑144/p.140
Pallotta, Stefania M17‑15/p.238
N14‑177/p.143
M06‑6/p.189
Palubiak, Darek M13‑1/p.218
Pan, Tinsu M22‑34/p.263
Pan, Xiaochuan M17‑21/p.238
M17‑22/p.238
M17‑23/p.239
M17‑34/p.239
M17‑36/p.239
M20‑2/p.220
Panagiotou, Christos M22‑35/p.263
Panchuk, Oleg R13‑2/p.194
R04‑46/p.109
Pande, Reena LM22‑60/p.265
Pandian, Lakshmi S
He‑2‑4/p.225
N1‑38/p.90
Panetta, Joseph V
M18‑10/p.242
Pang, Hongchao N1‑27/p.89
Pani, Roberto M16‑39/p.234
Pani, Silvia M15‑65/p.231
M16‑13/p.232
Panier, Sylvain M05‑6/p.188
Panin, Vladimir Y
M23‑1/p.255
M15‑40/p.229
M04‑7/p.168
Panisko, Mark EN14‑123/p.138
Panse, Ashish M10‑58/p.206
Pansu, Robert N41‑5/p.185
Paoloni, Alessandro N14‑176/p.142
Paolucci, Pier SN14‑36/p.131
Paoluzzi, Giovanni N14‑233/p.147
Papa, Massimo N14‑217/p.146
N20‑6/p.159
Papakostantinou, Ioannis N28‑2/p.164
Pappalardo, Alessandro M16‑11/p.232
M10‑60/p.207
Paquit, Vincent C
N8‑8/p.119
Paradiso, Daniele N1‑118/p.96
Parages, Felipe M
M22‑67/p.265
Pardi, Silvio N43‑9/p.187
N14‑80/p.135
N14‑72/p.134
N14‑71/p.134
Park, Byung Kwan M16‑24/p.233
Park, H. N1‑137/p.97
N1‑147/p.98
Park, Ha Ryung M15‑18/p.227
R04‑49/p.109
Park, Hanho M16‑54/p.235
M16‑58/p.235
Park, Hye‑Suk M18‑65/p.246
Park, Hyun‑wook M10‑78/p.208
Park, Il H N1‑218/p.103
Park, Ji koon M16‑69/p.236
Park, Ji‑Ae M15‑63/p.230
M22‑68/p.265
M21‑48/p.259
Park, Jin Hyung N1‑199/p.102
Park, Jong Hoon N14‑178/p.143
Park, Mi‑Ae M15‑27/p.228
M10‑45/p.206
M15‑58/p.230
M21‑43/p.259
M22‑60/p.265
Park, Min Jae M10‑48/p.206
Park, Miran M09‑52/p.199
Park, Ryan M21‑13/p.257
Park, Ryeojin M03‑1/p.166
Park, Seong Hee N1‑18/p.88
Park, Seongtae N38‑2/p.183
N38‑1/p.183
Park, Seyjoon M22‑19/p.262
Park, Shin‑Woong N1‑198/p.102
Park, Su‑Jin M16‑10/p.232
Author Index 301
M18‑56/p.246
M09‑33/p.198
Park, Sung Yong M22‑12/p.261
M22‑19/p.262
Park, Sung Kwang R04‑69/p.111
Parker, Andrew JN1‑13/p.88
Parker, Colin N18‑7/p.157
Parker, Elaine MHe‑1‑8/p.224
Parker, Joseph DN13‑8/p.123
Parker, Sherwood I
N14‑154/p.140
N1‑233/p.104
Parl, Christoph JNM‑7/p.126
M21‑26/p.258
Parmar, Arvind M21‑31/p.258
Parnham, Kevin M18‑12/p.243
M10‑79/p.208
Parodi, Katia M22‑13/p.261
M22‑10/p.261
HT‑2‑4/p.75
JNM‑5/p.126
M22‑16/p.261
HT‑2‑1/p.75
Parsani, Tommaso N20‑6/p.159
N14‑217/p.146
Parsons, Ann MN36‑7/p.182
N1‑86/p.93
Parthier, Lutz N1‑163/p.99
Parzefall, Ulrich N25‑3/p.162
N17‑1/p.156
R04‑3/p.106
Pascazio, Vito M22‑51/p.264
Paschen, Uwe N34‑3/p.180
Paschuk, Sergei N14‑78/p.135
Pascovici, George N14‑21/p.130
Passaleva, Giovanni N14‑125/p.138
Passeri, Daniele N14‑200/p.145
Passuello, Diego N14‑15/p.130
Patay, Gergely M04‑3/p.167
Pater, Jo N14‑164/p.141
Patera, Vincenzo N14‑176/p.142
Patlolla, Dilip RN8‑8/p.119
Pato, Lara RM09‑71/p.201
Paton, Katherine M22‑3/p.260
Patt, Bradley M17‑62/p.241
Patyal, Baldev N14‑189/p.144
Paul, Stephan M21‑19/p.257
Paulin, Caroline M05‑6/p.188
Paulus, Caroline R09‑5/p.170
Pausch, Guntram N8‑4/p.119
N41‑2/p.185
Pauss, Felicitas N1‑133/p.97
Pauwels, Kristof M16‑61/p.236
N28‑2/p.164
N41‑6/p.185
Pavesi, Maura R07‑3/p.169
Pavlick, Jason N9‑8/p.120
Pavlov, Nikolai M21‑32/p.258
M13‑2/p.218
Pawelczak, Iwona A
N1‑105/p.95
Payne, Stephen A
R12‑5/p.194
N26‑4/p.163
N41‑3/p.185
R04‑19/p.107
R08‑3/p.169
N1‑105/p.95
Paysan, Pascal M22‑1/p.260
Pearce, Mark N36‑2/p.181
Peaupardin, Philippe N39‑2/p.183
Pedash, Vyacheslav Y
N14‑63/p.133
M10‑27/p.204
Pedemonte, Stefano M23‑3/p.255
M17‑37/p.240
M15‑9/p.226
M09‑24/p.197
M08‑3/p.190
M04‑6/p.168
M03‑6/p.167
Pedersen, Ulrik N2‑3/p.81
Peerani, Paolo N1‑110/p.95
N14‑77/p.135
N1‑92/p.94
Pellegri, Luna N1‑151/p.98
Pellegrini, Giulio N14‑154/p.140
N14‑158/p.141
N14‑58/p.133
N5‑1/p.117
N44‑7/p.215
N25‑2/p.162
N14‑197/p.144
N14‑57/p.133
Pellegrini, Rosanna M16‑39/p.234
Pelletier, Christopher D
M10‑7/p.203
Pelosi, Alessandro N13‑2/p.122
Peloso, Roberta N45‑8/p.216
N1‑119/p.96
N45‑7/p.216
N14‑53/p.132
N1‑158/p.99
N14‑54/p.133
Pelowitz, Denise B
N7‑1/p.118
Peltonen, Sari M22‑48/p.264
Peng, Hao M21‑39/p.259
M13‑1/p.218
M10‑43/p.205
M16‑73/p.237
M15‑62/p.230
Peng, Qiyu M18‑11/p.242
N1‑212/p.103
Peng, Wenxi R04‑37/p.108
Penn, David N1‑54/p.91
Pennazio, Francesco M21‑23/p.257
Penny, Robert N1‑53/p.91
Pepin, Catherine M05‑6/p.188
Perali, Irene M22‑20/p.262
Pereira, Fabio N13‑7/p.123
Pereira, Luis N21‑6/p.160
Perevertaylo, Vladimir N44‑3/p.215
Pereverzev, Sergey V
N14‑136/p.139
N39‑6/p.184
Perez, Alejandro N14‑80/p.135
N14‑71/p.134
N14‑72/p.134
N43‑9/p.187
Perez, Jose MR04‑36/p.108
Perez‑Ponce, Hector M08‑1/p.190
Peric, Ivan N40‑3/p.184
N9‑7/p.120
N16‑7/p.156
Perkins, Amy EM10‑4/p.202
Perkins, Daniel N14‑40/p.131
Pernegger, Heinz N14‑216/p.146
Perot, Bertrand N27‑7/p.164
Perrella, Sabrina N14‑112/p.137
Perrey, Hanno N24‑4/p.161
N14‑213/p.146
Perrino, Roberto M16‑11/p.232
M10‑60/p.207
Perrodin, Didier N41‑6/p.185
Perry, John ON1‑164/p.99
Pervertaylo, Vladimir N14‑195/p.144
Pesic, Zoran N2‑3/p.81
Pessina, Gianluigi N14‑98/p.136
N1‑209/p.103
N14‑11/p.130
Pestotnik, Rok N14‑45/p.132
N17‑6/p.157
Petasecca, Marco N14‑193/p.144
N37‑7/p.183
N37‑6/p.182
N14‑196/p.144
N14‑195/p.144
N44‑3/p.215
N1‑216/p.103
Peter, Joerg M15‑29/p.228
M05‑1/p.188
M10‑62/p.207
Peter, Marleau N1‑60/p.91
Peters, Klaus N14‑156/p.141
Peterson, Bill M16‑57/p.235
Peterson, Todd EM10‑11/p.203
M05‑3/p.188
M10‑50/p.206
M16‑63/p.236
Petersson, Sture N14‑218/p.146
Petronio, Susan M16‑53/p.235
Petrosky, James C
N14‑6/p.129
N33‑7/p.180
N1‑93/p.94
Petrosyan, Gevorg N14‑237/p.147
Petrosyan, Lyudvig N14‑237/p.147
Petrosyan, Vahan N14‑237/p.147
Petta, Pasquale M10‑28/p.204
Petulla, Francesco M22‑17/p.262
Peurrung, Anthony J
N3‑1/p.82
Peyre, Jean N39‑2/p.183
Peyrin, Francoise M09‑29/p.198
Pfanner, Florian M18‑48/p.245
Pfeiffer, Andreas N14‑66/p.134
Philip, Dany M15‑37/p.229
Phillips, C. M21‑15/p.257
Phipps, David GN42‑5/p.186
N1‑9/p.87
Phlips, Bernard F
N1‑9/p.87
N15‑1/p.155
N11‑2/p.121
N42‑5/p.186
He‑2‑7/p.225
N11‑6/p.121
N1‑40/p.90
N14‑198/p.144
N18‑7/p.157
Pia, Maria Grazia N7‑4/p.118
N14‑240/p.136
N7‑8/p.118
N14‑66/p.134
N28‑5/p.165
N7‑3/p.118
N46‑8/p.217
N28‑7/p.165
N28‑6/p.165
N14‑65/p.134
Piana, Angelo N1‑111/p.95
N1‑187/p.101
M03‑3/p.167
N14‑166/p.141
Picciotto, Antonino N45‑8/p.216
N14‑53/p.132
Pichler, Bernd JM11‑7/p.191
JNM‑7/p.126
M10‑72/p.208
M11‑4/p.191
M15‑26/p.228
M21‑26/p.258
Pichotka, Martin P
R15‑4/p.221
JNMR‑4/p.126
R04‑12/p.107
Piemonte, Claudio N45‑8/p.216
N14‑53/p.132
N14‑32/p.131
N1‑206/p.102
N1‑203/p.102
N1‑171/p.100
M21‑5/p.256
Pierce, Larry AM21‑46/p.259
M15‑3/p.226
Piercey, Rodney B
N14‑100/p.137
Pierroutsakou, Dimitra N14‑113/p.137
Piersanti, Luca N14‑176/p.142
Pietropaolo, Antonino He‑2‑5/p.225
N21‑4/p.159
Pietrzak, Jakub M17‑4/p.237
Pietrzyk, Uwe M07‑6/p.190
Pikhay, Evgeny N14‑184/p.143
Pikna, Miroslav N14‑121/p.138
Pillon, Mario R07‑5/p.169
Pinci, Davide N33‑6/p.180
N14‑125/p.138
N1‑114/p.96
Pinder, Rodney R08‑4/p.170
Pinelli, Donald A
N1‑183/p.101
Pines, Jack N2‑7/p.82
N1‑237/p.105
N1‑238/p.105
Pinheiro, Christiano J
M18‑49/p.245
Pinot, Laurent M17‑61/p.241
M21‑16/p.257
Pinsard, frdric R10‑2/p.171
Pinto, Marco M22‑13/p.261
M22‑10/p.261
M10‑9/p.203
Pirrone, Sara N20‑6/p.159
N14‑217/p.146
Piscitelli, Francesco N1‑76/p.93
He‑1‑3/p.224
Pistorius, Stephen M16‑1/p.231
Piti, Zs M23‑2/p.255
Pizzichemi, Marco N28‑2/p.164
M10‑62/p.207
M16‑61/p.236
Placidi, Pisana N14‑200/p.145
Plackett, Richard N2‑3/p.81
Platsch, Günther M16‑32/p.233
Plautz, Tia N14‑192/p.144
R04‑24/p.107
Plaza, Jose Luis R04‑56/p.110
R08‑5/p.170
Plenevaux, Alain M21‑18/p.257
M21‑15/p.257
Plenteda, Romano N1‑110/p.95
N3‑2/p.82
Plettner, Cristina N41‑2/p.185
Plimley, Brian CN1‑220/p.103
N1‑221/p.103
Plucinski, Pawel N14‑118/p.138
Plumb, Andrew S
N14‑192/p.144
R04‑24/p.107
Pochodzalla, Josef N1‑69/p.92
Poeschl, Roman N35‑5/p.181
N14‑69/p.134
N14‑149/p.140
Pohjonen, Harri NR01‑1/p.223
Pohl, Martin NP2‑1/p.81
Pohl, Thomas M10‑56/p.206
Poitrasson‑Riviere, Alexis N1‑95/p.94
N23‑2/p.161
N1‑56/p.91
Polack, John KN1‑95/p.94
N23‑2/p.161
N1‑56/p.91
Polak, Ivo N14‑161/p.141
Poletti, Martin EM18‑86/p.248
Politi, Giuseppe N20‑6/p.159
N14‑217/p.146
Polycarpou, Irene M15‑45/p.229
Polychronakos, Venetios N6‑8/p.118
Pomper, Martin G
JNMR‑5/p.126
M07‑5/p.189
Ponchut, Cyril NR01‑7/p.223
Pooley, Daniel EN1‑63/p.92
N5‑7/p.117
Poon, Jonathan K
M10‑39/p.205
Popa, Emil M10‑5/p.202
Popescu, Lucretiu M
M09‑57/p.200
Popov, Vlladimir N14‑142/p.140
Popova, Elena N22‑4/p.160
Popovic, Kata M21‑47/p.259
Porro, Matteo N1‑230/p.104
N2‑4/p.81
N1‑228/p.104
N4‑8/p.83
Porto, Franco N20‑6/p.159
N14‑217/p.146
Pospisil, Stanislav N14‑181/p.143
N37‑4/p.182
JNMR‑3/p.126
R15‑1/p.221
N1‑106/p.95
R04‑59/p.110
Postranecky, Martin N14‑108/p.137
Potari, Norbert M10‑37/p.205
Poussier, Sylvain M10‑2/p.202
Pouthas, Joel N39‑2/p.183
Povoli, Marco N14‑204/p.145
N44‑7/p.215
Pozzi, Sara AN1‑89/p.94
N15‑2/p.155
N14‑77/p.135
N14‑81/p.135
N1‑50/p.91
N1‑92/p.94
N5‑8/p.117
N1‑56/p.91
N23‑2/p.161
N1‑95/p.94
Praetzel, Engelhard N1‑109/p.95
Pratte, Jean‑Francois N40‑2/p.184
N34‑2/p.180
M18‑24/p.243
M10‑47/p.206
N14‑43/p.132
M05‑6/p.188
Praus, Petr R04‑47/p.109
Pray, Danrae SN38‑1/p.183
N38‑2/p.183
Precious, John N15‑1/p.155
N1‑9/p.87
Prekas, Georgios R15‑7/p.221
R01‑1/p.84
Presotto, Luca M22‑52/p.264
M10‑28/p.204
Pressler, Daniel N1‑71/p.92
Pressyanov, Dobromir S
N1‑115/p.96
N1‑112/p.95
Preston, Jeff N8‑4/p.119
Preston, Rhys MN1‑219/p.103
Prestopino, Giuseppe R07‑5/p.169
Prettyman, Tom N1‑96/p.94
Price, Patrice MM22‑36/p.263
M17‑31/p.239
Prieels, Damien M22‑20/p.262
Priegnitz, Marlen HT‑2‑2/p.75
Priest, Anders PN29‑3/p.177
Pro, Tiziana N1‑206/p.102
Probst, Roland M18‑70/p.247
M20‑7/p.220
Prochazka, Andrej N9‑2/p.119
N14‑121/p.138
Procz, Simon R04‑12/p.107
JNMR‑4/p.126
Produit, Nicolas R04‑57/p.110
Prokopovich, Dale A
HT‑4‑7/p.77
R10‑6/p.171
N14‑194/p.144
M18‑8/p.242
N44‑3/p.215
Proksa, Roland M17‑20/p.238
Prokupek, Jan HT‑2‑3/p.75
N42‑6/p.186
N29‑5/p.177
Protic, D. N1‑127/p.97
Proudfoot, James N14‑159/p.141
N1‑184/p.101
Prout, David LM09‑80/p.201
M09‑81/p.201
M11‑2/p.191
Prusa, Petr N1‑175/p.100
N26‑5/p.163
Pucknell, Vic N8‑3/p.119
Puddu, Silvia N21‑4/p.159
Pugliatti, Cristina M17‑15/p.238
N40‑4/p.184
N14‑177/p.143
Puglisi, Donatella N29‑5/p.177
R12‑1/p.193
Puigdengoles, Carles N16‑3/p.156
Puill, Veronique N34‑1/p.180
Puill, Vronique M17‑61/p.241
Pulko, Jozef M21‑19/p.257
Pullia, Alberto N9‑6/p.120
R04‑58/p.110
N14‑9/p.129
N1‑29/p.89
N14‑21/p.130
N14‑22/p.130
Puriga, Ekaterina A
N14‑102/p.137
Purschke, Martin L
N43‑5/p.187
N14‑114/p.138
M18‑24/p.243
M10‑64/p.207
M13‑7/p.218
Puryga, Ekaterina A
N14‑103/p.137
N14‑101/p.137
Pusa, Petteri N18‑5/p.157
Pusuwan, Pawana M10‑36/p.205
M10‑48/p.206
Pyeon, Cheol Ho N1‑51/p.91
q
Qi, Jinyi M02‑2/p.166
M21‑34/p.258
M19‑4/p.219
M18‑42/p.245
M18‑22/p.243
M10‑39/p.205
M09‑39/p.198
M04‑4/p.167
M04‑2/p.167
M02‑4/p.166
Qi, Yujin N1‑216/p.103
Qian, Hua M10‑73/p.208
M15‑49/p.229
M19‑5/p.219
Qiang, Yi N1‑185/p.101
Qiu, Xuezhong M22‑70/p.266
Quagli, Tommaso N14‑219/p.146
Quaglia, Riccardo N1‑120/p.96
N14‑53/p.132
N14‑54/p.133
N45‑8/p.216
N9‑8/p.120
Quarati, Francesco N1‑163/p.99
R03‑5/p.85
Quartieri, Emanuele N4‑8/p.83
Querol, Marc N14‑116/p.138
Quevedo, Manuel N1‑71/p.92
Quick, Harald HM15‑19/p.227
Quillin, Stephen N1‑8/p.87
N8‑2/p.119
N1‑19/p.88
Quinlan, Michael N15‑7/p.155
N3‑7/p.82
N1‑48/p.90
Quintieri, Lina He‑2‑5/p.225
Author Index 303
N13‑2/p.122
Quinto, Michele A
M09‑19/p.197
Quirion, David N14‑197/p.144
N14‑58/p.133
N5‑1/p.117
Quiter, Brian JN15‑7/p.155
N1‑48/p.90
N3‑7/p.82
N27‑9/p.164
r
Ra, Jong Beom M17‑45/p.240
M17‑59/p.241
Rabinovitz, David N14‑201/p.145
Rachinhas, Paulo M22‑7/p.260
Radeka, Veljko N6‑1/p.117
Radev, Radoslav N1‑108/p.95
Radicci, Valeria N2‑8/p.82
Radle, James EN11‑7/p.121
Radley, Ian R04‑60/p.110
R04‑16/p.107
R13‑5/p.194
R14‑6/p.195
JMR‑2/p.125
Rafecas, Magdalena M17‑5/p.237
M22‑15/p.261
M16‑45/p.234
M05‑5/p.188
M15‑39/p.229
M16‑65/p.236
M16‑62/p.236
N14‑107/p.137
M06‑5/p.189
Raffanti, Rick N5‑7/p.117
Ragazzini, Luca M21‑3/p.256
Rahmim, Arman M15‑66/p.231
M07‑5/p.189
M17‑29/p.239
M18‑78/p.247
M22‑64/p.265
M23‑4/p.255
Rahni, Ashrani AM15‑23/p.227
Rakotozafindrabe, Andry N24‑7/p.162
Ralchenko, Victor G
R04‑29/p.108
Ralf, Roder N1‑179/p.100
Ralston, James N1‑28/p.89
Rama, Matteo N14‑71/p.134
N14‑72/p.134
N14‑80/p.135
N43‑9/p.187
Ramakers, Ruud R
M05‑4/p.188
Ramberg, Erik JM16‑72/p.237
N1‑111/p.95
N14‑166/p.141
N21‑7/p.160
M09‑61/p.200
N14‑203/p.145
N1‑187/p.101
Ramelli, Renzo N12‑7/p.122
Ramey, Joanne O
N26‑3/p.163
Ramirez Perez De Inestrosa, Javier M10‑14/p.203
Ramirez, Javier M22‑44/p.264
Ramirez, Rocio M21‑30/p.258
Ramirez‑Jaramillo, Rocio A
M03‑8/p.167
Ramirez‑Jimenez, Francisco J
N1‑208/p.103
Ramos, Emilie N1‑116/p.96
Ramsey, Brian DN1‑183/p.101
Ramseya, Brian D
N14‑55/p.133
Randazzo, Nunzio N14‑165/p.141
M17‑15/p.238
N14‑177/p.143
N40‑4/p.184
M06‑6/p.189
Ranieri, A. M16‑11/p.232
Ranieri, Antonio N13‑2/p.122
M10‑60/p.207
Rankine, Leith JM18‑34/p.244
M18‑33/p.244
Rannou, Fernando R
M09‑58/p.200
Rao, Triveni N39‑4/p.184
Rapsomanikis, Aristotelis‑Nikolaos M16‑41/p.234
M18‑73/p.247
M09‑77/p.201
Rarbi, Fatah N14‑39/p.131
Rarenko, Ilarii R04‑46/p.109
Rashevsky, Alexander N36‑5/p.182
N6‑5/p.118
Raspino, Davide He‑2‑5/p.225
N21‑6/p.160
Rathke, John LC5‑3/p.127
Ratti, Lodovico N44‑6/p.215
N14‑27/p.130
N29‑2/p.177
Rau, Chritsoph N2‑3/p.81
Raux, Ludovic N4‑1/p.83
M16‑65/p.236
Ravindranath, Bosky M21‑22/p.257
M18‑24/p.243
M18‑1/p.242
M16‑44/p.234
N43‑5/p.187
Rawool‑Sullivan, Mohini N14‑59/p.133
Ray, Cedric M18‑58/p.246
HT‑2‑5/p.75
JNM‑5/p.126
M10‑9/p.203
N16‑2/p.156
M22‑10/p.261
Ray, Saswati N1‑15/p.88
N1‑31/p.89
Raychaudhuri, Siba P
M05‑2/p.188
Raylman, Raymond R
M10‑76/p.208
M16‑68/p.236
Re, Valerio N44‑6/p.215
N14‑27/p.130
Reader, Andrew J
M15‑15/p.227
M22‑69/p.266
M22‑36/p.263
M17‑49/p.240
M17‑31/p.239
M15‑57/p.230
M15‑14/p.227
M09‑23/p.197
M22‑61/p.265
M22‑55/p.264
M19‑3/p.219
Rebuffel, Veronique M10‑5/p.202
Reckleben, Christian N4‑8/p.83
Reed, Michael SN1‑43/p.90
Reed, Richard CN3‑5/p.82
Reedy, Edward TN1‑44/p.90
N1‑45/p.90
N11‑4/p.121
Rehak, Pavel N31‑6/p.178
N14‑43/p.132
Rehlich, Kay N14‑237/p.147
Reid, Chantal DN14‑188/p.144
N14‑190/p.144
Reilhac, Anthonin M14‑1/p.218
M10‑51/p.206
M15‑9/p.226
M21‑31/p.258
M21‑49/p.259
Reims, Nils M16‑66/p.236
Reinecke, Mathias N14‑143/p.140
Reinhard, Mark I
N1‑49/p.91
N14‑194/p.144
R10‑6/p.171
M18‑8/p.242
N44‑3/p.215
Reinhardt, Dirk M17‑60/p.241
304 Author Index Reinhold, Joerg N1‑69/p.92
Reis, Marilia AM21‑11/p.256
Reithinger, Valerian JNM‑5/p.126
M22‑10/p.261
N1‑116/p.96
Ren, Guohao N1‑138/p.97
N41‑7/p.185
Ren, Ran M19‑2/p.219
Ren, Wuwei M10‑19/p.204
M18‑5/p.242
Renard, Christophe N24‑7/p.162
Renard‑Le Galloudec, Nathalie N1‑60/p.91
N1‑14/p.88
Renaud, Jennifer M15‑44/p.229
Renault, Jean‑Philippe N37‑1/p.182
Renis, Marcella HT‑2‑3/p.75
N42‑6/p.186
Renk, Timothy N11‑5/p.121
Renker, Dieter N37‑2/p.182
Renz, Wolfgang M02‑3/p.166
M18‑2/p.242
Renzi, Ronald FN11‑5/p.121
N1‑99/p.94
Repond, Jose LC3‑3/p.127
Requardt, Herwig N14‑195/p.144
Resanovic, Rajko R04‑55/p.110
Rescia, Sergio N39‑4/p.184
Resnick, Paul JN15‑3/p.155
Reszka, Anna R04‑45/p.109
R04‑50/p.109
R11‑1/p.193
Rethfeldt, Christoph He‑1‑5/p.224
Retico, Alessandra N43‑2/p.186
Retiere, Fabrice N32‑5/p.179
N22‑5/p.160
M21‑25/p.258
M16‑37/p.234
M10‑42/p.205
M16‑23/p.233
Reyna, David N1‑90/p.94
N27‑4/p.164
Reynard‑Carette, Christelle N27‑3/p.164
N1‑130/p.97
Reynolds, Paul D
M09‑83/p.202
M18‑16/p.243
M21‑36/p.259
Rezaei, Ahmadreza M04‑7/p.168
M04‑1/p.167
M09‑16/p.197
Reznik, Alla R07‑4/p.169
Rheaume, Vincent‑Philippe N40‑2/p.184
N34‑2/p.180
Rhee, June Tak M10‑69/p.208
Rhodes, Nigel JN21‑6/p.160
N21‑1/p.159
N1‑63/p.92
N21‑5/p.160
N21‑2/p.159
He‑1‑4/p.224
N1‑61/p.91
Ribezl, E. N14‑45/p.132
Riboldi, Marco M22‑16/p.261
Riboldi, Stefano N14‑111/p.137
N1‑151/p.98
N14‑9/p.129
N1‑113/p.96
N14‑34/p.131
Ribon, Alberto N14‑66/p.134
Riccio, Filippo N14‑217/p.146
N20‑6/p.159
Richard, Marie‑Helene M22‑10/p.261
Richter, Rainer H
N4‑3/p.83
N34‑6/p.180
N33‑3/p.179
N40‑3/p.184
Richter, Robert N14‑157/p.141
N13‑3/p.122
Ricketts, Kate M21‑17/p.257
Rico, Javier N45‑2/p.216
Riedel, Richard A
N1‑77/p.93
N1‑81/p.93
Rigie, David SM20‑1/p.220
M20‑6/p.220
Riklund, Katrine M15‑24/p.227
Rimoldi, Ornella M22‑52/p.264
Rinaldi, Ilaria M22‑10/p.261
Ring, Terry AN27‑2/p.163
Rink, Kristian R10‑1/p.171
Ripamonti, Giancarlo N14‑109/p.137
Rissi, Michael M09‑45/p.199
M16‑31/p.233
Rit, Simon M09‑29/p.198
M18‑58/p.246
Ritschl, Ludwig M14‑3/p.219
M10‑33/p.205
Ritt, Stefan M11‑4/p.191
N14‑166/p.141
N1‑111/p.95
Rittenbach, Andrew J
M10‑79/p.208
M18‑12/p.243
JNMR‑5/p.126
Ritter, Greg N1‑26/p.89
Ritzert, Michael N14‑37/p.131
N16‑7/p.156
N14‑32/p.131
Rivera, Ryan RN40‑4/p.184
Rivera‑Islas, Refugio Ivan M18‑60/p.246
Rivetti, Angelo N16‑4/p.156
Rizzo, Francesca N20‑6/p.159
N14‑217/p.146
Rizzo, Giuliana N29‑2/p.177
N44‑6/p.215
Robert, Aymeric N1‑237/p.105
Robert, Charlotte HT‑4‑6/p.77
Roberts, Barry M18‑6/p.242
Roberts, Oliver N39‑2/p.183
Robertson, Gideon K
N1‑99/p.94
N1‑84/p.93
Robertson, J LN1‑87/p.94
Robertson, R G H
N14‑35/p.131
Robertson, Stacey N1‑19/p.88
N1‑8/p.87
N8‑2/p.119
Robichaud, Adam N1‑30/p.89
N1‑4/p.87
Robinson, Sean M
N8‑1/p.119
Robson, Clyde CN14‑118/p.138
Rocha, Licinio N30‑1/p.177
N41‑5/p.185
Rocha‑Leao, Cedric R11‑4/p.193
Rodrguez, Javier N14‑116/p.138
Rodrguez‑Villafuerte, Mercedes M02‑2/p.166
M18‑22/p.243
Rodrigues, Barbara R09‑6/p.170
Rodrigues, Fabiana M15‑56/p.230
Rodrigues, Pedro M10‑4/p.202
M12‑2/p.192
M10‑3/p.202
Rodriguez, Douglas C
N15‑4/p.155
N1‑47/p.90
Rodriguez, Joaquin N14‑197/p.144
N5‑1/p.117
Rodriguez, Maria Jose M09‑46/p.199
N1‑194/p.102
Rodriguez, Mauricio R04‑66/p.111
Rodriguez, Olga M20‑7/p.220
Roellinghoff, Frauke M22‑10/p.261
M22‑20/p.262
Roemer, Katja N8‑4/p.119
Roessl, Ewald M17‑20/p.238
Rogalla, P M17‑23/p.239
Rogers, A MN20‑2/p.158
Rogers, Sarah EN1‑63/p.92
Rogerson, Jr., William T
He‑1‑8/p.224
Rohkohl, Christopher M19‑8/p.220
Rohling, Heide M16‑12/p.232
M06‑5/p.189
HT‑2‑2/p.75
JNM‑6/p.126
Rohne, Ole M16‑31/p.233
Rohrer, John LN15‑8/p.155
Roizin, Yakov N14‑184/p.143
Rollet, Christine M18‑6/p.242
Rolo, Manuel DN16‑4/p.156
Romani, Francesco HT‑2‑3/p.75
Romano, Francesco N42‑6/p.186
M17‑15/p.238
N14‑165/p.141
N14‑176/p.142
N14‑177/p.143
M22‑24/p.262
Ron, Wurtz N1‑173/p.100
Roncali, Emilie M03‑2/p.167
M21‑32/p.258
Rong, Xing M15‑50/p.230
M16‑19/p.233
Ronzhin, Anatoly I
N1‑187/p.101
M16‑72/p.237
M09‑61/p.200
N14‑166/p.141
N1‑111/p.95
Roodman, Aaron J
N14‑46/p.132
Rooh, Gul N1‑147/p.98
N1‑137/p.97
Ropelewski, Leszek N38‑7/p.183
Ros Garcia, Ana M16‑42/p.234
N1‑194/p.102
N14‑99/p.136
Ros, Domenec M09‑53/p.200
Roscilli, Lorenzo N14‑144/p.140
Rosen, Marc DN5‑2/p.117
N31‑2/p.178
N31‑1/p.178
Rozenfeld, Anatoly B
N37‑7/p.183
N14‑196/p.144
N1‑216/p.103
N14‑194/p.144
N14‑193/p.144
N44‑3/p.215
N37‑6/p.182
N14‑184/p.143
N14‑195/p.144
Ross, C. N1‑127/p.97
Ross, Marc CLC6‑1/p.128
LC5‑1/p.127
Ross, Steven GM23‑7/p.255
Ross, Steven JN31‑1/p.178
N31‑2/p.178
N5‑2/p.117
Rossall, Andrew K
JMR‑2/p.125
Rossetti, Davide N14‑36/p.131
Rosso, Valeria M22‑24/p.262
Rosson, Robert N26‑1/p.163
Rota Kops, Elena M15‑33/p.228
Rothfuss, Harold E
N30‑5/p.178
Rousseau, Marc N39‑2/p.183
HT‑4‑3/p.77
M18‑79/p.247
Rousseau, Marissa N1‑26/p.89
Rovenskikh, Andrey F
N14‑102/p.137
Rowlands, John R07‑4/p.169
Roy, Supratik M15‑2/p.226
Royle, Gary M21‑17/p.257
Royon, Christophe N17‑7/p.157
Royston, Katherine K
M10‑30/p.204
Roza, Neil N15‑5/p.155
Rozler, Michael M18‑19/p.243
M18‑18/p.243
Rtiere, Fabrice M10‑26/p.204
Ruan, Dan M22‑27/p.262
M17‑63/p.241
M06‑4/p.189
Ruat, Marie NR01‑7/p.223
R10‑6/p.171
NR01‑4/p.223
Rubio‑Montero, Antonio J
N14‑70/p.134
Ruchti, Randal N1‑213/p.103
Ruddy, Terrence D
M15‑60/p.230
Rudell, Jacques C
M18‑40/p.244
M18‑45/p.245
Rudin, Stephen M10‑44/p.205
M17‑41/p.240
M10‑58/p.206
Ruggeri, Alessandro N16‑5/p.156
Ruggiero, Gennaro N14‑57/p.133
Rui, Xue M18‑89/p.248
Ruiter, Nicole VJNM‑3/p.125
Rummel, Stefan N40‑3/p.184
Ruotsalainen, Ulla M22‑48/p.264
M09‑11/p.196
M09‑12/p.197
Rusanov, Ivan N14‑121/p.138
N9‑2/p.119
Rusev, Gencho N1‑18/p.88
Rusev, Gencho YN28‑9/p.165
Russ, William N1‑167/p.100
Russell, Steven W
N1‑201/p.102
Russo, Giovanni Valerio N14‑165/p.141
Russo, Guido N14‑71/p.134
N14‑72/p.134
N14‑80/p.135
N43‑9/p.187
Russotto, Paolo N14‑217/p.146
N20‑6/p.159
Rust, Thomas CM22‑62/p.265
Ruth, Thomas M22‑3/p.260
Ruthotto, Lars M15‑43/p.229
M15‑35/p.228
Ruz Armendariz, Jaime N39‑5/p.184
Ryan, James MN1‑26/p.89
N36‑3/p.181
N14‑48/p.132
Ryan, William AM18‑10/p.242
Rybka, Alexandr R13‑2/p.194
Ryder, William JM21‑47/p.259
M17‑55/p.241
M15‑64/p.231
M10‑52/p.206
Rykalin, Victor N14‑189/p.144
Ryner, Lawrence M16‑23/p.233
Ryu, Hyun‑Ju M10‑55/p.206
M16‑47/p.235
M16‑10/p.232
Ryu, Syukyo GN36‑4/p.182
Ryu, Young Hoon M22‑68/p.265
s
Sabet, Hamid JNMR‑6/p.126
N26‑2/p.163
Sabourov, Konstantin N29‑3/p.177
Sacchetti, Francesco N21‑6/p.160
Sacco, Ilaria N16‑7/p.156
Sacco, Wagner FM18‑49/p.245
Sadrozinski, Hartmut F
Author Index 305
R04‑24/p.107
N14‑189/p.144
N14‑198/p.144
N18‑7/p.157
N14‑192/p.144
N18‑1/p.157
Safavi‑Naeini, Mitra N1‑216/p.103
Saha, Krishnendu M16‑21/p.233
R15‑6/p.221
Sahbaee, Pooyan N14‑90/p.136
Sahoo, Himansu N23‑4/p.161
Saifuddin, Sarene C
M15‑65/p.231
Saito, Akinori M18‑28/p.244
Saito, Kiwamu N37‑8/p.183
Saito, Masatoshi N14‑223/p.146
Saito, Naohito N14‑214/p.146
Saito, Takehiko R
N1‑69/p.92
Saito, Tatsuhiko N12‑6/p.122
Saji, Choji N23‑6/p.161
Sakaguchi, Takuya M22‑40/p.263
M15‑34/p.228
Sakai, Koichi M18‑28/p.244
Sakai, Toshiaki M18‑41/p.244
Sakasai, Kaoru N1‑140/p.98
N1‑103/p.95
N1‑70/p.92
Sakashita, Yoshinori N14‑45/p.132
N17‑6/p.157
Sakaue, Kazuyuki N14‑1/p.129
N42‑1/p.186
Sakuma, Hajime M22‑39/p.263
Sakuma, Ichiro M12‑8/p.192
M10‑63/p.207
Sakurai, Yoshinori N1‑82/p.93
Salamon, Andrea N14‑233/p.147
N14‑36/p.131
Salas‑Gonzalez, Diego M10‑14/p.203
M22‑44/p.264
Salata, Camila M18‑81/p.247
Salcin, Esen M16‑67/p.236
Salighe Rad, Hamidreza M18‑78/p.247
Salina, Gaetano N14‑36/p.131
N14‑233/p.147
Salmon, Eric M21‑18/p.257
Salomon, André M09‑2/p.196
M02‑3/p.166
M09‑73/p.201
M10‑74/p.208
M11‑5/p.191
Salvatore, Christian M15‑4/p.226
Samei, Ehsan N14‑90/p.136
Sampietro, Marco N45‑7/p.216
Sampson, Janet N18‑5/p.157
Samulon, Eric CN10‑3/p.120
Sanchez Benitez, Angel M
N14‑217/p.146
Sanchez Lorente, Alicia N1‑69/p.92
Sanchez Majos, S. N1‑69/p.92
Sanchez, Adrian A
M17‑21/p.238
Sanchez, Federico N45‑2/p.216
Sanchez, Filomeno M09‑46/p.199
N1‑194/p.102
Sanchez‑Benitez, Angel M
N20‑6/p.159
Sanchis, Enrique N14‑5/p.129
Sanderson, Tyler N1‑89/p.94
Sandiego, Christine M
M15‑36/p.228
Sandow, Christian N1‑230/p.104
N1‑228/p.104
Sanfilippo, Delfo M03‑3/p.167
N14‑166/p.141
N1‑187/p.101
N1‑111/p.95
Sangiorgio, Samuele N14‑136/p.139
N39‑6/p.184
Sanner, Robert N41‑3/p.185
Santavenere, Fabio M10‑60/p.207
Santelj, Luka N14‑45/p.132
N17‑6/p.157
Santeramo, Bruno N43‑9/p.187
N14‑80/p.135
N14‑71/p.134
N14‑72/p.134
Santorelli, Roberto N45‑2/p.216
Santoro, Simone N20‑6/p.159
N14‑217/p.146
Santos Ribeiro, Andre M15‑33/p.228
Santos, Andres M22‑24/p.262
Santos, Carlos AN14‑135/p.139
N13‑7/p.123
Santos, Robinson A
R04‑25/p.107
Santos‑Villalobos, Hector N14‑68/p.134
Santovetti, Emanuele N14‑233/p.147
Saracco, Paolo N7‑8/p.118
N7‑4/p.118
N7‑3/p.118
N14‑65/p.134
Saracino, Giulio N14‑144/p.140
Sargeni, Fausto N14‑233/p.147
Sarkar, Jit N40‑8/p.185
Sarraj, Maher N16‑3/p.156
Sarrut, David M08‑1/p.190
HT‑4‑5/p.77
Sarti, Alessio N14‑176/p.142
Sarwar, Azeem M20‑7/p.220
Sasaki, Osamu N14‑214/p.146
Sasaki, Shinichi N37‑8/p.183
Sasaki, Takashi HT‑4‑4/p.77
N28‑3/p.164
N43‑4/p.187
Sasaki, Toshiaki M15‑1/p.226
Sato, Hiroki M18‑20/p.243
M18‑26/p.243
Sato, Hirotaka N1‑75/p.93
Sato, Kenichi M16‑25/p.233
M16‑17/p.232
N22‑2/p.160
Sato, Masanobu M09‑64/p.200
Sato, Shinji M06‑2/p.188
M22‑2/p.260
Sato, Tamotsu N28‑8/p.165
Sato, Toshiyuki R04‑30/p.108
Sato, Yasushi M15‑1/p.226
Sattel, Timo FM10‑10/p.203
M09‑66/p.201
Sauvageon, Aymeric R04‑40/p.109
Savran, Deniz M22‑18/p.262
Sawada, Ryu N22‑7/p.160
Sawada, Takayuki R04‑4/p.106
Sawall, Stefan M09‑44/p.199
M09‑47/p.199
M15‑32/p.228
Sawano, Tatsuya N13‑8/p.123
Sawhney, Kawal J
N1‑226/p.104
Sawiak, Steve M22‑46/p.264
Scafe’, Raffaele M16‑39/p.234
Scarcella, Carmelo N16‑5/p.156
Scaringella, Monica N14‑187/p.143
HT‑2‑7/p.76
M06‑6/p.189
M17‑15/p.238
N14‑177/p.143
Schaart, Dennis R
JNMR‑7/p.126
M06‑3/p.189
M22‑8/p.261
N1‑154/p.99
Schaefer, Dirk M09‑29/p.198
Schaefers, Klaus P
M21‑21/p.257
M15‑43/p.229
M17‑60/p.241
M15‑35/p.228
M15‑52/p.230
M15‑59/p.230
Schaeffter, Tobias M10‑74/p.208
Schanne, Stephane R04‑40/p.109
Scheel, Logan M16‑74/p.237
Scheirich, Jan N40‑3/p.184
Schelin, Hugo N14‑78/p.135
Schelten, Jakob N1‑68/p.92
Schenk, Werner N1‑229/p.104
Schepers, Georg N14‑156/p.141
Scherrer, Chad N8‑1/p.119
Scherwinski, Falko N8‑4/p.119
N41‑2/p.185
Scherzinger, Julius He‑1‑1/p.224
Schier, Sheena N35‑3/p.181
Schill, Christian N14‑224/p.146
Schillaci, Francesco HT‑2‑3/p.75
N42‑6/p.186
Schindler, Simon N44‑5/p.215
Schirra, Carsten M17‑20/p.238
Schlee, Stephan N1‑230/p.104
Schlesselmann, John M16‑53/p.235
Schlimme, Bjrn Sren N1‑69/p.92
Schlosser, Dieter M
N1‑156/p.99
Schlyer, David JN43‑5/p.187
M10‑64/p.207
M18‑24/p.243
Schmall, Jeffrey P
M21‑32/p.258
M09‑79/p.201
M21‑45/p.259
Schmand, Matthias N30‑2/p.178
Schmickler, Hermann LC4‑5/p.127
Schmid, Elmar N2‑8/p.82
Schmid, Soenke M21‑21/p.257
Schmidt, Aaron J
N5‑3/p.117
Schmidt, Christoph N1‑134/p.97
Schmidt, Holger M15‑26/p.228
Schmidt, Taly GM09‑32/p.198
Schmidtlein, C R
M16‑5/p.231
Schmitt, Bernd N2‑8/p.82
N4‑7/p.83
Schmitt, Christelle N39‑2/p.183
Schmitt, Katharina M17‑54/p.241
M17‑56/p.241
Schmitt, Stephen M
M17‑1/p.237
Schne, Sebastian JNM‑6/p.126
M16‑12/p.232
HT‑2‑2/p.75
Schneebeli, Matthias N6‑2/p.117
Schneider, Andreas A
R04‑42/p.109
R13‑6/p.194
NR01‑1/p.223
R04‑38/p.108
Schneider, Florian R
M21‑19/p.257
N37‑2/p.182
M17‑30/p.239
Schnell, Robert N14‑219/p.146
Schnyder, Roger N6‑2/p.117
Schoelkopf, Bernhard M15‑26/p.228
Schoendube, Harald M17‑56/p.241
M17‑54/p.241
Schoening, Andre N14‑222/p.146
Schooneveld, Erik M
N21‑1/p.159
N1‑63/p.92
N21‑6/p.160
N21‑2/p.159
N21‑5/p.160
N1‑61/p.91
Schopferer, Sebastian N14‑224/p.146
Schotanus, Paul N1‑163/p.99
N1‑13/p.88
Schoth, Matthias N1‑69/p.92
Schreiber, Akos N2‑8/p.82
Schreiber, Juergen N1‑188/p.101
Schreyer, Andreas N1‑109/p.95
Schug, David M18‑3/p.242
M12‑1/p.191
Schulte, Daniel LC2‑2/p.86
Schulte, Reinhard W
N14‑174/p.142
HT‑3‑2/p.76
N14‑192/p.144
HT‑4‑1/p.76
HT‑3‑8/p.76
HT‑1‑1/p.75
R04‑24/p.107
N14‑78/p.135
N14‑189/p.144
JNMR‑1/p.126
Schultz, Kurt M10‑41/p.205
Schultz‑Coulon, Hans‑Christian N16‑6/p.156
N14‑37/p.131
Schulz, Christian He‑1‑5/p.224
Schulz, Florian N1‑69/p.92
Schulz, Volkmar M18‑2/p.242
M18‑3/p.242
M12‑1/p.191
M11‑5/p.191
M09‑2/p.196
M10‑66/p.207
M21‑5/p.256
M10‑74/p.208
M09‑73/p.201
M02‑3/p.166
M09‑65/p.200
M09‑3/p.196
Schulze, Julia R10‑1/p.171
Schumer, Joseph W
N11‑2/p.121
He‑2‑7/p.225
N1‑42/p.90
N42‑5/p.186
N11‑3/p.121
Schumm, Bruce N35‑3/p.181
Schuster, Patricia N1‑59/p.91
Schwarz, Carsten N14‑156/p.141
Schwegler, Philipp N13‑3/p.122
N14‑157/p.141
Schweika, Werner N1‑68/p.92
Schweitzer, Jeffrey N36‑7/p.182
N1‑86/p.93
Schwemmer, Chris M19‑8/p.220
Schwenker, Benjamin N40‑3/p.184
N29‑7/p.177
Schwenzer, Nina F
M15‑26/p.228
Schwiening, Jochen N14‑156/p.141
N17‑5/p.157
Schwoebel, Paul R
N15‑3/p.155
Sciubba, adalberto N14‑176/p.142
Scott, Clayton N1‑89/p.94
Scott, Paul DR02‑5/p.84
R13‑5/p.194
Scott, Paul RHe‑2‑7/p.225
N1‑42/p.90
Scotto‑Lavina, Luca M10‑34/p.205
N14‑31/p.131
Scraggs, David N8‑3/p.119
Scuderi, Valentina N40‑4/p.184
Scuffham, James W
NR01‑1/p.223
M15‑65/p.231
M16‑13/p.232
Se, Stephen M21‑47/p.259
Seabury, Edward H
N11‑1/p.121
Seaver, Chad N14‑234/p.147
Seco, Joao M22‑11/p.261
HT‑4‑2/p.77
Seddon, Dave AN18‑5/p.157
N8‑3/p.119
Seeley, Zachary N26‑4/p.163
Segal, Julie DN1‑235/p.105
N9‑3/p.120
N14‑46/p.132
Segovia, Fermin M22‑44/p.264
Seguin‑Moreau, Nathalie N4‑1/p.83
N14‑8/p.129
Seidel, Jurgen M17‑7/p.237
Seifert, Allen N14‑123/p.138
Seifert, Carolyn E
N1‑43/p.90
N15‑8/p.155
N3‑6/p.82
Seifert, Stefan JNMR‑7/p.126
Seino, Tomoyuki R08‑2/p.169
Seipel, Heather A
N1‑45/p.90
N11‑4/p.121
Seitz, Bjoern N20‑3/p.158
Seki, Mafuyu N1‑142/p.98
N1‑160/p.99
Sekiguchi, Yuko N35‑2/p.181
N14‑130/p.139
N1‑193/p.102
Sekikawa, Yuya M22‑40/p.263
Selin, Sergey N1‑55/p.91
Seljak, Andrej N14‑45/p.132
N17‑6/p.157
Seller, Paul M15‑65/p.231
M16‑13/p.232
N1‑225/p.104
NR01‑1/p.223
R04‑38/p.108
R04‑42/p.109
R13‑6/p.194
N2‑5/p.82
Sellin, Paul JR08‑1/p.169
M16‑13/p.232
R13‑6/p.194
M15‑65/p.231
NR01‑1/p.223
R04‑42/p.109
Semeniuk, Oleksii R07‑4/p.169
Semkow, Thomas M
N14‑92/p.136
N14‑207/p.145
Semmelroth, Kurt N1‑188/p.101
Senthilkumaran, Abhirami N1‑184/p.101
N14‑159/p.141
Seo, Changwoo M10‑53/p.206
N1‑224/p.104
Seo, Hee N7‑3/p.118
N1‑199/p.102
N14‑65/p.134
Seo, Youngho M18‑27/p.244
M18‑17/p.243
M09‑68/p.201
M16‑51/p.235
Seo, Youngso JNMR‑5/p.126
Seong, Ilsoo SN5‑2/p.117
N31‑2/p.178
N31‑1/p.178
Seret, Alain M21‑15/p.257
M21‑18/p.257
Sergey, Los M16‑72/p.237
Serra, Nicola N1‑206/p.102
Servoli, Leonello N14‑200/p.145
Seta, Hiromi N14‑52/p.132
Seto, Satoru R04‑4/p.106
Seto, Yasuyuki M10‑63/p.207
Seung‑Chan, Oh N1‑180/p.101
Severino, Clizia Tecla N21‑4/p.159
Seweryniak, Dariusz N20‑2/p.158
Sfienti, Concettina N1‑69/p.92
Shabalina, Elizaveta N18‑3/p.157
Shah, Kanai SN41‑1/p.185
N1‑10/p.88
N1‑168/p.100
N26‑3/p.163
R03‑2/p.85
R04‑13/p.107
R04‑19/p.107
M09‑79/p.201
R12‑2/p.193
R12‑5/p.194
R11‑3/p.193
M02‑2/p.166
R03‑4/p.85
N41‑4/p.185
M21‑45/p.259
He‑2‑4/p.225
N1‑169/p.100
N1‑38/p.90
N1‑46/p.90
Shanbhag, Dattesh D
M15‑49/p.229
Shao, Lingxiong M15‑8/p.226
M03‑4/p.167
M20‑2/p.220
M10‑4/p.202
Shao, Qinghui N1‑108/p.95
Shao, Yiping M11‑1/p.191
M21‑7/p.256
N16‑8/p.156
M08‑8/p.190
N1‑190/p.101
N14‑238/p.147
JNM‑4/p.125
Shapiro, Benjamin M20‑7/p.220
Shapoval, Illya N14‑75/p.135
Sharma, Shivcharan L
N40‑8/p.185
Shazeeb, Mohammed S
M15‑53/p.230
Shelkov, Georgy R15‑4/p.221
Shen, Huaya N21‑3/p.159
Shen, Wei N14‑37/p.131
N16‑6/p.156
Shen, Zeng‑Ming M18‑44/p.245
R04‑67/p.111
Shenai, Alpana N14‑205/p.145
Shenton‑Taylor, Caroline N1‑189/p.101
N1‑6/p.87
N8‑3/p.119
Shi, Daxin M17‑22/p.238
M17‑23/p.239
Shi, Feng N1‑72/p.92
Shi, Kuangyu M09‑48/p.199
M10‑75/p.208
M21‑20/p.257
Shi, Pengcheng M22‑65/p.265
Shi, Xintian N2‑8/p.82
N4‑7/p.83
Shikama, Tatsuo N1‑160/p.99
Shima, Kazunari M16‑52/p.235
Shimaoka, Takehiro N39‑7/p.184
Shimazaki, Hironobu M16‑52/p.235
Shimazoe, Kenji N14‑175/p.142
Author Index 307
M12‑8/p.192
M10‑16/p.203
M10‑17/p.203
M10‑63/p.207
N14‑23/p.130
Shimizu, Hirotaka N42‑1/p.186
Shimizu, Keiji M18‑28/p.244
Shimoda, Yuya N14‑52/p.132
Shin, Dongho M22‑12/p.261
M22‑19/p.262
Shin, Han Baek M18‑15/p.243
Shin, Jae‑ik M22‑19/p.262
Shin, Jung wook R04‑68/p.111
Shin, Min‑Seok N1‑224/p.104
Shin, Yunchang N1‑157/p.99
Shinaji, Tetsuya M16‑29/p.233
M10‑21/p.204
Shinohara, Takenao N13‑8/p.123
Shippen, Alan BN1‑129/p.97
N1‑207/p.102
Shiraishi, Takahiro M10‑54/p.206
Shiran, Nataliia V
N1‑162/p.99
N1‑161/p.99
Shirmohammad, Maryam M05‑4/p.188
Shirwadkar, Urmila N1‑10/p.88
N1‑169/p.100
N1‑168/p.100
He‑2‑4/p.225
N41‑1/p.185
N41‑4/p.185
Shishido, Toetsu N1‑142/p.98
Shizu, Minami N9‑2/p.119
Shizuma, Toshiyuki N1‑18/p.88
Shoda, Chihiro N1‑83/p.93
Shoji, Masayoshi N1‑83/p.93
Shoji, Tadayoshi R03‑1/p.85
R11‑5/p.193
R04‑28/p.108
Shokouhi, Sepideh M10‑11/p.203
Shore, Adam M08‑4/p.190
Shorohov, Mihail R04‑32/p.108
R03‑5/p.85
Shortt, Brian N14‑53/p.132
Shrestha, Uttam M18‑17/p.243
M09‑68/p.201
Shultis, J KR12‑7/p.194
He‑2‑7/p.225
N1‑94/p.94
Si, Chin HM16‑38/p.234
Sibczyński, Paweł
N1‑139/p.97
N1‑131/p.97
Sibomana, Merence M15‑28/p.228
Siciliano, Edward R
He‑1‑7/p.224
N3‑4/p.82
Siddiqi, Kaleem M22‑61/p.265
Siddons, David Peter N1‑237/p.105
N14‑43/p.132
Sidky, Emil YM17‑23/p.239
M17‑21/p.238
M09‑32/p.198
M20‑2/p.220
M17‑36/p.239
M17‑22/p.238
M17‑34/p.239
Sidlauskas, Gvidas N16‑6/p.156
Siegel, Stefan BM18‑4/p.242
M18‑1/p.242
M21‑22/p.257
N30‑5/p.178
Siegmund, Oswald H
N5‑7/p.117
Sik, O. R04‑65/p.110
Sikula, J. R04‑65/p.110
Silari, Marco N21‑4/p.159
Siles, Pascale M10‑62/p.207
Silva, Ana LM18‑85/p.248
N14‑133/p.139
Silva, Claudia MM18‑81/p.247
Silva, Fabricio N14‑78/p.135
Silva, Jose CM10‑62/p.207
N16‑4/p.156
Silva, Rui M10‑62/p.207
N16‑4/p.156
Silver, Yiftah N31‑7/p.179
Silverstein, Samuel B
N14‑118/p.138
Simões, Hugo M22‑7/p.260
N14‑168/p.142
M18‑64/p.246
M22‑6/p.260
Simmonds, Phillip E
N14‑195/p.144
Simoes, Hugo M22‑13/p.261
Simoes, Marcus V
M21‑24/p.258
Simon, Frank N35‑7/p.181
Simpson, John N8‑3/p.119
Simula, Francesco N14‑36/p.131
Sinev, Nikolai BN14‑201/p.145
Singh, Bipin JNMR‑6/p.126
M13‑3/p.218
N1‑234/p.104
Singh, Santosh M09‑14/p.197
Singla, Minni N25‑6/p.162
Sipala, Valeria N14‑165/p.141
M17‑15/p.238
M06‑6/p.189
N14‑177/p.143
N40‑4/p.184
Sipila, Heikki N36‑6/p.182
Sirca, Simon N1‑69/p.92
M22‑18/p.262
Sisniega, Alejandro M21‑51/p.260
M17‑17/p.238
M18‑77/p.247
Sitar, Branislav N14‑121/p.138
Sitek, Arkadiusz M22‑60/p.265
M19‑6/p.219
M15‑27/p.228
M09‑86/p.202
M09‑22/p.197
Sizov, Fedir R04‑27/p.108
R16‑2/p.221
Sklyarchuk, Olena R04‑43/p.109
Sklyarchuk, Valery R04‑46/p.109
R04‑43/p.109
Skott, Peter N9‑2/p.119
Skretting, Arne M16‑31/p.233
Slater, James MN28‑4/p.164
JNM‑8/p.126
Slaughter, Dennis N41‑3/p.185
Slee, Mike JN8‑3/p.119
Sliwinski, Wojtek N46‑2/p.216
Smeets, Julien M22‑20/p.262
Smith, David RM16‑55/p.235
Smith, Graham N14‑55/p.133
Smith, J. N1‑30/p.89
Smith, Mark FN14‑190/p.144
N14‑188/p.144
Smith, Martin BN1‑166/p.100
Smith, Rhodri LM15‑23/p.227
Smith, Shane M21‑28/p.258
N14‑185/p.143
Snoeys, Walter N29‑1/p.177
Snyder, Scott R15‑6/p.221
R04‑22/p.107
R05‑3/p.124
So, J. H. N41‑8/p.185
N1‑147/p.98
Soares, Paula M22‑7/p.260
Sobering, Timothy J
He‑2‑7/p.225
N1‑42/p.90
R12‑7/p.194
Sobiella, Manfred M16‑12/p.232
Sobolewski, Zbigniew He‑1‑6/p.224
Sobotka, Lee M23‑8/p.255
308 Author Index Socher, Michaela M09‑47/p.199
Soffientini, Chiara M17‑6/p.237
Soh, Myung‑Jin N14‑17/p.130
Soh, Seul‑Yi N14‑17/p.130
Sokol, Paul EN14‑6/p.129
Solaz, Carles M05‑5/p.188
M17‑5/p.237
N14‑110/p.137
M16‑65/p.236
N14‑107/p.137
M16‑45/p.234
Soldat, Jan N1‑230/p.104
N4‑8/p.83
Solevi, Paola M06‑5/p.189
Solf, Torsten M11‑5/p.191
M10‑4/p.202
M10‑3/p.202
M09‑73/p.201
Solovyev, Vladimir N1‑12/p.88
Soltau, Heike N1‑156/p.99
Soltveit, Hans Kristian N14‑222/p.146
Somayaji, Ravi N2‑3/p.81
Son, Seunghee N36‑7/p.182
Son, Young Don M18‑37/p.244
M18‑36/p.244
Sondericker, John N31‑6/p.178
N39‑4/p.184
Song, Bowen M22‑53/p.264
M22‑42/p.264
Song, In Chan M10‑69/p.208
Song, Jongkeun M18‑84/p.248
Song, Na M15‑21/p.227
Song, Tae Yong M16‑24/p.233
Song, YongKeun R04‑69/p.111
Sörensen, Jens M16‑5/p.231
Sorensen, Peter N14‑136/p.139
N39‑6/p.184
Soret, Jesus M16‑22/p.233
Soriano, Antonio M09‑46/p.199
N1‑194/p.102
Soriano, Arsenia R16‑1/p.221
Sosebee, Mark N38‑2/p.183
N38‑1/p.183
Sossi, VesnaM16‑37/p.234
M01‑1/p.166
M10‑42/p.205
M07‑5/p.189
M22‑3/p.260
M05‑4/p.188
M10‑26/p.204
M21‑25/p.258
M07‑7/p.190
Sossong, Michael J
N3‑5/p.82
Soufflet, Fabrice R10‑2/p.171
Soukup, Pavel R04‑59/p.110
Soultanidis, Georgios M
M10‑74/p.208
M14‑6/p.219
Soung Yee, Lawrence N14‑140/p.139
N14‑141/p.140
Soyama, Kazuhiko N1‑70/p.92
N1‑103/p.95
Sozzi, Marco N43‑6/p.187
Spadea, Maria FHT‑4‑2/p.77
Spanggaard, Jens N14‑134/p.139
Sparger, John N8‑5/p.119
Spartiotis, Konstantinos R05‑4/p.124
Specht, Matthieu N44‑4/p.215
Speller, Robert D
M22‑24/p.262
M16‑64/p.236
M15‑37/p.229
Sperl, Jonathan IM18‑93/p.248
M18‑67/p.246
Spiers, Jonathan N2‑3/p.81
Spill, Edward JN1‑61/p.91
N21‑2/p.159
N21‑1/p.159
Spinks, Terence JM22‑57/p.265
Spisak, Tamas M10‑77/p.208
Spiteri, Pierre M07‑3/p.189
Sportelli, Giancarlo M22‑24/p.262
Spyrou, Nicholas M
N14‑115/p.138
Squillante, Micheal R
N1‑38/p.90
R12‑2/p.193
Stühler, Elisabeth M16‑32/p.233
St. James, Sara M22‑11/p.261
Staib, Michael JN1‑32/p.89
Stamen, Rainer N14‑226/p.147
Stancampiano, Concetta M17‑15/p.238
N14‑177/p.143
N40‑4/p.184
M06‑6/p.189
Stanchina, Sylvain JMR‑5/p.125
Stanek, Robert N1‑184/p.101
Stankova, Vera N14‑185/p.143
M17‑5/p.237
M16‑65/p.236
M16‑45/p.234
M05‑5/p.188
M21‑28/p.258
N14‑110/p.137
N14‑107/p.137
Stapels, Christopher J
N1‑96/p.94
N1‑46/p.90
N22‑6/p.160
N1‑122/p.96
Stapnes, Steinar M16‑31/p.233
LC1‑3/p.86
Starr, Richard N1‑86/p.93
Stave, Sean CN1‑104/p.95
Stechele, Walter N14‑117/p.138
Steele, John N11‑5/p.121
N1‑59/p.91
Steer, Christopher A
N1‑19/p.88
N8‑2/p.119
N1‑8/p.87
N14‑139/p.139
Stefanescu, Alexander N28‑7/p.165
Stefanescu, Irina N21‑8/p.160
Stefanik, Todd N26‑4/p.163
Stein, Juergen N41‑2/p.185
N8‑4/p.119
Steinberg, David R04‑24/p.107
M09‑78/p.201
N14‑186/p.143
N14‑192/p.144
Steinbrueck, Georg N33‑5/p.180
Stepanov, Pavel Y
M18‑70/p.247
M20‑7/p.220
Stepanyan, Armen M18‑9/p.242
Stephen, John BR04‑57/p.110
R09‑1/p.170
R14‑2/p.195
Stephen, Thomas N2‑5/p.82
Sterpone, Luca N23‑1/p.161
Steudtner, Tom N20‑7/p.159
Steven, Sheets N1‑173/p.100
Stewart, Andrew G
N14‑164/p.141
Stewart, Graeme D
N25‑2/p.162
Stezowski, Olivier N39‑2/p.183
Sthlmeyer, Martin N34‑3/p.180
Stichelbaut, Friedrich M22‑20/p.262
Stierstorfer, Karl M17‑54/p.241
M17‑56/p.241
Stiliaris, Efstathios M09‑77/p.201
N14‑113/p.137
M17‑12/p.238
M18‑73/p.247
M16‑41/p.234
Stiller, Wolfram M10‑25/p.204
Stinnett, Richard R04‑22/p.107
R15‑6/p.221
Stocki, Trevor JN1‑30/p.89
N1‑4/p.87
Stoehlker, Ulrich R09‑2/p.170
R04‑39/p.108
Stoermer, Michael N1‑109/p.95
Stolin, Alexander V
M10‑76/p.208
M16‑68/p.236
Stoll, Sean PM10‑64/p.207
M13‑7/p.218
M18‑24/p.243
N43‑5/p.187
Stoller, Christian N20‑1/p.158
Stonehill, Laura C
N1‑166/p.100
N1‑164/p.99
Stoppa, David N14‑167/p.142
N14‑172/p.142
Stortz, Greg M21‑25/p.258
M16‑37/p.234
M10‑42/p.205
M10‑26/p.204
M16‑23/p.233
Stoyanova, Elena N1‑21/p.88
Stratmann, Philipp M15‑65/p.231
Straub, Katrin M22‑24/p.262
Strauss, Olivier M17‑14/p.238
Strder, Lothar N28‑7/p.165
Strellis, Dan N1‑40/p.90
Streun, Matthias M16‑50/p.235
Stricker‑Shaver, Daniel A
M11‑4/p.191
Strickman, Mark S
He‑2‑7/p.225
Strmen, Peter N14‑121/p.138
Stroili, Roberto N14‑71/p.134
N14‑72/p.134
N43‑9/p.187
N14‑80/p.135
Strologas, John M18‑23/p.243
Strom, David N14‑201/p.145
N35‑3/p.181
Stroynowski, Ryszard N31‑6/p.178
Strueder, Lothar N1‑156/p.99
N1‑230/p.104
N40‑6/p.185
Stsepankou, Dzmitry M09‑6/p.196
Stuchberry, A. EN1‑127/p.97
Studen, Andrej N14‑185/p.143
M21‑28/p.258
Student, Andrej N14‑110/p.137
Stuhl, Laszlo N1‑151/p.98
Sturm, Benjamin N26‑4/p.163
N41‑3/p.185
Stute, Simon M07‑3/p.189
M15‑28/p.228
Styles, Nicholas A
N46‑7/p.217
Suchocki, Andrzej R11‑1/p.193
R04‑45/p.109
Suga, Mikio M10‑61/p.207
M16‑59/p.236
M06‑2/p.188
M10‑54/p.206
M10‑21/p.204
M17‑42/p.240
Sugimoto, Takashi N23‑5/p.161
N23‑6/p.161
Sugimoto, Yasuhiro N4‑2/p.83
Sugiyama, Makoto N1‑145/p.98
Sukhanov, Andrey Y
N14‑19/p.130
Sukowski, Frank M16‑66/p.236
Sumiyoshi, Takayuki N14‑45/p.132
N17‑6/p.157
N1‑217/p.103
Summers, Christopher J
N26‑2/p.163
N1‑91/p.94
N26‑1/p.163
Sun, Hongyan M16‑1/p.231
Sun, Liang N1‑98/p.94
N1‑41/p.90
N1‑34/p.89
He‑1‑6/p.224
Sun, Lijun N1‑72/p.92
Sun, Tao M14‑2/p.219
Sun, Wenlu N22‑6/p.160
Sun, Xishan JNM‑4/p.125
N16‑8/p.156
N14‑238/p.147
N1‑190/p.101
M11‑1/p.191
M21‑7/p.256
M08‑8/p.190
Sun, Zhijia He‑1‑2/p.224
Sunassee, Kavitha M10‑74/p.208
Sunderland, John J
M21‑44/p.259
Sundstrom, Torbjorn M15‑24/p.227
Sung, Younghun M15‑20/p.227
M15‑22/p.227
M22‑43/p.264
M22‑71/p.266
M18‑62/p.246
Supic, Lazar N1‑52/p.91
N14‑86/p.135
Surti, Suleman M08‑4/p.190
M13‑4/p.218
Suzui, Nobuo N27‑8/p.164
Suzuki, Akira N1‑160/p.99
N1‑142/p.98
Suzuki, Jun‑ichi N13‑8/p.123
Suzuki, Kazuhiko R04‑4/p.106
Suzuki, Minoru N1‑82/p.93
Suzuki, Shotaro N1‑153/p.99
Suzuki, Yuto R10‑4/p.171
Swanekamp, Stephen B
N42‑5/p.186
N11‑3/p.121
N1‑42/p.90
Sweany, Melinda N1‑90/p.94
N27‑4/p.164
Sweeney, Anthony N8‑3/p.119
Swider, Stacy N10‑5/p.120
N1‑136/p.97
R13‑1/p.194
Swiderski, Lukasz N1‑67/p.92
N1‑131/p.97
Swinhoe, Martyn T
N3‑4/p.82
Sword, Eric DN11‑7/p.121
Syed, Umme‑Farzana N14‑92/p.136
Sykora, Garrett JN21‑5/p.160
Szabo, Zsolt M21‑27/p.258
N14‑182/p.143
Szadkowski, Andrzej R11‑1/p.193
R04‑45/p.109
R04‑50/p.109
Szafraniec, Magdalena B
M22‑24/p.262
Szameitat, Tobias N14‑224/p.146
Szanda, Istvan M21‑29/p.258
Szawłowski, Marek N1‑148/p.98
N34‑5/p.180
N1‑131/p.97
N22‑3/p.160
Szczęśniak, Tomasz N1‑148/p.98
Author Index 309
N34‑5/p.180
N1‑131/p.97
N22‑3/p.160
N30‑2/p.178
Szczygiel, Robert N9‑5/p.120
N14‑38/p.131
Szirmay‑Kalos, Laszlo M09‑72/p.201
M04‑3/p.167
M09‑5/p.196
Sztuk‑Dambietz, Jolanta N1‑232/p.104
Szucs, Bernadett M10‑77/p.208
Szupryczynski, Piotr N30‑2/p.178
t
Tabacchini, Valerio JNMR‑7/p.126
Tabary, Joachim R09‑5/p.170
M10‑5/p.202
Tabata, Makoto N14‑45/p.132
N14‑162/p.141
N1‑217/p.103
M16‑48/p.235
N17‑6/p.157
Taccetti, Francesco N14‑217/p.146
Tada, Tsutomu R03‑1/p.85
R11‑5/p.193
Tagare, Hemant M07‑4/p.189
Taghavi, Saeed N2‑3/p.81
Tagnani, Diego N14‑144/p.140
Taguchi, Katsuyuki M18‑90/p.248
Tahari, Abdel KM22‑64/p.265
M15‑66/p.231
Tahavori, Fatemeh M22‑28/p.262
Taherian, Saeid R15‑7/p.221
R01‑1/p.84
Tai, Yang N1‑85/p.93
Tai, Yuan‑Chuan M18‑1/p.242
M21‑22/p.257
M16‑44/p.234
M23‑8/p.255
M20‑8/p.220
Taira, Yoshitaka N14‑7/p.129
Tajima, Hiroyasu N28‑8/p.165
R05‑1/p.124
N12‑6/p.122
Takacs, Endre M10‑77/p.208
Takada, Akinari N14‑199/p.145
Takada, Atsushi N13‑8/p.123
Takada, Eiji N14‑199/p.145
Takagaki, Hideyuki N14‑45/p.132
N17‑6/p.157
Takahashi, Hiroyuki M10‑17/p.203
M10‑63/p.207
M12‑8/p.192
N14‑175/p.142
N31‑3/p.178
N14‑23/p.130
M10‑16/p.203
Takahashi, Isao R08‑2/p.169
Takahashi, Kazutoshi N37‑8/p.183
Takahashi, Tadayuki N28‑8/p.165
Takahashi, Tadyuki R05‑1/p.124
Takahashi, Yoshihiko N1‑78/p.93
Takahashi, Yoshiyuki N1‑51/p.91
Takakura, Kousuke N1‑140/p.98
Takeda, Ayaki N42‑1/p.186
N44‑1/p.215
N36‑4/p.182
Takeda, Mauro N
N1‑121/p.96
Takeda, Sawako N14‑52/p.132
Takeda, Shinichiro R05‑1/p.124
Takeda, Toru M15‑1/p.226
Takei, Yoh N14‑52/p.132
Takeshita, Tohru N1‑192/p.101
Taketani, Atushi N14‑30/p.131
Takubo, Yousuke N4‑2/p.83
Takuma, Akira N14‑30/p.131
Takyu, Soudai M13‑6/p.218
Talamonti, Cinzia N14‑187/p.143
M06‑6/p.189
M17‑15/p.238
N14‑177/p.143
Talat, Didar M10‑46/p.206
Tallaksen, Katharin M10‑76/p.208
Tamagawa, Toru N14‑130/p.139
Tambave, Ganesh J
N19‑6/p.158
Tamborini, Davide N16‑1/p.156
Tamma, Carlo M10‑60/p.207
Tanaka, Hiroki N1‑82/p.93
Tanaka, Manobu N14‑30/p.131
N4‑4/p.83
Tanaka, Ryotaro N23‑5/p.161
N23‑6/p.161
Tanaka, Satoshi N43‑4/p.187
Tanaka, Yoshito N14‑129/p.139
Tandon, Prateek N1‑37/p.90
Tang, Bin He‑1‑2/p.224
Tang, Fu‑Kun R04‑67/p.111
Tang, Jing M23‑4/p.255
Tang, Liguang N1‑69/p.92
Tang, Qiulin M18‑90/p.248
Tang, Shaojie M18‑66/p.246
Tang, Xiangyang M18‑66/p.246
Tang, Zhenan N14‑209/p.145
Tanguay, Jesse M10‑24/p.204
M10‑13/p.203
M10‑12/p.203
R04‑48/p.109
Tanigawa, Asuka M10‑54/p.206
Tanimori, Toru N13‑8/p.123
Tanimoto, Katsuyuki M10‑54/p.206
Tao, Ashley M15‑61/p.230
Tappero, Ryan R03‑4/p.85
Tarasov, Vladimir N14‑63/p.133
Tarazona Martinez, Alfonso N32‑7/p.179
Tarolli, Alessandro N14‑32/p.131
N1‑206/p.102
N1‑203/p.102
Tarr, Garry N44‑8/p.215
Tartoni, Nicola N1‑226/p.104
R15‑5/p.221
R10‑3/p.171
R07‑5/p.169
N2‑3/p.81
Taschereau, Richard M11‑2/p.191
M10‑40/p.205
Tashima, Hideaki M18‑29/p.244
N14‑191/p.144
M22‑2/p.260
M16‑71/p.236
M16‑70/p.236
M13‑5/p.218
M12‑5/p.192
M10‑61/p.207
M10‑21/p.204
M06‑2/p.188
M16‑29/p.233
M17‑42/p.240
M22‑14/p.261
M16‑16/p.232
M16‑15/p.232
M09‑76/p.201
Tashiro, Makoto S
N14‑52/p.132
Tauber, Clovis M07‑3/p.189
310 Author Index Taubman, Matthew S
N15‑4/p.155
N15‑8/p.155
Tauzin, Gerard N1‑116/p.96
N37‑1/p.182
Tavernier, Stefaan M10‑62/p.207
Taylor, David N1‑54/p.91
Taylor, Mark M18‑9/p.242
Taylor, Russell N1‑97/p.94
Taylor, Wendy N14‑91/p.136
Tcherniakovski, Denis JNM‑3/p.125
Tcherniatine, Valeri N31‑6/p.178
N39‑4/p.184
Teixeira, Rui PHT‑4‑2/p.77
Telsemeyer, Julia N37‑4/p.182
HT‑2‑6/p.76
Temming, Kim N31‑4/p.178
Tench, Christopher M17‑32/p.239
Teng, Ping‑kun N14‑171/p.142
Teng, Shiang R04‑41/p.109
Teng, Yu‑Sheng N14‑221/p.146
Tennyson, Brian N20‑5/p.159
Teofilov, Nikolai N8‑4/p.119
ter Weele, David N
N1‑154/p.99
Terada, Yukikatsu N14‑52/p.132
N28‑8/p.165
Terakawa, Atsuki M13‑6/p.218
Terasawa, Kazuhiro N37‑8/p.183
Terry, James RN1‑164/p.99
Terunuma, Nobuhiro N14‑1/p.129
Tescaro, Diego N14‑50/p.132
Teshima, Masahiro N1‑211/p.103
N22‑4/p.160
Tesi, Mauro N14‑177/p.143
Tessarotto, Fulvio N14‑135/p.139
Tessonnier, Laurent M10‑62/p.207
Testa, Etienne HT‑2‑5/p.75
M18‑58/p.246
M10‑9/p.203
M22‑10/p.261
N16‑2/p.156
JNM‑5/p.126
Tetrault, Marc‑Andre N40‑2/p.184
Thamban, Arun Thamban N26‑2/p.163
Thanasas, Dimitrios M16‑41/p.234
Thandi, Amandeep N1‑5/p.87
N8‑3/p.119
Thea, Alessandro N32‑3/p.179
N14‑163/p.141
Theidel, Gerd N2‑8/p.82
Thelin, Peter N26‑4/p.163
Theodoratos, Gerasimos R15‑2/p.221
Theofilatos, Konstantinos N45‑5/p.216
Thers, Dominique M10‑34/p.205
N14‑31/p.131
Thibaudeau, Christian M05‑7/p.188
M10‑47/p.206
Thielemans, Kris M09‑53/p.200
M22‑57/p.265
M21‑29/p.258
M08‑2/p.190
Thienpont, Damien N14‑14/p.130
Thil, Christophe N1‑231/p.104
Thirolf, Peter GHT‑2‑4/p.75
Thiruvenkadam, Sheshadri M15‑49/p.229
Thoma, Ulrike N1‑134/p.97
Thomas, Benjamin A
M23‑3/p.255
M15‑9/p.226
Thomay, Christian N1‑19/p.88
N8‑2/p.119
Thompson, Al CN1‑233/p.104
Thompson, Christopher J
M16‑37/p.234
M10‑26/p.204
M10‑42/p.205
M16‑23/p.233
M21‑25/p.258
Thompson, Jeffrey N15‑5/p.155
Thompson, Jon N2‑3/p.81
Thompson, Martin N1‑30/p.89
N1‑4/p.87
Thompson, Scott J
N11‑1/p.121
Thon, Andreas M12‑2/p.192
Thorn, Craig N31‑6/p.178
N39‑4/p.184
Thornhill, Jim N18‑5/p.157
Thorpe, Matt N2‑3/p.81
Thorpe, Thomas N
N31‑2/p.178
N5‑2/p.117
N31‑1/p.178
Thrall, Crystal LR11‑3/p.193
R04‑13/p.107
Threadgold, James N11‑2/p.121
N1‑5/p.87
Threadgold, Jim N1‑16/p.88
Thungstrom, Goran N14‑218/p.146
R10‑3/p.171
R15‑5/p.221
Tian, Lingling M18‑92/p.248
Tice, Jeff N1‑236/p.105
Tickner, James RN1‑219/p.103
Tieulent, Raphael N24‑7/p.162
Tillotson, Thomas N41‑3/p.185
Tim, Sobering N1‑97/p.94
Tintori, Carlo R04‑29/p.108
Tippmann, Marc N1‑222/p.104
N1‑211/p.103
Tisa, Simone N16‑5/p.156
N34‑3/p.180
Titov, Maxim NP1‑1/p.81
NP3‑3/p.217
Tiwari, Ashutosh R04‑41/p.109
Tocharoenchai, Chiraporn M10‑36/p.205
M10‑48/p.206
Tocut, Vanessa N14‑51/p.132
N6‑4/p.118
Toda, Naohiro M20‑5/p.220
Todeschini, Paola M22‑52/p.264
Toepfer, Thomas N1‑163/p.99
Toh, Kentaro N1‑103/p.95
N1‑140/p.98
N1‑70/p.92
Tohme, Michel M18‑42/p.245
Tokieda, Hiroshi N31‑5/p.178
Tokuda, Satoshi R04‑30/p.108
Tolbanov, Oleg R15‑4/p.221
Toledo Alarcon, Jose F
N32‑7/p.179
Toledo, Fabio N1‑121/p.96
Tomada, Astrid N1‑236/p.105
Tomandl, Ivo N1‑65/p.92
Tomanin, Alice N1‑92/p.94
N1‑110/p.95
Tomasello, Barbara HT‑2‑3/p.75
N42‑6/p.186
Tomassetti, Luca N14‑80/p.135
N43‑9/p.187
N14‑71/p.134
N14‑72/p.134
Tome, Wolfgang N14‑196/p.144
Tomita, Hideki N1‑152/p.98
N1‑83/p.93
N27‑5/p.164
Tonchev, Anton N1‑18/p.88
Torma, Pekka TN36‑6/p.182
Tornga, Shawn N36‑3/p.181
Torres, Felipe M09‑58/p.200
Torres, Jose M16‑22/p.233
Torres‑Bribiesca, Marco A
N1‑208/p.103
Torres‑Espallardo, Irene M17‑30/p.239
M17‑5/p.237
M16‑65/p.236
M06‑5/p.189
M22‑15/p.261
Torrisi, Lorenzo N42‑6/p.186
R12‑1/p.193
HT‑2‑3/p.75
Toshito, Toshiyuki HT‑4‑4/p.77
Tosi, Alberto N16‑1/p.156
N34‑3/p.180
N16‑5/p.156
Tosoratto, Laura N14‑36/p.131
Toth, Balazs M04‑3/p.167
M09‑5/p.196
M09‑72/p.201
Totsuka, Daisuke N26‑7/p.163
N1‑146/p.98
Tourrette, Thierry R04‑40/p.109
Tourvielle, Christian M21‑16/p.257
Tout, Deborah M22‑50/p.264
Tower, Josh R12‑5/p.194
N1‑10/p.88
Toyokawa, Hidenori R10‑5/p.171
Toyokawa, Hiroyuki N14‑7/p.129
Tramontana, Antonella HT‑2‑3/p.75
N42‑6/p.186
Tran, Vi Hoa M16‑57/p.235
Tranquille, Gerard N14‑134/p.139
Traversi, Gianluca N29‑2/p.177
N44‑6/p.215
N14‑27/p.130
Tremsin, Anton S
N5‑7/p.117
Trifiro’, Antonio N20‑6/p.159
N14‑217/p.146
Trimarchi, Marina N14‑217/p.146
N20‑6/p.159
Trimborn, Barbara R04‑10/p.106
Trimpl, Marcel N9‑5/p.120
Trinczek, Michael M22‑3/p.260
Trindade, Andreia M10‑4/p.202
M12‑2/p.192
M10‑3/p.202
Tripathi, Mani N35‑3/p.181
Troncon, Clara N14‑208/p.145
N1‑181/p.101
Trost, Jeff CM22‑40/p.263
M15‑34/p.228
Trovato, Marco M16‑65/p.236
N14‑107/p.137
M17‑5/p.237
Trueb, Peter N6‑2/p.117
Truhn, Daniel M18‑2/p.242
Trujillo, Manuel R09‑4/p.170
Trunk, Ulrich N4‑7/p.83
Tsai, Chung‑Yung M17‑51/p.241
Tsai, Pei‑rong N14‑171/p.142
Tsai, Ya‑wen N14‑171/p.142
Tsai, Yu‑Jung M17‑44/p.240
Tsang, Thomas N39‑4/p.184
Tseng, Hsu‑Yin M16‑33/p.234
Tshadadze, Edisher N13‑2/p.122
Tsoumpas, Charalampos M17‑12/p.238
M15‑45/p.229
M08‑2/p.190
M09‑75/p.201
M14‑6/p.219
M23‑5/p.255
M10‑74/p.208
M09‑53/p.200
Tsubota, Youichi N39‑7/p.184
Tsuda, Tomoaki M09‑64/p.200
Tsui, Benjamin M
JNMR‑5/p.126
M10‑79/p.208
M08‑5/p.190
M09‑4/p.196
M18‑12/p.243
M10‑48/p.206
Tsujimoto, Masahiro N14‑52/p.132
Tsukada, Kyo N1‑69/p.92
Tsurin, Ilya N14‑164/p.141
N25‑4/p.162
Tsuru, Takeshi GN36‑4/p.182
Tsutsumi, Kousuke N1‑176/p.100
N1‑175/p.100
N26‑5/p.163
Tumer, Tumay R04‑22/p.107
R05‑3/p.124
Tummo, Juraphan N14‑219/p.146
Tuna, Uygar M22‑48/p.264
M09‑12/p.197
Tung, Chi‑Hua M10‑4/p.202
Tung, Chuang‑jong N14‑171/p.142
Tuning, Niels N14‑122/p.138
Tuominen, Eija N14‑121/p.138
Turcato, Monica N1‑232/p.104
Turco, Anna M10‑20/p.204
M18‑5/p.242
Turkington, Timothy G
M18‑34/p.244
M18‑35/p.244
M18‑33/p.244
Turkoglu, Danyal N42‑2/p.186
Turpeinen, Raimo N14‑121/p.138
Turqueti, Marcos N1‑36/p.90
R16‑1/p.221
N15‑6/p.155
Tuve’, Cristina N40‑4/p.184
Twigger, Jessie N1‑32/p.89
Tyagi, Mohit N1‑132/p.97
Tyazhev, Anton R15‑4/p.221
u
Uchida, Tomohisa N1‑83/p.93
Uchihori, Yukio N37‑8/p.183
N28‑8/p.165
Uchiyama, Daisuke N1‑69/p.92
Uchiyama, Yusuke N22‑7/p.160
Udias, Jose MM17‑7/p.237
Ueno, Kazuki N14‑214/p.146
N13‑8/p.123
Uesaka, Mitsuru N31‑3/p.178
Uesaka, Tomohiro N31‑5/p.178
Ugorowski, Phil B
He‑2‑7/p.225
Uhlmann, Norman R04‑52/p.109
N1‑188/p.101
N14‑179/p.143
Ujhelyi, Ferenc M21‑6/p.256
M10‑6/p.202
Ullan, Miguel N14‑57/p.133
N14‑158/p.141
N14‑58/p.133
Umenhoffer, Tamas M09‑72/p.201
Author Index 311
M04‑3/p.167
Uno, Shoji N1‑83/p.93
Unz, Ronald N1‑39/p.90
Upplegger, Lorenzo N40‑4/p.184
Ur, Calin N14‑21/p.130
Urakawa, Junji N42‑1/p.186
N14‑1/p.129
Uras, Antonio N24‑7/p.162
Urdaneta, Mario M18‑70/p.247
M20‑7/p.220
Uritani, Akira N1‑79/p.93
N1‑78/p.93
M18‑63/p.246
Urso, Giorgio N32‑6/p.179
Usuki, Yoshiyuki N26‑5/p.163
M18‑26/p.243
Uxa, Stepan R10‑7/p.171
R04‑47/p.109
Uzun, Dilber M16‑46/p.235
v
Vacchi, Andrea N36‑5/p.182
N6‑5/p.118
Vacik, Jiri N1‑106/p.95
N1‑65/p.92
Vadenbroucke, Arne M21‑36/p.259
Vagovic, Patrik N10‑7/p.121
Vahsen, Sven EN31‑1/p.178
N31‑2/p.178
N5‑2/p.117
Vaissier, Pieter EM17‑10/p.238
Valastyán, Ivan M10‑19/p.204
M10‑20/p.204
N14‑119/p.138
M18‑5/p.242
M21‑27/p.258
N14‑182/p.143
Valdez, Greg DN7‑5/p.118
Valenciaga, Yanisley M11‑2/p.191
M09‑81/p.201
Valentine, John N1‑53/p.91
Valentino, Vincenzo N13‑2/p.122
Valero, Alberto N19‑2/p.158
Valiollahzadeh, Sayyed Majid M15‑55/p.230
Vallance, Michael M15‑5/p.226
Vallerand, Philippe N6‑4/p.118
Vallerga, John VN5‑7/p.117
Valletta, Antonio R09‑7/p.170
Valtorta, Silvia M15‑4/p.226
Valvo, Giusy N1‑187/p.101
N1‑111/p.95
N14‑166/p.141
Van Audenhaege, Karen M16‑4/p.231
Van Berg, Rick M18‑10/p.242
van Dam, Herman T
JNMR‑7/p.126
van der Borden, Arnout J
M06‑3/p.189
M22‑8/p.261
van der Graaf, Harry N40‑5/p.184
van der Schaaf, Arjen M06‑3/p.189
M22‑8/p.261
Van Dyk, Gregory K
N1‑24/p.89
van Eijck, Lambert N21‑5/p.160
Van Esch, Patrick N1‑76/p.93
He‑1‑3/p.224
Van Holen, Roel M09‑71/p.201
M15‑7/p.226
M16‑4/p.231
M16‑20/p.233
M18‑43/p.245
M22‑22/p.262
Van Loef, Edgar V
N41‑1/p.185
N1‑168/p.100
N26‑3/p.163
N41‑4/p.185
van ‘t Veld, Aart A
M22‑8/p.261
M06‑3/p.189
van Vliet, Lucas J. M22‑38/p.263
van Waasen, Stefan N1‑68/p.92
M16‑50/p.235
Van Wechel, Timothy D
N14‑35/p.131
Vandeghinste, Bert M16‑4/p.231
M21‑14/p.257
Vandehey, Nicholas T
M09‑36/p.198
Vandenberghe, Stefaan M22‑22/p.262
M21‑14/p.257
M16‑4/p.231
M16‑20/p.233
M15‑7/p.226
M12‑3/p.192
M09‑71/p.201
M06‑3/p.189
M06‑5/p.189
Vandenbroucke, Arne M09‑83/p.202
M21‑37/p.259
M18‑16/p.243
Vander Stappen, Francois M22‑20/p.262
VanDevender, Brent A
N15‑4/p.155
N14‑123/p.138
N1‑124/p.96
Vanhove, Christian M21‑14/p.257
M15‑7/p.226
Vaquero, Juan Jose M17‑7/p.237
M17‑17/p.238
M21‑51/p.260
M18‑77/p.247
Varela, Joao N16‑4/p.156
M10‑62/p.207
M15‑29/p.228
M15‑56/p.230
Vargas, Phillip M20‑1/p.220
Varner, Robert LN31‑7/p.179
Vaska, Paul N43‑5/p.187
M10‑64/p.207
M13‑7/p.218
M18‑24/p.243
JNMR‑5/p.126
Vassal, Marie‑Ccile R10‑2/p.171
Vassallo, Caroline N1‑19/p.88
Vasyukov, Sergei A
N1‑162/p.99
Vavrik, Daniel N1‑106/p.95
Vazquez‑Flores, Gerson J
He‑1‑6/p.224
N1‑34/p.89
N1‑41/p.90
N1‑98/p.94
Veale, Matthew C
R04‑42/p.109
M16‑13/p.232
NR01‑1/p.223
R04‑38/p.108
R13‑6/p.194
M15‑65/p.231
Vedda, Anna N26‑7/p.163
Veerappan, Chockalingam N14‑120/p.138
Veit‑Haibach, Patrick M10‑70/p.208
Vela, Oscar R08‑5/p.170
R04‑36/p.108
R02‑2/p.84
Velasco, Jose LN14‑70/p.134
Veloso, Joao FN14‑135/p.139
N13‑7/p.123
M18‑85/p.248
Veloza, Stella M10‑25/p.204
Velthuis, Jaap N8‑2/p.119
N29‑4/p.177
N1‑19/p.88
Vencelj, Matjaz M22‑18/p.262
Vengadabady, Laura M22‑57/p.265
Venialgo, Esteban N14‑64/p.133
Venkatesan, Sampath N9‑4/p.120
Verbitskaya, Elena N14‑57/p.133
Verde, Giuseppe N14‑217/p.146
N20‑6/p.159
Verger, Loick NR01‑3/p.223
JMR‑5/p.125
M10‑5/p.202
R09‑5/p.170
Verhaeghe, Jeroen M09‑23/p.197
M15‑15/p.227
M22‑55/p.264
Verheyden, Ruben N14‑45/p.132
N17‑6/p.157
Verhoeven, Caroline M09‑17/p.197
Verity, Jeffrey N8‑4/p.119
Vernon, Emerson N6‑3/p.118
N6‑8/p.118
R04‑7/p.106
R05‑2/p.124
Verona, Claudio R07‑5/p.169
M22‑17/p.262
Verona‑Rinati, Gianluca R07‑5/p.169
M22‑17/p.262
Verrastro, Claudio N14‑64/p.133
Verrecchia, Patrice N37‑1/p.182
N1‑116/p.96
Verzellesi, Giovanni N1‑117/p.96
Vetter, Kai N14‑86/p.135
N15‑7/p.155
N1‑221/p.103
N1‑48/p.90
N8‑6/p.119
N1‑220/p.103
NR01‑6/p.223
N8‑7/p.119
N29‑3/p.177
N3‑7/p.82
N1‑52/p.91
N45‑6/p.216
Vial, Philip M22‑9/p.261
Viana, Bruno N26‑6/p.163
Vianello, E N14‑154/p.140
Vicente, Esther M17‑7/p.237
Vicini, Piero N14‑36/p.131
Vidal, Luis Fernando M09‑46/p.199
N1‑194/p.102
Vigilante, Mariano N14‑217/p.146
N20‑6/p.159
Vignati, Marco N1‑114/p.96
Vigneault, Mark N1‑213/p.103
Villa, Federica N34‑3/p.180
N16‑1/p.156
Villani, Enrico Giulio N14‑184/p.143
Villard, Jean‑Francois N1‑130/p.97
Vinke, Ruud M16‑14/p.232
M03‑3/p.167
M08‑7/p.190
Violante, Massimo N23‑1/p.161
Virolainen, Tuula NR01‑5/p.223
Visscher, Theodore N1‑77/p.93
Visvikis, Dimitris M09‑50/p.199
M23‑5/p.255
M22‑49/p.264
M22‑34/p.263
M08‑1/p.190
M17‑35/p.239
M17‑14/p.238
M11‑8/p.191
Vitale, Emanuela N14‑176/p.142
Vlassis, Spyridon R15‑2/p.221
Voena, Cecilia N14‑176/p.142
N1‑114/p.96
Vogel, Jakob M09‑48/p.199
Vogel, Sam N1‑122/p.96
Vogt, Holger N34‑3/p.180
Volgyes, David M09‑45/p.199
M16‑31/p.233
Volkovskii, Alexander R04‑22/p.107
R15‑6/p.221
R05‑3/p.124
von der Lippe, Henrik N6‑7/p.118
Voss, Bernd N14‑121/p.138
N9‑2/p.119
Voss, Lars FR12‑5/p.194
N1‑108/p.95
R04‑19/p.107
R08‑3/p.169
Vu, Nam M10‑40/p.205
Vunckx, Kathleen M04‑6/p.168
M15‑9/p.226
Vurgun, Nasit M16‑73/p.237
Vyas, Jagdish CN40‑8/p.185
Vykydal, Zdenek R15‑1/p.221
w
Wachter, Astrid M15‑47/p.229
Wada, Mami M16‑48/p.235
Wada, Yasuhiro M15‑1/p.226
Wada‑Katsumi, Mami N14‑162/p.141
Wagadarikar, Ashwin A
M16‑36/p.234
Wagatsuma, Kei M15‑1/p.226
Wagner, Andreas N20‑7/p.159
Wagner, Brent KN26‑1/p.163
Wahl, Christopher G
N1‑157/p.99
N20‑5/p.159
Wahl, David N28‑2/p.164
Wahl, Richard LM07‑5/p.189
M22‑64/p.265
Wajima, Y. R07‑1/p.169
Wakahara, Shingo N1‑145/p.98
N1‑142/p.98
N1‑153/p.99
Waker, Anthony J
N1‑58/p.91
N39‑3/p.184
Walder, Jean‑Pierre N2‑2/p.81
N6‑7/p.118
Walenta, Albert Einrich N16‑2/p.156
Walenta, Albert H
M16‑63/p.236
N1‑229/p.104
Walker, Frank R04‑22/p.107
R15‑6/p.221
Walker, Matthew D
M10‑42/p.205
M05‑4/p.188
Walker, Nicholas LC2‑1/p.86
Walker, Richard J
N40‑1/p.184
Waller, David N1‑30/p.89
N1‑4/p.87
Wallny, Rainer N1‑133/p.97
Walsh, Susan M21‑44/p.259
Walsh, William JN14‑77/p.135
Wang, Bairong N20‑4/p.158
Wang, Cai‑Lin N1‑87/p.94
N1‑100/p.95
N1‑81/p.93
Wang, Changsheng R04‑5/p.106
Wang, Chung‑Hsiang N14‑221/p.146
N14‑171/p.142
Wang, Ge M09‑28/p.198
M09‑27/p.198
M09‑41/p.199
M22‑41/p.263
M09‑42/p.199
Wang, Gin‑Chung J
N14‑41/p.131
M12‑4/p.192
Wang, Guang QR04‑2/p.106
Wang, Guobao M02‑4/p.166
M04‑2/p.167
Wang, Hongkai M10‑40/p.205
Wang, Huanyu R04‑37/p.108
N14‑47/p.132
Wang, Jerry M12‑4/p.192
Wang, Jing M09‑59/p.200
M17‑13/p.238
Wang, Jingbo N1‑1/p.87
Wang, Jiong M20‑2/p.220
Wang, Liang M21‑22/p.257
Wang, Luyao M16‑2/p.231
Wang, Qian M21‑20/p.257
Wang, Qiang M18‑1/p.242
Wang, Shaohua N1‑172/p.100
N10‑6/p.120
Wang, Sharon M10‑3/p.202
Wang, Shi M10‑80/p.208
M10‑18/p.203
M10‑15/p.203
M10‑59/p.207
M17‑43/p.240
M18‑32/p.244
N14‑44/p.132
Wang, Steve M20‑1/p.220
Wang, Tao R04‑5/p.106
Wang, Tzu‑Fang R09‑4/p.170
N1‑108/p.95
Wang, Weichung M17‑50/p.241
Wang, Weiyi R04‑20/p.107
NR01‑8/p.223
Wang, Wenli M04‑4/p.167
M09‑85/p.202
M15‑41/p.229
M18‑6/p.242
M17‑9/p.237
M10‑29/p.204
M15‑38/p.229
Wang, Wenxin N21‑3/p.159
N38‑5/p.183
Wang, Wu XN1‑80/p.93
Wang, Xinzeng N14‑170/p.142
Wang, Xuewu N1‑17/p.88
N1‑1/p.87
N1‑27/p.89
N14‑33/p.131
Wang, Yanfeng He‑1‑2/p.224
Wang, Yi M22‑70/p.266
N1‑1/p.87
N1‑27/p.89
N4‑6/p.83
N20‑4/p.158
Wang, Yijie M22‑41/p.263
Wang, Ying N1‑7/p.87
N1‑3/p.87
Wang, Zen M12‑4/p.192
Wanke, Rainer N43‑6/p.187
Ward, Wil M22‑63/p.265
Wargo, Richard R
M18‑33/p.244
Warman, Lawrence N1‑54/p.91
Warnock, Geoff M21‑15/p.257
M21‑18/p.257
Warren, Glen AN15‑4/p.155
N1‑45/p.90
N5‑6/p.117
Warren, Matt N14‑108/p.137
Washio, Masakazu N14‑1/p.129
Wassatsch, Andreas N4‑3/p.83
Wassick, Greg N1‑26/p.89
Watabe, Hiroshi M16‑7/p.232
N27‑8/p.164
Watabe, Hiroshi M21‑1/p.256
Watanabe, Ken N42‑1/p.186
Watanabe, Kenichi N1‑146/p.98
M18‑63/p.246
N1‑153/p.99
N1‑78/p.93
He‑2‑8/p.225
N1‑79/p.93
Watanabe, Mitsuo M16‑15/p.232
M18‑41/p.244
M18‑28/p.244
Watanabe, Shin R05‑1/p.124
N28‑8/p.165
Watanabe, Yasuyoshi N1‑204/p.102
M16‑40/p.234
Waters, Laurie SN7‑1/p.118
Watson, Charles C
JNM‑1/p.125
Watson, Scott MN1‑45/p.90
N1‑174/p.100
N11‑1/p.121
Watts, David M06‑5/p.189
Watts, Stephen N44‑7/p.215
Wawrzyniak, Gregor JMR‑4/p.125
R01‑2/p.84
Wayant, Clayton N5‑3/p.117
Weaverdyck, Curtis N31‑7/p.179
Weber, Bruce VN1‑42/p.90
N11‑6/p.121
N11‑3/p.121
Weber, Thomas M
R09‑4/p.170
Webster, Eric AN40‑1/p.184
Webster, John RN21‑2/p.159
Weckmann, Armin N14‑240/p.136
Wehrl, Hans FM11‑7/p.191
Wei, Kong M16‑56/p.235
Wei, Qingyang M21‑33/p.258
M10‑18/p.203
M10‑44/p.205
M17‑41/p.240
M18‑32/p.244
Wei, Qinhua N1‑143/p.98
Wei, Su Hua N14‑60/p.133
Weidenspointner, Georg N14‑65/p.134
N14‑240/p.136
N28‑6/p.165
N28‑5/p.165
N7‑3/p.118
N1‑228/p.104
N1‑230/p.104
N28‑7/p.165
Weigell, Philipp N33‑3/p.179
Weih, Markus M16‑32/p.233
Weilhammer, Peter N14‑110/p.137
M21‑28/p.258
N14‑185/p.143
Weinberg, Irving N
M20‑7/p.220
M18‑70/p.247
Weirich, Christoph M09‑15/p.197
Weisenberger, Andrew G
N14‑188/p.144
N14‑190/p.144
M18‑9/p.242
Weisman, Kenneth JNMR‑5/p.126
Weissler, Bjoern M18‑3/p.242
M12‑1/p.191
M11‑5/p.191
M02‑3/p.166
M09‑65/p.200
M10‑66/p.207
Weizeorick, John N23‑7/p.161
N2‑2/p.81
Wellmann, Peter R04‑36/p.108
Wells, David N18‑5/p.157
Wells, Kevin M15‑23/p.227
Author Index 313
N37‑3/p.182
N14‑183/p.143
M22‑28/p.262
M15‑11/p.227
Wells, R Glenn M09‑74/p.201
M15‑60/p.230
Wen, Jie M23‑8/p.255
M16‑44/p.234
M21‑22/p.257
M18‑1/p.242
Wendel, Christoph N1‑134/p.97
Wensong, Zhu N14‑10/p.129
Wessel, Jan Christopher JMR‑4/p.125
M16‑51/p.235
R01‑2/p.84
Westbrook, Edward N1‑233/p.104
Westerwoud, Vicotr M08‑6/p.190
Weyers, Sascha N34‑3/p.180
Wharton, C. JN1‑33/p.89
White, Andrew P
N38‑2/p.183
N38‑1/p.183
White, Justin N1‑36/p.90
White, Timothy A
N8‑1/p.119
Whitney, Chad M
N1‑122/p.96
N22‑6/p.160
N1‑38/p.90
N1‑96/p.94
N1‑46/p.90
Wichmann, Katarzyna N43‑8/p.187
Wieczorek, Herfried M10‑4/p.202
M10‑3/p.202
Wiedner, Dirk N14‑222/p.146
Wieger, Brian MN14‑77/p.135
Wieland, Oliver N1‑151/p.98
N1‑118/p.96
N1‑119/p.96
Wieleczko, Jean‑Pierre N39‑2/p.183
Wiener, Rony IM13‑4/p.218
M18‑10/p.242
Wiesinger, Florian M15‑49/p.229
M23‑2/p.255
M10‑70/p.208
Wiest, Florian N37‑2/p.182
N45‑3/p.216
N45‑4/p.216
Wilcox, Trevor AN7‑1/p.118
Wilen, Chris N15‑4/p.155
Wilhelm, Heribert R15‑5/p.221
R10‑3/p.171
Wilk, Fabian N40‑3/p.184
Williams, Christopher S
N20‑8/p.159
Williams, Garth N2‑7/p.82
N1‑238/p.105
Williams, Heather A
M22‑50/p.264
Williams, John G
N1‑215/p.103
Williams, Rees N1‑163/p.99
Williams, Richard M
N14‑123/p.138
Williamson, Martin R
N1‑201/p.102
Willis, Brian N2‑3/p.81
Willis, William M15‑66/p.231
N31‑6/p.178
Wilpert, Thomas He‑1‑5/p.224
Wilson, David M18‑11/p.242
Wilson, Joshua M
M18‑35/p.244
M18‑34/p.244
M18‑33/p.244
Wilson, Mark N14‑40/p.131
Wilson, Matthew D
M15‑65/p.231
M16‑13/p.232
R04‑42/p.109
R04‑38/p.108
R13‑6/p.194
NR01‑1/p.223
Wilt, Philip N20‑2/p.158
Wimberley, Catriona M14‑1/p.218
Windridge, David M15‑11/p.227
Winey, Brian M22‑23/p.262
Wing, Matthew N14‑108/p.137
N2‑5/p.82
N1‑225/p.104
Winter, Marc JNM‑5/p.126
LC2‑3/p.86
N14‑220/p.146
N44‑4/p.215
N29‑8/p.177
Wirth, Brian DR04‑21/p.107
Witkowska, Barbara R04‑50/p.109
R11‑1/p.193
R04‑45/p.109
Witkowska‑Baran, Marta R11‑1/p.193
R04‑50/p.109
R04‑45/p.109
Wittman, Richard S
N8‑1/p.119
Wiyaporn, Kanyalak M10‑48/p.206
Wlodek, Kaplan N1‑179/p.100
Wolf, Andreas N8‑4/p.119
Wolf, Didier M10‑2/p.202
Wolf, Paul AM09‑32/p.198
Wollenweber, Scott D
M10‑70/p.208
M15‑49/p.229
M15‑46/p.229
M10‑73/p.208
M23‑2/p.255
Wolski, Darek N22‑3/p.160
Wolsztynski, Eric M15‑2/p.226
Wolters, Carsten H
M15‑35/p.228
Wong, Dean FM15‑66/p.231
M07‑5/p.189
Wong, Jeannie N14‑196/p.144
Wong, Wai‑Hoi M21‑30/p.258
M03‑8/p.167
Wonsak, Sven N25‑3/p.162
Woo, Sang‑Keun M15‑51/p.230
M15‑63/p.230
M21‑48/p.259
M22‑68/p.265
Wood, Lynn N15‑4/p.155
Woods, Michael N35‑3/p.181
Woody, Craig LN43‑5/p.187
M18‑24/p.243
M10‑64/p.207
N39‑1/p.183
M13‑7/p.218
Woolf, Richard SN1‑16/p.88
N1‑9/p.87
N42‑5/p.186
N11‑6/p.121
Workman, Herschel E
He‑2‑1/p.225
N1‑100/p.95
N1‑81/p.93
Wroe, Andrew JN14‑189/p.144
N28‑4/p.164
JNM‑8/p.126
Wu, Chao M15‑48/p.229
Wu, Feng N14‑47/p.132
Wu, Heyu R04‑64/p.110
M18‑1/p.242
M23‑8/p.255
Wu, Hsin TM14‑2/p.219
Wu, Jing M08‑8/p.190
M10‑80/p.208
M10‑15/p.203
JNM‑4/p.125
Wu, Jinyuan N32‑8/p.179
Wu, Shukui R10‑5/p.171
Wu, Xiaopeng NR01‑5/p.223
N1‑179/p.100
Wu, Yibao M02‑2/p.166
Wu, Ying KN1‑18/p.88
314 Author Index Wu, Yucheng N14‑106/p.137
Wu, Yun NM14‑2/p.219
Wu, Yuntao N1‑138/p.97
Wu, Zhongyi M16‑2/p.231
Wuensch, Walter LC5‑4/p.128
Wulf, Eric AN11‑6/p.121
N42‑5/p.186
Wunderlich, Adam M17‑52/p.241
Wurz, Jonathan R
N14‑48/p.132
x
Xi, Daoming M16‑2/p.231
Xi, Wenze M18‑9/p.242
Xia, Yan M10‑15/p.203
M10‑18/p.203
M09‑43/p.199
M08‑8/p.190
M10‑80/p.208
Xiao, Peng M16‑3/p.231
N14‑93/p.136
M16‑2/p.231
Xiao, Yongshun M09‑28/p.198
M09‑27/p.198
Xiaolei, Cheng N14‑97/p.136
Xiaoping, Ouyang N14‑97/p.136
Xie, Junqi N1‑223/p.104
Xie, Qingguo M16‑2/p.231
M16‑3/p.231
N14‑93/p.136
Xie, WenQing N14‑124/p.138
Xing, Lei M18‑47/p.245
Xing, Yuxiang M18‑55/p.246
M09‑35/p.198
Xinyi, Cheng M09‑7/p.196
N14‑169/p.142
Xiong, Wei N1‑150/p.98
Xu, Dan M17‑47/p.240
Xu, Dapeng R04‑64/p.110
Xu, Feng R04‑9/p.106
Xu, Hong He‑1‑2/p.224
Xu, Jingjia M22‑65/p.265
Xu, Jingyan M10‑79/p.208
M09‑4/p.196
M18‑12/p.243
Xu, Lingyan R04‑5/p.106
Xu, Qiaofeng M17‑20/p.238
Xu, Tianpeng N14‑44/p.132
M10‑18/p.203
Xu, Xiaodong N41‑6/p.185
Xu, Xunjiang N14‑4/p.129
Xu, Yadong R04‑5/p.106
Xu, Yuanlai R11‑5/p.193
R03‑1/p.85
Xue, Tao N14‑106/p.137
Xue, Yuxiong N1‑72/p.92
y
Yagi, Takahiro N1‑51/p.91
Yakimovich, Vladimir R11‑2/p.193
Yamada, Kawakatsu N14‑7/p.129
Yamada, Ryoko M18‑28/p.244
M18‑41/p.244
Yamada, Takahiro M15‑1/p.226
Yamaga, Mitsuhiro N23‑5/p.161
N2‑1/p.81
N23‑6/p.161
Yamaguchi, Akira N14‑128/p.139
Yamaguchi, Hidetoshi N31‑5/p.178
Yamaguchi, Sunao N14‑52/p.132
Yamaguchi, Takahiro N14‑131/p.139
Yamaguchi, Yoshimasa N1‑51/p.91
Yamaji, Akihiro N1‑160/p.99
N1‑145/p.98
N1‑159/p.99
N1‑142/p.98
N1‑153/p.99
Yamakawa, Tsutomu M18‑57/p.246
Yamamgishi, Hideshi N1‑70/p.92
Yamamoto, Hitoshi LC1‑5/p.86
N4‑2/p.83
Yamamoto, Koei N22‑2/p.160
Yamamoto, Seiichi M16‑17/p.232
M18‑26/p.243
M16‑7/p.232
M18‑20/p.243
N27‑8/p.164
M21‑1/p.256
M16‑25/p.233
Yamamura, Kazuhisa M16‑17/p.232
M16‑25/p.233
Yamaoka, Jared N31‑2/p.178
N5‑2/p.117
Yamaoka, Jared A
N31‑1/p.178
Yamashita, H. R07‑1/p.169
Yamashita, Tomohiro HT‑4‑4/p.77
Yamashita, Yoshiki M16‑52/p.235
Yamauchi, Hidemoto M18‑28/p.244
M18‑41/p.244
Yamaya, Taiga M18‑31/p.244
M13‑5/p.218
M16‑15/p.232
M16‑16/p.232
M16‑29/p.233
M16‑59/p.236
M16‑70/p.236
M12‑5/p.192
M17‑42/p.240
M18‑29/p.244
M22‑14/p.261
M22‑2/p.260
N14‑173/p.142
N14‑191/p.144
M16‑71/p.236
M10‑54/p.206
M10‑21/p.204
M09‑76/p.201
M06‑2/p.188
M10‑61/p.207
Yamazaki, Atsushi He‑2‑8/p.225
N1‑78/p.93
N1‑79/p.93
N1‑153/p.99
N1‑146/p.98
M18‑63/p.246
Yamazaki, Hiromichi M13‑6/p.218
Yamazaki, Ione M
N1‑121/p.96
Yamazaki, Makoto N1‑192/p.101
Yamazaki, Yoichi M20‑5/p.220
Yan, Shikui M21‑40/p.259
M18‑59/p.246
Yan, Zewu N10‑4/p.120
N10‑3/p.120
Yanagida, Takayuki N1‑176/p.100
N26‑5/p.163
N1‑177/p.100
N1‑79/p.93
N1‑175/p.100
N1‑146/p.98
N1‑78/p.93
N26‑7/p.163
N1‑145/p.98
He‑2‑8/p.225
Yang, Fan N1‑172/p.100
N25‑8/p.162
Yang, Feng‑Yi M16‑33/p.234
Yang, Gang YN1‑80/p.93
Yang, Ge R04‑8/p.106
R04‑27/p.108
R04‑11/p.107
R02‑3/p.84
JNMR‑5/p.126
R05‑2/p.124
R08‑4/p.170
R11‑2/p.193
R16‑3/p.222
R03‑4/p.85
Yang, Guian He‑1‑2/p.224
Yang, Hao R04‑54/p.110
R04‑15/p.107
R14‑4/p.195
Yang, Haori R04‑41/p.109
N1‑35/p.89
N1‑64/p.92
Yang, Hongwei N1‑27/p.89
Yang, Jianhua N1‑138/p.97
Yang, Kan N1‑135/p.97
Yang, Keedong M10‑53/p.206
Yang, Lei R04‑64/p.110
yang, li M19‑4/p.219
Yang, Seul Ki N1‑218/p.103
Yang, Yi M18‑66/p.246
Yang, Yigang N1‑85/p.93
Yang, Yongfeng M05‑2/p.188
M18‑22/p.243
M02‑2/p.166
M09‑79/p.201
M21‑32/p.258
Yang, Zhen He‑1‑2/p.224
Yang, Zhi M18‑82/p.248
Yangs, Ge R01‑3/p.84
R04‑62/p.110
Yao, Jingwu M15‑34/p.228
Yao, Rutao M10‑58/p.206
M15‑36/p.228
M10‑44/p.205
M18‑32/p.244
M21‑33/p.258
M21‑41/p.259
M17‑41/p.240
Yap, Li‑Peng M21‑13/p.257
Yarema, Raymond J
N14‑205/p.145
Yastrebov, Ilia N46‑2/p.216
Yasuda, Hiroshi N14‑194/p.144
Yasuda, K. R07‑1/p.169
Yasuda, Tetsuya N28‑8/p.165
Yatsu, Yoichi N12‑6/p.122
Ye, Bangjiao M16‑56/p.235
Ye, Hongwei M17‑9/p.237
M04‑4/p.167
M15‑41/p.229
M15‑38/p.229
M10‑29/p.204
Ye, Jingbo N31‑6/p.178
Ye, Jinghan M15‑8/p.226
Ye, Jong Chul M17‑48/p.240
Ye, Kevin M16‑53/p.235
Yeh, Yung‑Shun N14‑105/p.137
Yeo, Sunmog R04‑51/p.109
Yeom, Jung YM16‑14/p.232
M08‑7/p.190
M03‑3/p.167
Yeom, Jung‑Yeol M09‑60/p.200
M18‑16/p.243
M13‑2/p.218
Yevseyeva, Olga N14‑78/p.135
Yi, Hengguan N1‑27/p.89
Yi, Yun N1‑198/p.102
Yin, Yong‑Gen N27‑8/p.164
Yin, Yongzhi R04‑64/p.110
Yokoi, Kazuma R08‑2/p.169
Yokota, Yuui N1‑153/p.99
N26‑7/p.163
N1‑170/p.100
N1‑159/p.99
N1‑145/p.98
N1‑142/p.98
He‑2‑8/p.225
N1‑160/p.99
N1‑149/p.98
Yokote, Takahiko M18‑53/p.245
M18‑51/p.245
M18‑52/p.245
Yonggang, Wang N14‑10/p.129
M09‑7/p.196
N14‑169/p.142
Yonkeu, Andr N1‑58/p.91
Yoo, Hyunjun N1‑196/p.102
N1‑197/p.102
N14‑29/p.131
N1‑144/p.98
Yoo, Ran Ji M15‑51/p.230
Yoo, Wonsik N1‑141/p.98
Yoon, Hyun Suk M21‑38/p.259
Yoruk, Umit M21‑36/p.259
M09‑83/p.202
Yoshida, Eiji M18‑31/p.244
M16‑71/p.236
N14‑191/p.144
M22‑14/p.261
M18‑29/p.244
M17‑42/p.240
M16‑70/p.236
M16‑59/p.236
M16‑29/p.233
M16‑16/p.232
M16‑15/p.232
M13‑5/p.218
M10‑61/p.207
M10‑54/p.206
M10‑21/p.204
M09‑76/p.201
M06‑2/p.188
M22‑2/p.260
M12‑5/p.192
Yoshida, Jin M18‑63/p.246
Yoshikawa, Akira N1‑170/p.100
N26‑5/p.163
N1‑79/p.93
N1‑78/p.93
N1‑177/p.100
N26‑7/p.163
N1‑175/p.100
N1‑146/p.98
N1‑160/p.99
N1‑159/p.99
N1‑176/p.100
N1‑149/p.98
N1‑145/p.98
N1‑142/p.98
N1‑153/p.99
He‑2‑8/p.225
Yoshimatsu, Akina R04‑30/p.108
Yoshimuta, Toshinori R04‑30/p.108
Yoshino, Masao N12‑6/p.122
Yoshiyuki, Usuki M18‑20/p.243
Yosoi, Masaru N14‑162/p.141
Youn, Hanbean R04‑48/p.109
M15‑18/p.227
R04‑49/p.109
M10‑13/p.203
M10‑24/p.204
M10‑12/p.203
Younan, Nicolas H
N1‑39/p.90
Young, Frank CN1‑9/p.87
N42‑5/p.186
Young, John WN30‑5/p.178
Yousuf, Omair M22‑40/p.263
M15‑34/p.228
Yu, A Ram M22‑66/p.265
Yu, Baihui N1‑17/p.88
N1‑27/p.89
Yu, Hao N14‑106/p.137
Yu, Jae N38‑1/p.183
Yu, Jaehoon N38‑2/p.183
Yu, Jung Woo M15‑63/p.230
M15‑51/p.230
Yu, Zhicong M17‑53/p.241
Yuan, Hui N1‑150/p.98
Yubuta, Kunio N1‑142/p.98
Yue, Qian N14‑106/p.137
N1‑27/p.89
N14‑124/p.138
Yue, Xiaoguang N1‑27/p.89
N14‑33/p.131
Yun, Seungman M10‑24/p.204
R04‑48/p.109
M10‑13/p.203
M10‑12/p.203
Yun, Sueng Man M16‑60/p.236
Author Index 315
Yusa, Y. N14‑45/p.132
Yusa, Yosuke N17‑6/p.157
Yvon, Dominique F
N1‑116/p.96
N37‑1/p.182
z
Zahra, David M21‑49/p.259
M21‑31/p.258
M10‑51/p.206
Zaidi, Habib M19‑3/p.219
M18‑78/p.247
M17‑31/p.239
M17‑29/p.239
M15‑13/p.227
M22‑45/p.264
M15‑14/p.227
Zain, Rasif MR15‑5/p.221
R10‑3/p.171
Zaitseva, Natalia P
N1‑55/p.91
N1‑105/p.95
Zakrzewski, Bob N9‑8/p.120
Zambelli, Nicola R13‑3/p.194
R07‑3/p.169
R08‑6/p.170
R09‑1/p.170
R02‑1/p.84
Zambon, Pietro N14‑67/p.134
N20‑6/p.159
N14‑217/p.146
Zampa, Gianluigi N36‑5/p.182
N6‑5/p.118
Zampa, Nicola N36‑5/p.182
N6‑5/p.118
Zamyatin, Alexander A
M17‑23/p.239
M18‑75/p.247
M17‑22/p.238
M09‑10/p.196
M18‑82/p.248
M17‑47/p.240
M10‑41/p.205
Zani, Margherita M06‑6/p.189
M17‑15/p.238
N14‑177/p.143
Zanzi, Daniele N13‑3/p.122
N14‑157/p.141
Zapata, Cesar M22‑24/p.262
Zapf, Michael JNM‑3/p.125
Zappa, Franco N34‑3/p.180
N16‑5/p.156
Zappettini, Andrea R13‑3/p.194
R09‑1/p.170
R02‑1/p.84
R14‑2/p.195
R04‑57/p.110
R07‑3/p.169
R08‑6/p.170
Zatserklyaniy, Andriy N14‑166/p.141
N1‑111/p.95
R04‑24/p.107
N14‑192/p.144
Zaunick, Hans‑Georg N14‑219/p.146
Zazvorka, Jakub R10‑7/p.171
Zeitelhack, Karl N21‑6/p.160
N21‑8/p.160
Zemlicka, Jan R15‑1/p.221
Zen, Heishun N1‑18/p.88
Zen, Zhi N20‑4/p.158
Zeng, Gengsheng L
M09‑10/p.196
M17‑57/p.241
M22‑30/p.263
Zeng, Ming N14‑33/p.131
N1‑27/p.89
N14‑4/p.129
Zeng, Zhi N14‑33/p.131
N1‑27/p.89
Zerega, Yves N1‑130/p.97
Zerguerras, Thomas N39‑2/p.183
Zervakis, Manolis R15‑2/p.221
Zha, Gangqiang R04‑5/p.106
Zhang, Bin M10‑4/p.202
Zhang, Bo M09‑29/p.198
Zhang, Chengmo R04‑37/p.108
Zhang, Chunhui N21‑3/p.159
Zhang, Dong N14‑4/p.129
Zhang, Feng NR01‑8/p.223
R04‑7/p.106
R14‑4/p.195
Zhang, Gaigong N10‑4/p.120
Zhang, Guopeng M22‑42/p.264
Zhang, Hao M17‑13/p.238
M09‑59/p.200
Zhang, Hua M18‑91/p.248
M18‑92/p.248
Zhang, Hui N14‑170/p.142
Zhang, Jeff M20‑4/p.220
Zhang, Jiaguo Zhang N4‑7/p.83
Zhang, Jian‑Chuan R04‑67/p.111
M18‑44/p.245
R05‑4/p.124
Zhang, Li M09‑26/p.197
M09‑27/p.198
M09‑28/p.198
N1‑3/p.87
M17‑46/p.240
N1‑7/p.87
M18‑71/p.247
M22‑41/p.263
N1‑25/p.89
Zhang, Li yN25‑8/p.162
Zhang, Liyuan N1‑172/p.100
N41‑7/p.185
Zhang, Mengxi M02‑2/p.166
M18‑22/p.243
Zhang, Xiaodong N29‑6/p.177
N30‑6/p.178
N21‑3/p.159
N1‑214/p.103
Zhang, Xiaohui N1‑216/p.103
Zhang, Xuezhu M21‑25/p.258
M10‑26/p.204
M16‑37/p.234
M10‑42/p.205
Zhang, Yunwan M18‑92/p.248
Zhang, Yuxuan M21‑30/p.258
M03‑8/p.167
Zhang, Zheng M17‑23/p.239
M17‑22/p.238
Zhang, Zhige N14‑184/p.143
Zhao, Cuilan N1‑216/p.103
Zhao, Yubin He‑1‑2/p.224
Zhao, Ziran N1‑17/p.88
N1‑27/p.89
Zheng, Peng M18‑55/p.246
Zheng, Qian R04‑56/p.110
R02‑2/p.84
R04‑36/p.108
R08‑5/p.170
Zheng, Xiaofen M03‑7/p.167
M18‑21/p.243
Zheng, Yawen M16‑2/p.231
Zheng, Yi M16‑64/p.236
M15‑37/p.229
Zhivkova, Valentina N1‑21/p.88
Zhokor, Avideh N15‑7/p.155
Zhong, Min M15‑17/p.227
Zhou, Bing N31‑7/p.179
Zhou, Jian M19‑4/p.219
M18‑42/p.245
M18‑22/p.243
M21‑34/p.258
M04‑4/p.167
M02‑2/p.166
Zhou, Jianrong He‑1‑2/p.224
Zhou, Xin N4‑6/p.83
Zhou, Yao N1‑150/p.98
Zhou, Yun M07‑5/p.189
M22‑64/p.265
Zhou, Zhenzhen N1‑143/p.98
Zhu, Diling N1‑237/p.105
316 Author Index Zhu, Feng‑ming N1‑57/p.91
Zhu, Hongbin M22‑42/p.264
Zhu, Jun M16‑2/p.231
Zhu, Kejun N14‑153/p.140
Zhu, Lei M15‑10/p.226
M09‑25/p.197
Zhu, Nuo SN1‑80/p.93
Zhu, Peng N1‑27/p.89
Zhu, Ren‑Yuan N25‑8/p.162
N41‑7/p.185
N1‑172/p.100
Zhu, Shaofei N20‑2/p.158
Zhu, Wei M22‑42/p.264
Zhu, Wentao M22‑29/p.263
Zhu, Xuezhou N16‑8/p.156
N14‑238/p.147
Zhu, Xuping M22‑23/p.262
Zhu, Yuefeng R04‑54/p.110
R04‑23/p.107
R04‑20/p.107
Zhuravleva, Mariya N1‑132/p.97
Zibell, Andre N13‑3/p.122
Zieblinski, Miroslaw N39‑2/p.183
Ziegler, Jeff BN1‑88/p.94
Ziegler, Sibylle IN37‑2/p.182
M21‑20/p.257
M17‑30/p.239
M09‑48/p.199
M21‑19/p.257
M10‑75/p.208
Ziemons, Karl M15‑47/p.229
Zier, Jacob CN1‑5/p.87
N1‑16/p.88
N42‑5/p.186
N1‑42/p.90
N11‑3/p.121
He‑2‑7/p.225
N15‑1/p.155
Zimmer, Luc M21‑16/p.257
Zimmerman, Tom N4‑6/p.83
Zimmermann, Sergio N20‑2/p.158
Zimmermann, Stephanie N31‑4/p.178
Zinets, Oleg N37‑7/p.183
Zinke, Manfred M10‑66/p.207
M09‑65/p.200
Ziock, Klaus‑Peter N1‑53/p.91
N8‑5/p.119
N8‑8/p.119
N1‑155/p.99
Zioga, Maria M09‑77/p.201
M18‑73/p.247
M16‑41/p.234
Zito, Felicia M17‑6/p.237
Zitzer, Benjamin J
N14‑235/p.147
Zocca, Francesca N9‑6/p.120
Zoccarato, Yannick N24‑7/p.162
N16‑2/p.156
M22‑10/p.261
Zoglauer, Andreas N1‑48/p.90
N28‑6/p.165
N15‑7/p.155
N14‑82/p.135
N14‑240/p.136
N7‑3/p.118
N14‑49/p.132
N3‑7/p.82
Zontar, Dejan N14‑110/p.137
M21‑28/p.258
N14‑185/p.143
Zorn, Carl M18‑9/p.242
N1‑185/p.101
Zorzi, Nicola N14‑154/p.140
N45‑8/p.216
N1‑206/p.102
N1‑182/p.101
N14‑53/p.132
N14‑204/p.145
Zosim, Dmitry N1‑161/p.99
Zubal, George M16‑34/p.234
Zubarev, Peter VN14‑103/p.137
N14‑102/p.137
Zuber, Marcus R10‑1/p.171
Zucca, Stefano N29‑2/p.177
Zvelebil, Marketa M10‑65/p.207
R15‑3/p.221
Zwaans, Ben M02‑3/p.166
M12‑1/p.191
M12‑2/p.192
Zwerger, Andreas R15‑1/p.221
R14‑5/p.195
R10‑1/p.171
R09‑2/p.170
R04‑53/p.110
R04‑39/p.108
R04‑3/p.106
N10‑7/p.121
JNMR‑4/p.126
Zygmanski, Piotr M09‑6/p.196
Author Index 317
Acknowledgement
T
he success of the 2012 Nuclear Science Symposium,
Medical Imaging Conference, and Room Temperature
Semiconductor Detector Workshop is only possible due to
the tremendous effort of the organizing committee and all the other
volunteers associated with the conference. Their efforts to organize all
of the scientific and social functions as well as manage the daunting
financial and logistical issues while still working at their “day job” are
the cornerstone of what makes this conference such a success from
year to year. This year, we set a record for the number of abstract
submissions for a site in the United States and are expecting the
largest number of attendees to a US site in the history of the event. I
offer my very sincere thanks - for a job well done.
This conference, and the ability of the volunteers to work on it, is made
possible through the sponsorship of the IEEE Nuclear and Plasma
Sciences Society (NPSS) and through the generous support of the
cooperating institutions and organizations listed on the inside front
cover. I am indeed fortunate to have such a hard working and skilled
committee - the key to the success of such a complex conference.
All of the committee members have shown their dedication to the
conference, their willingness to compromise where needed, and their
ability to work together - even over long distances.
Of course, there would not be a conference without the outstanding
contributions from all of the authors and attendees. I wish to thank
you for continuing to assure that the IEEE NSS/MIC and the RTSD
maintains its reputation for the outstanding intellectual and scientific
content of the conference.
Tom Lewellen
General Chair
NSS Topic Conveners
Etiennette Auffray, CERN, Switzerland
Sergey Barsuk, LAL Orsay, France
Adam Bernstein, Lawrence Livermore National Laboratory, USA
James E Brau, University of Oregon, USA
Diego Casadei, New York University, USA
Gianluigi Casse, Dep. of Physics, University of Liverpool, United Kingdom
Seonho Choi, Seoul National University, South Korea
Paul Colas, CEA/IRFU, France
Christophe de La Taille, IN2P3 / CNRS, France
Peter Denes, Lawrence Berkeley National Laboratory, USA
Grzegorz Deptuch, Fermilab, USA
Serge Duarte Pinto, CERN, Switzerland
Guenter Eckerlin, DESY, Germany
Doris Eckstein, Deutsches Elektronen-Synchrotron DESY, Germany
Ralf Engels, Forschungszentrum Juelich GmbH, Germany
Lorenzo Fabris, Oak Ridge National Laboratory, USA
Luigi Gaioni, INFN Pavia, Italy
Erika Garutti, University of Hamburg, Germany
Daniel Haas, SRON Netherlands Institute for Space Research, Netherlands
Ryosuke Itoh, KEK, Japan
HongJoo Kim, Department of Physics, Kyungpook National University, South Korea
Richard T Kouzes, PNNL, USA
Peter Krizan, University of Ljubljana, Slovenia
Susanne Kuehn, University of Freiburg, Germany, Germany
Markus Kuster, European XFEL GmbH, Germany
Patrick JL Le Du, IPNL, IN2P3, France
Tiehui Ted Liu, Fermilab, USA
Abdallah Lyoussi, CEA / French Atomic Energy Commission, France
Maria Grazia Pia, INFN Genova, Italy
Sara Pozzi, University of Michigan, USA
Leszek Ropelewski, CERN, Switzerland
Marc Ross, SLAC National Accelerator Laboratory, USA
Maxim P. Titov, CEA Saclay, IRFU/SPP, France
John Valentine, SAIC, USA
Marc Winter, IPHC - IN2P3/CNRS, France
Douglas Wright, Lawrence Livermore National Laboratory, USA
Bo Yu, Brookhaven National Laboratory, USA
Jae Yu, Univ. of Texas Arlington, USA
NSS Reviewers
John N Aarsvold, Atlanta Veterans Affairs Medical Center & Emory University, USA
Marcello Abbrescia, University of Bari, Italy
Toshinori Abe, Japan Synchrotron Radiation Research Institute, Japan
Anthony Affolder, University of Liverpool, Department of Physics, United Kingdom
Alberto Aloisio, University of Naples ‘Federico II’ and I.N.F.N., Italy
George Alverson, Northeastern Univ., USA
Giovanni Ambrosi, INFN Sezione di Perugia Italy, Italy
Mark Amman, Lawrence Berkeley National Laboratory, USA
Ladislav Andricek, MPI fuer Physik, Munich, Germany
Robert Andritschke, Max-Planck-Institut Halbleiterlabor, Germany
Yasuo Arai, KEK, Japan
Pedro Arce, CIEMAT, Spain
Tsukasa Aso, Nagaoka University of Technology, Japan
Etiennette Auffray, CERN, Switzerland
318 Acknowledgement Acknowledgement 319
Rachel M Avramidou, National Technical University of Athens, Greece
Sunanda Banerjee, FNAL, USA
Brad Barber, University of Arizona, USA
Thomas Barber, University of Freiburg, Germany
William C Barber, DxRay Inc., USA
Sergey Barsuk, LAL Orsay, France
Paul J Barton, Lawrence Berkeley National Laboratory, USA
Matej Batic, Institute Jožef Stefan, Slovenia
Marco Battaglia, SCIPP - UCSC and LBNL, USA
Marcia Begalli, State University of Rio de Janeiro, Brazil
Steven Bellinger, Kansas State University, USA
Gregory A Bizarri, LBNL - Berkeley, USA
Christian Bohm, University of Stockholm, Department of Physics, Sweden
Aleksey E Bolotnikov, Brookhaven National Laboratory, USA
Maurizio M. Bonesini, Sezione INFN Milano Bicocca, Italy
Edith Bourret, Lawrence Berkeley National Laboratory, USA
Nathaniel Bowden, Lawrence Livermore National Laboratory, USA
Chuck L. Britton, Oak Ridge National Lab, USA
Erik Brubaker, Sandia National Laboratories, CA, USA
Mara Bruzzi, Dipartimento di Energetica di Firenze, Italy
Morgan T Burks, Lawrence Livermore National Laboratory, USA
Sergey A Butsyk, University of New Mexico, USA
Belkis Cabrera-Palmer, Sandia National Laboratories, USA
Massimo L. Caccia, Università dell’Insubria, Italy
Paolo Calafiura, Lawrence Berkeley National Laboratory, USA
Mar Capeans, CERN, Switzerland
Alessandro X. D. Cardini, INFN Sezione di Cagliari, Italy
Michael E Casey, Siemens Medical Solutions, USA
Gabriella Catanesi, INFN Bari, Italy
Anna Cavallini, Department of Physics University of Bologna, Italy
Arion F Chatziioannou, UCLA Crump Institute, USA
Nerine Cherepy, Lawrence Livermore National Laboratory, USA
Giorgio Chiarelli, INFN Sez. di Pisa, Italy
David Chichester, Idaho National Laboratory, USA
Gabriele Chiodini, Istituto Nazionale di Fisica Nucleare - Lecce, Italy
Remi Chipaux, CEA DSM/IRFU/SEDI, France
Finn Christensen, Danish National Space Center, Denmark
Radovan Chytracek, R. C. Consult, Switzerland
Neal Clinthorne, University of Michigan, USA
David J.A. Cockerill, Rutherford Appleton Laboratory, United Kingdom
Anna Colaleo, INFN-Bari, Italy
Paul Colas, CEA/IRFU, France
Juan I. Collar, Enrico Fermi Institute, USA
Maurizio Conti, Siemens, USA
John A Correia, Massachusetts General Hospital/Harvard Medical School, USA
Gloria Corti, CERN, Switzerland
Cinzia Da Via, University of Manchester /CERN, United Kingdom
Ioan Dafinei, Istituto Nazionale di Fisica Nucleare, Italy
Magnus Dahlbom, David Geffen School of Medicine at UCLA, USA
Gian-Franco Dalla Betta, University of Trento and INFN, Italy
Maurizio Dapor, Interdisciplinary Laboratory for Computational Science, FBK,
Trento, Italy
Mohammad Dawood, University of Münster, Germany
Steven a Dazeley, LLNL, USA
Riccardo de Asmundis, INFN, Napoli, Italy
Christophe de La Taille, IN2P3 / CNRS, France
Andrea Dell’Acqua, CERN, Switzerland
320 Acknowledgement Stephen E Derenzo, Lawrence Berkeley National Laboratory, USA
Timothy DeVol, Clemson University, Environmental Engineering and Earth
Sciences Department, USA
Anna Di Ciaccio, university of roma tor vergata and INFN, Italy
Hans Dijkstra, CERN, Switzerland
Avraham Dilmanian, Brookhaven National Laboratory, USA
Guenther Dissertori, Institute for Particle Physics, ETH Zurich, Switzerland
Wojciech Dominik, Warsaw University, Poland
Pieter Dorenbos, Delft University of Technology, Netherlands
Fred Patrick Doty, Sandia National Laboratory, USA
Winicjusz Drozdowski, Nicolaus Copernicus University, Poland
Serge Duarte Pinto, CERN, Switzerland
Christophe Dujardin, University Lyon1, France
Doris Eckstein, Deutsches Elektronen-Synchrotron DESY, Germany
Ralf Engels, Forschungszentrum Juelich GmbH, Germany
Anna Erickson, LLNL, USA
Lars A Eriksson, Siemens Medical Solutions, Molecular Imaging, USA
Lorenzo Fabris, Oak Ridge National Laboratory, USA
Riccardo Fantechi, INFN - Sezione di Pisa, Italy
Viviana Fanti, Dipartimento di Fisica dell’Universita’ di Cagliari e INFN sezione
di Cagliari, Italy
Philippe Farthouat, CERN, Switzerland
Alberto Fazzi, Politecnico di Milano, Italy
Alessandro Ferretti, Torino University and INFN, Italy
Fernando Ferroni, Universita’ di Roma La Sapienza & INFN Roma, Italy
Carlo Fiorini, Politecnico di Milano, Italy
Marek Flaska, University of Michigan, USA
Angela M Foudray, St Cloud State University, USA
Rudolf Fruehwirth, Institute of High Energy Physics, Vienna, Austria
Lars R Furenlid, University of Arizona, USA
Nikolai Z Galunov, Institute for Scintillation Materials, National Ac.Science of
Ukraine, Ukraine
Francisco Garcia, Helsinki Institute of Physics and Department of Physcal
Sciences, University of Helsinki, Finland
Maurice Garcia-Sciveres, LBNL, USA
Marat I Gataullin, California Institute of Technology, USA
Romain Gaume, University Central Florida, USA
Evangelos N. Gazis, National Technical University of Athens, Greece
Hartmut Gemmeke, Forschungszentrum Karlsruhe, Germany
Dimitry Ginzburg, Radiation Detection Department, Rotem Industries Ltd, , Israel
Thomas Glanzman, Stanford Linear Accelerator Center, USA
Jarek Glodo, Radiation Monitoring Devices, USA
Andrew L Goertzen, University of Manitoba, Canada
Faustino Gomez, University of Santiago, Spain
Heinz Graafsma, DESY, Germany
Fabiana Gramegna, Laboratori Nazionali di Legnaro - I.N.F.N., Italy
Francesco Grancagnolo, Istituto Nazionale di Fisica Nucleare, Italy
Vladimir Grichine, P.N. Lebedev Physical Institute of RAS, Russian Federation
Joern Grosse-Knetter, Univertsitaet Goettingen, Germany
Martin Grossmann, PSI, Switzerland
Chiara Guazzoni, Politecnico di Milano and INFN, Italy
Frezghi Habte, Stanford University, USA
Michael Hagelstein, Karlsruhe Institute of Technology, Germany
Andreas Haungs, Karlsruhe Institute of Technology - KIT, Germany
Nolan Hertel, Georgia Institute of Technology, USA
Richard D Hichwa, University of Iowa, USA
Hartmut Hillemanns, CERN, Switzerland
Nathan Hilton, Sandia National Labs, USA
Acknowledgement 321
Gabriela Hoff, Pontifical Catholic University in Rio Grande do Sul, Brazil
Jaesub Hong, Harvard-Smithsonian Astrophysical Observatory, USA
Seong Jong Hong, Seoul Nat’l Univ. College of Medicine, South Korea
Alexander S Howard, ETH, Zurich, Switzerland
Zhifeng Huang, UCLA, USA
Hirokazu Ikeda, ISAS, JAXA, Japan
Pier Giorgio Innocenti, CERN, Switzerland
Jan S. Iwanczyk, DxRay, Inc., USA
Joanna Iwanowska, National Centre for Nuclear Research, Poland
Hiroyuki Iwasaki, KEK, Japan
Martin Janecek, Lawrence Berkeley National Laboratory, USA
Pierre Jarron, cern university of Torino, Switzerland
Valentin T Jordanov, Yantel, LLC, USA
Kei Kamada, Furukawa Co., Ltd., Japan
Anuj Kapadia, Dept of Radiology, Medical Physics Graduate Program, Duke
University, USA
Jan Kaplon, CERN, Switzerland
Alireza Kargar, RMD Inc., USA
Dean Karlen, University of Victoria, Canada
Scott D Kiff, Sandia National Laboratories, USA
HongJoo Kim, Department of Physics, Kyungpook National University, South Korea
Yong-Kyun Kim, Hanyang University, South Korea
Bernadette Kirk, ORNL, USA
Nikolay Vladimir Klassen, Institute of Solid State Physics, Russian Academy of
Sciences, Russian Federation
Juergen Knobloch, CERN, Switzerland
Mikhail Korjik, RINP, Minsk, Belarus, Belarus
Danek Kotlinski, Paul Scherrer Institute, Switzerland, Switzerland
Richard T Kouzes, PNNL, USA
Peter Krizan, University of Ljubljana, Slovenia
Markus Kuster, European XFEL GmbH, Germany
Ernesto Lamanna, Magna Graecia University Cz & INFN Gruppo Collegato
Cs, Italy
Joern Lange, University of Hamburg,
Richard C Lanza, MIT, USA
Wim T.L.P. Lavrijsen, LBNL, USA
Patrick JL Le Du, IPNL, IN2P3, France
James W LeBlanc, GE Research, USA
Roger Lecomte, Université de Sherbrooke, Canada
Paul R Lecoq, CERN, Switzerland
Kisung Lee, Korea University, South Korea
Wonho Lee, Korea University, South Korea
Charles Leggett, Lawrence Berkeley National Laboratory, USA
Craig S. Levin, Stanford University, USA
Micheal LeVine, Brookhaven National Laboratory, USA
Lorne J Levinson, Weizmann Institute of Science, Israel
Dietrich Liko, HEPHY Vienna, Austria
Ronald Lipton, Fermilab, USA
Herbert Loehner, KVI, University Groningen, Netherlands
Francesco Longo, Department of Physics, University of Trieste and INFN,
Trieste, Italy
Eleonora Luppi, Ferrara University and INFN, Italy
Hong Ma, Brookhaven National Laboratory, USA
Alexander B Mann, Technische Universität München, Germany
Thomas Markiewicz, SLAC National Accelerator Laboratory, USA
Peter A Marleau, Sandia National Laboratories, USA
322 Acknowledgement John Mattingly, North Carolina State University, USA
Robert M Mayo, Johns Hopkins University Applied Physics Laboratory, USA
Giovanni Mazza, INFN sez. di Torino, Italy
Tom Meyer, , Switzerland
Satoshi Mihara, KEK, Japan
Teodor I. Milenov, Institute of Solid State Physics, Bulgarian Academy of
Sciences, Bulgaria
Oleg V Missevitch, Institute for Nuclear Problems, Minsk, Belarus
Gregory S Mitchell, UC Davis, USA
Guenakh Mitselmakher, University of Florida, USA
Jun Miyamoto, Lousiana State University, USA
Michael Moll, CERN, Switzerland
Christian Morel, CPPM, Aix-Marseille II University, France
William W. Moses, Lawrence Berkeley National Laboratory, USA
Marek Moszynski, National Centre for Nuclear Reserarch, Poland
Hideo Murayama, National Institute of Radiological Sciences, Japan
Yuri Musienko, FNAL/INR(Moscow), Switzerland
Andreas Mussgiller, DESY, Germany
Alfredo Musso, INFN-Torino, Italy
Eugenio Nappi, INFN Sezione di Bari, Italy, Italy
Filippo Nava, Dipartimento di Fisica Università di Modena e Reggio Emilia, Italy
Francesca Nessi-Tedaldi, ETH Zurich, Switzerland
Martin Nikl, Institute of Physics of Academy of Sciences of the Czech Republic,
Czech Republic
Rainer W Novotny, 2nd Physics Institute, University Giessen, Germany
Horst G. Oberlack, MPI fuer Physik, Munich, Germany
Eraldo Oliveri, CERN,
Yasar Onel, Univ. of Iowa, USA
Thomas Otto, Technology Department, TE-HDO, CERN, Switzerland
Anna Maria Paganoni, ,
Roberto Pani, Sapienza University of Rome, Italy
Marc Paterno, FNAL, USA
Mark Pearce, Kungl Tekniska Högskolan, KTH, Sweden
Stephen Peggs, Brookhaven National Laboratory, USA
Anna Peisert, CERN, Switzerland
Marco Petasecca, Centre of Medical Radiation Physics - University of Wollongong,
Australia
Todd E Peterson, Vanderbilt University, USA
Ashot Petrosyan, Institute for Physical Research, National Academy of Science
of Armenia, Armenia
Roberto Petti, CERN, Switzerland
Andreas Pfeiffer, CERN, Switzerland
Michael J Pivovaroff, Lawrence Livermore National Laboratory, USA
Vlladimir Popov, Thomas Jefferson National Accelerator Facility, USA
Stanislav Pospisil, Institute of Experimental and Applied Physics, Czech Technical
University in Prague, Czech Republic
Michela Prest, universita` dell’Insubria e INFN Milano Bicocca, Italy
Martin L Purschke, Brookhaven National Lab, USA
Francesco Quarati, Faculty of Applied Science, Delft University of Technology,
Netherlands
Lina Quintieri, INFN - LNF, Italy
Francisco Javier Ramírez-Jiménez, Instituto Nacional de Investigaciones
Nucleares, Mexico
Lodovico Ratti, University of Pavia, Italy
Federico Ravotti, CERN, Switzerland
Guohao Ren, Shanghai Institute of Ceramics, China
Jose Repond, Argonne National Laboratory, USA
Acknowledgement 323
Stefan Ritt, Paul Scherrer Institute, Switzerland
Angelo Rivetti, Istituto Nazionale di Fisica Nucleare - INFN - Sezione di Torino,
Italy
Pedro Rodrigues, Philips Research Europe, Netherlands
Stefan Roiser, CERN, Switzerland
Anatoli Romaniouk, CERN, Swaziland
Leszek Ropelewski, CERN, Switzerland
Gary J Royle, University College London, United Kingdom
Paolo Russo, Universita’ di Napoli Federico II and INFN Napoli, Italy
Lorraine E Sadler, Sandia National Laboratories, USA
Hartmut F.-W. Sadrozinski, Santa Cruz Institute for Particle Physics, Univ. of
California Santa Cruz, USA
Kaoru Sakasai, Japan Atomic Energy Agency, Japan
Denison Souza Santos, Instituto de Radioproteção e Dosimetria, Brazil
Paolo Saracco, INFN Genova, Italy
Takashi Sasaki, KEK, Japan
Dennis Schaart, Delft University of Technology, Netherlands
Burkhard Schmidt, CERN, Switzerland
Joao Seco, Massachusetts General Hospital,
Felix Sefkow, DESY, Germany
Carolyn E. Seifert, Pacific Northwest National Laboratory, USA
Youngho Seo, University of California, San Francisco, USA
Yiping Shao, The University of Texas M.D. Anderson Cancer Center, USA
Nataliia V Shiran, scientist, Ukraine
Frank Simon, Max-Planck-Institut fuer Physik, Germany
Graham Smith, Brookhaven National Laboratory, USA
Michael Squillante, Radiation Monitoring Devices, Inc., USA
Maya Stavrianakou, CERN and DAT NCSR DEMOKRITOS, Greece
Daniel L Stephens Jr., Pacific Northwest National Laboraotry, USA
Roberto Stroili, INFN Padova, Italy
Bjarne Stugu, Univ. Bergen, Norway
Benjamin W Sturm, Lawrence Livermore National Laboratory, USA
Takayuki Sumiyoshi, Tokyo Metropolitan University, Japan
Suleman Surti, University of Pennsylvania, USA
Lukasz Swiderski, National Centre for Nuclear Research, Poland
Tomasz Szczesniak, National Centre for Nuclear Research, Poland
Hiroyasu Tajima, Solar-Terrestrial Environment Laboratory, Nagoya University,
Japan
Hui Tan, XIA LLC, USA
Manobu Tanaka, KEK IPNS, Japan
Stefaan P Tavernier, Vrije Universiteit Brussel, Belgium
Martin P Tornai, Duke University Medical Center, USA
Gerard Tranquille, CERN, Switzerland
Andreia M A Trindade, Philips Research, Netherlands
Kenan Unlu, Pennsylvania State University, USA
Michela C.A. Uslenghi, INAF/Iasf-Milano, Italy
Jiri Vacik, Nuclear Physics Institute, Academy of Sciences of the Czech Republic,
Czech Republic
John Valentine, SAIC, USA
Vladivoj Valkovic, A.C.T.d.o.o., Croatia
Erik Vallazza, INFN - Istituto Nazionale di Fisica Nucleare, Sezione di Trieste, Italy
Richard Van Berg, University of Pennsylvania, USA
Harry van der Graaf, Nikhef, Netherlands
Edgar V Van Loef, Radiation Monitoring Devices, Inc., USA
Arne Vandenbroucke, Stanford University, USA
Marie Vanstalle, GSI Helmholtz Centre for Heavy Ion Research, Germany
Gary S Varner, Univ. of Hawaii, USA
324 Acknowledgement Rob Veenhof, CERN and Wisconsin, Switzerland
Jaap Velthuis, Bristol University, United Kingdom
Ludo Vermeeren, SCK-CEN, Belgium,
Sergey Vinogradov, Lebedev Physical Institute of the Russian Academy of
Jan L. Visschers, NIKHEF Amsterdam, Netherlands
Wolfgang Waltenberger, Hephy Vienna, Austria
Kenichi Watanabe, Nagoya University, Division of Quantum Science and
Energy Engineering, Japan
Gordon T. Watts, University of Washington, USA
Marc M Weber, Karlsruhe Institute of Technology, Germany
Georg Weidenspointner, MPI Halbleiterlabor, Germany
Andrew G Weisenberger, Thomas Jefferson National Accelerator Facility, USA
Andy P White, University of Texas at Arlington, USA
Richard Wigmans, Texas Tech University, USA
Crispin Williams, INFN Bologna, Italy
William Wisniewski, SLAC National Accelerator Laboratory, USA
Mitchell Woodring, Pacific Northwest National Laboratory, USA
Craig L Woody, Brookhaven National Lab, USA
Douglas Wright, Lawrence Livermore National Laboratory, USA
Yibao Wu, Digirad, USA
Claudia-Elisabeth Wulz, Oesterreichische Akademie der Wissenschaften, Austria
Seiichi Yamamoto, Nagoya University Graduate School of Medicine, Japan
Takayuki Yanagida, NICHe, Tohoku University, Japan
Kan Yang, Saint-Gobain Crystals, USA
Yushu Yao, Lawrence Berkeley National Laboratory, USA
Julia V. Yarba, Fermilab, USA
Charles C Young, SLAC, USA
John Young, Savannah River National Laboratory, USA
Jae Yu, Univ. of Texas Arlington, USA
Hui Yuan, Shanghai Institute of Ceramics, China
Habib Zaidi, Geneva University Hospital, Switzerland
Christos Zamantzas, CERN, Switzerland
Liyuan Zhang, California Institute of Technology, USA
Nan Zhang, Siemens, USA
Ren-yuan Zhu, California Institute of Technology, USA
Mariya Zhuravleva, Scintillation Materials Research Center, University of
Tennessee, USA
Sibylle Ziegler, Nuklearmedizin Klinikum rechts der Isar der TU München,
Germany
Klaus P Ziock, Oak Ridge National Laboratory, USA
Andreas Zoglauer, University of California at Berkeley, USA
MIC Reviewer
John N Aarsvold, Atlanta Veterans Affairs Medical Center & Emory University, USA
Pablo Aguiar, Fundacion IDICHUS, Complexo Hospitalario Universitario de
Santiago de Compostela, Spain
Adam M Alessio, University of Washington, USA
Giovanni Ambrosi, INFN Sezione di Perugia Italy, Italy
Pedro Arce, CIEMAT, Spain
Evren Asma, General Electric Global Research, USA
Tsukasa Aso, Nagaoka University of Technology, Japan
Ramsey D Badawi, UC Davis Medical Center, USA
Bing Bai, University of Southern California, USA
Chuanyong Bai, Digirad Corporation, USA
Girish Bal, Siemens Healthcare, USA
Harshali Bal, Siemens Medical Solutions - MI, USA
Brad Barber, University of Arizona, USA
William C Barber, DxRay Inc., USA
Marco Battaglia, SCIPP - UCSC and LBNL, USA
Acknowledgement 325
Freek J Beekman, Delft University of Technology, Netherlands
Simone Beer, Central Institute for Electronics, Forschungszentrum Juelich,
Germany
Bernard Bendriem, Siemens Molecular Imaging, USA
M’hamed Bentourkia, Université de Sherbrooke, Canada
Christian Bohm, University of Stockholm, Department of physics, Sweden
Alexandre Bousse, Institute of Nuclear Medicine, UCL, United Kingdom
Spencer L Bowen, Massachusetts General Hospital, USA
Jovan G Brankov, Illinois Institute of Technology, USA
David Brasse, Institut Pluridisciplinaire Hubert Curien, France
Mara Bruzzi, Dipartimento di Energetica di Firenze, Italy
Iréne Buvat, IMNC UMR 8165 CNRS, Orsay, France
Richard E. Carson, Yale University, USA
James A Case, Cardiovascular Imaging Technologies, USA
Michael E Casey, Siemens Medical Solutions, USA
Ciprian Catana, Massachusetts General Hospital, USA
Anna M Celler, University of British Columbia, Canada
Kyle Champley, GE Global Research, USA
Arion F Chatziioannou, UCLA Crump Institute, USA
Abhijit J Chaudhari, UC Davis School of Medicine, USA
Stephane Chauvie, Santa Croce e Carle Hospital, Italy
Chin-Tu Chen, The University of Chicago, USA
Ju-Chieh (Kevin) Cheng, Department of Radiology, Washington University in
St. Louis, USA
Nerine Cherepy, Lawrence Livermore National Laboratory, USA
Simon R Cherry, University of California-Davis, USA
Garry Chinn, Stanford School of Medicine, USA
Gabriele Chiodini, Istituto Nazionale di Fisica Nucleare - Lecce, Italy
Yong Choi, Sogang University, South Korea
Cecil Chow Robilotta, University of Sao Paulo, Brazil
Yong Hyun Chung, Department of Radiological Science, College of Health
Science, Yonsei University, South Korea
Carlo Civinini, INFN-Firenze, Italy
Rolf Clackdoyle, Laboratoire Hubert Curien, CNRS, St. Etienne, France
Neal Clinthorne, University of Michigan, USA
Claude Comtat, SHFJ, CEA, France
Maurizio Conti, Siemens, USA
Alexander K Converse, University of Wisconsin-Madison, USA
John A Correia, Massachusetts General Hospital/Harvard Medical School, USA
Albert Cot, Universitat de Barcelona, Spain
Francesco Cusanno, TU Muenchen, Germany
Cinzia Da Via, University of Manchester /CERN, United Kingdom
Magnus Dahlbom, David Geffen School of Medicine at UCLA, USA
Yves D’Asseler, MEDISIP-UGent, Belgium
Margaret E. Daube-Witherspoon, University of Pennsylvania, USA
Mohammad Dawood, University of Münster, Germany
Bruno De Man, GE Research, USA
Michel Defrise, Dept. of Nuclear Medicine, Vrije Universiteit Brussel, Belgium
Robert deKemp, University of Ottawa Heart Institute, Canada
Stephen E Derenzo, Lawrence Berkeley National Laboratory, USA
Laurent Desbat, TIMC-IMAG, Grenoble University (UJF), France
Philippe Després, Centre hospitalier universitaire de Québec, Canada
Yuni K Dewaraja, University of Michigan, USA
Frank P DiFilippo, Cleveland Clinic, USA
Wojciech Dominik, Warsaw University, Poland
Huini Du, Toshiba Medical Research Institute USA, Inc., USA
Yong Du, Johns Hopkins Medical Institutions, USA
Georges El Fakhri, Harvard Medical School and Massachusetts General Hospital, USA
326 Acknowledgement Ralf Engels, Forschungszentrum Juelich GmbH, Germany
Lars A Eriksson, Siemens Medical Solutions, Molecular Imaging, USA
Kjell Erlandsson, University College London, United Kingdom
Riccardo Fantechi, INFN - Sezione di Pisa, Italy
Viviana Fanti, Dipartimento di Fisica dell’Universita’ di Cagliari e INFN sezione
di Cagliari, Italy
Troy H Farncombe, Hamilton Health Sciences / McMaster University, Canada
Jeff Fessler, University of Michigan, USA
Fine Fiedler, Helmholtz-Zentrum Dresden-Rossendorf, Germany
Carlo Fiorini, Politecnico di Milano, Italy
Angela M Foudray, St Cloud State University, USA
Eric C Frey, Johns Hopkins University, USA
Roger R Fulton, Westmead Hospital, Australia
Tobias Funk, Triple Ring Technologies, USA
Lars R Furenlid, University of Arizona, USA
Daniel Gagnon, Toshiba Medical Research Institute, USA, USA
Franco Garibaldi, Istituto Superiore di Sanita’ and INFN Roma, Italy
Romain Gaume, University Central Florida, USA
Howard C Gifford, University of Houston, USA
David R. Gilland, University of Florida, USA
Stephen J Glick, Univ. of Massachusetts Medical School, USA
Andrew L Goertzen, University of Manitoba, Canada
faustino gomez, University of Santiago, Spain
Heinz Graafsma, DESY, Germany
Michael V Green, Molecular Imaging Program/NIH, USA
Martin Grossmann, PSI, Switzerland
Songxiang Gu, FDA, USA
Chiara Guazzoni, Politecnico di Milano and INFN, Italy
Frezghi Habte, Stanford University, USA
James J Hamill, Siemens Healthcare, USA
Robert L Harrison, University of Washington, Germany
Tomoyuki Hasegawa, Allied Health Sciences, Kitasato University, Japan
Hans Herzog, Institute of Neuroscience and Biophysics - Medicine,
Forschungszentrum Juelich, Germany
Richard D Hichwa, University of Iowa, USA
Hartmut Hillemanns, CERN, Switzerland
Seong Jong Hong, Seoul Nat’l Univ. College of Medicine, South Korea
Jiang Hsieh, GE Healthcare, USA
Sung-Cheng (Henry) Huang, UCLA David Geffen School of Medicine, USA
Zhifeng Huang, UCLA, USA
Jennifer S Huber, Lawrence Berkeley National Lab, USA
Ronald H Huesman, Lawrence Berkeley Lab, USA
James W Hugg, Gamma Medica, USA
Brian F Hutton, Institute of Nuclear Medicine, UCL, London, United Kingdom
Hidehiro Iida, National Cerebral & Cardio-Vascular Center, Japan
Marijana Ivanovic, University of North Carolina, Chapel Hill, USA
Jan S. Iwanczyk, DxRay, Inc., USA
Bjoern W Jakoby, Siemens Medical Solutions, USA
Martin Janecek, Lawrence Berkeley National Laboratory, USA
Floris P Jansen, GE Research, USA
Pierre Jarron, cern university of Torino, Switzerland
Ronald J. Jaszczak, Professor Emeritus of Radiology, Duke University Medical
Center, USA
Marc Kachelriess, German Cancer Research Center (DKFZ), Heidelberg,
Germany, Germany
Dan J Kadrmas, University of Utah, USA
Acknowledgement 327
Kei Kamada, Furukawa Co., Ltd., Japan
Chien-Min Kao, The University of Chicago, USA
Nikolaos Karakatsanis, Postdoctoral Fellow, Johns Hopkins Medical Institutions, USA
Joel S Karp, University of Pennsylvania, USA
Brad J Kemp, Mayo Clinic, USA
Marie Foley Kijewski, Brigham and Women’s Hospital and Harvard Medical
School, USA
Ho Kyung Kim, Pusan National University, South Korea
Kyeong Min Kim, Korea Institute of Radiological and Medical Sciences, South
Korea
Yong-Kyun Kim, Hanyang University, South Korea
Paul E Kinahan, University of Washington, USA
Michael A King, Univ of Mass Med School, USA
Nikolay Vladimir Klassen, Institute of Solid State Physics, Russian Academy of
Juergen Knobloch, CERN, Switzerland
George Kontaxakis, Universidad Politécnica de Madrid, Spain
Mikhail Korjik, RINP, Minsk, Belarus, Belarus
Hiroyuki Kudo, University of Tsukuba, Japan
Richard Laforest, Washington University, School of Medicine, USA
David S Lalush, North Carolina State University, USA
Ernesto Lamanna, Magna Graecia University Cz & INFN Gruppo Collegato
Cs, Italy
Richard C Lanza, MIT, USA
Carole Lartizien, CREATIS- CNRS UMR5220, France
Frances W. Y. Lau, Stanford University, USA
Patrick JL Le Du, IPNL,IN2P3, France
Richard M Leahy, University of Southern California, USA
James W LeBlanc, GE Research, USA
Roger Lecomte, Université de Sherbrooke, Canada
Paul R Lecoq, CERN, Switzerland
Jae Sung Lee, Department of Nuclear Medicine, Seoul National University
College of Medicine, South Korea
Kisung Lee, Korea University, South Korea
Soo-Jin Lee, Paichai University, Dept. of Electronic Engineering, South Korea
Wonho Lee, Korea University, South Korea
Craig S. Levin, Stanford University, USA
Tom K Lewellen, University of Washington, USA
Robert M Lewitt, Univ of Pennsylvania, Dept of Radiology, USA
Chanqing Li, University of California-Davis, USA
Lihong C Li, City University of New York, USA
Jerome Z Liang, Stony Brook University, USA
Michael Ljungberg, Medical Radiation Physics, Lund University, Sweden
Martin Lodge, Johns Hopkins, USA
Herbert Loehner, KVI, University Groningen, Netherlands
Lawrence R MacDonald, University of Washington, Seattle, USA
Mark T Madsen, University of Iowa, USA
Alexander B Mann, Technische Universität München, Germany
Rihua Mao, Shanghai Institute of Ceramics, Chinese Academy of Sciences, China
Paul K Marsden, King’s College London, England, United Kingdom
Samuel Matej, University of Pennsylvania, USA
Steven R Meikle, University of Sydney, Australia
Scott D Metzler, University of Pennsylvania, USA
Tom Meyer, CERN, Switzerland
Christian J. Michel, Siemens Medical Solutions - Molecular Imaging, USA
Satoshi Mihara, KEK, Japan
Oleg V Missevitch, Institute for Nuclear Problems, Minsk, Belarus
328 Acknowledgement Gregory S Mitchell, UC Davis, USA
Joyeeta Mitra, University of Massachusetts, USA
Robert S Miyaoka, University of Washington, USA
Stephen C Moore, Brigham & Women’s Hospital, USA
Christian Morel, CPPM, Aix-Marseille II University, France
William W. Moses, Lawrence Berkeley National Laboratory, USA
Marek Moszynski, National Centre for Nuclear Reserarch, Poland
Nobutoku Motomura, Toshiba Medical Systems, Japan
Klaus Mueller, Computer Science, Stony Brook University, USA
Hideo Murayama, National Institute of Radiological Sciences, Japan
Raymond F Muzic, Jr., Case Western Reserve University, USA
Deepa Narayanan, National Cancer Institute, NIH, USA
Filippo Nava, Dipartimento di Fisica Università di Modena e Reggio Emilia, Italy
Frederic Noo, University of Utah, Dept of Radiology, USA
Johan LJ Nuyts, KU Leuven, Belgium
Jonathon A Nye, Emory University, USA
Michael K O’Connor, Mayo Clinic, USA
Koichi Ogawa, Graduate School of Engineering, Hosei University, Japan
Yasar Onel, Univ. of Iowa, USA
Arne M Paans, University Medical Center Groningen, Netherlands
Matthew R Palmer, Beth Israel Deaconess Medical Center, USA
Xiaochuan Pan, The University of Chicago, USA
Roberto Pani, Sapienza University of Rome, Italy
Vladimir Y Panin, Siemens Healthcare, USA
Katia Parodi, Heidelberger Ionen Therapie, Heidelberg, Germany
Stephen Peggs, Brookhaven National Laboratory, USA
Todd E Peterson, Vanderbilt University, USA
Uwe K Pietrzyk, Institute of Neuroscience and Medicine - FZ Juelich, Germany
Guillem Pratx, Stanford University, USA
Jinyi Qi, University of California, Davis, USA
Magdalena Rafecas, Instituto de Fisica Corpuscular (IFIC), Universidad de
Valencia - CSIC, Spain
Arman Rahmim, Johns Hopkins University, USA
Francisco Javier Ramírez-Jiménez, Instituto Nacional de Investigaciones
Nucleares, Mexico
Raymond Raylman, Dept of Radiology/West Virginia University, USA
Andrew J Reader, McGill University, Canada
Janet S Reddin, Univ. of Pennsylvania, USA
Guohao Ren, Shanghai Institute of Ceramics, China
Angelo Rivetti, Istituto Nazionale di Fisica Nucleare - INFN - Sezione di Torino,
Italy
Pedro Rodrigues, Philips Research Europe, Netherlands
Emilie Roncali, University of California-Davis, USA
Steven G Ross, GE Healthcare, USA
Gary J Royle, University College London, United Kingdom
Paolo Russo, Universita’ di Napoli Federico II and INFN Napoli, Italy
Hartmut F.-W. Sadrozinski, Santa Cruz Institute for Particle Physics, Univ. of
California Santa Cruz, USA
Denison Souza Santos, Instituto de Radioproteção e Dosimetria, Brazil
Takashi Sasaki, KEK, Japan
Dennis Schaart, Delft University of Technology, Netherlands
Christiaan Schiepers, David Geffen School of Medicine at UCLA, USA
Volkmar Schulz, Philips Research Europe - Aachen / RWTH Aachen University,
Germany
Youngho Seo, University of California, San Francisco, USA
Georgy Shakirin, Philips Research, Netherlands
Lingxiong Shao, Philips Medical Systems, USA
Yiping Shao, The University of Texas M.D. Anderson Cancer Center, USA
Acknowledgement 329
Michael D Silver, TMRU, USA
Arkadiusz Sitek, Brigham and Women’s Hospital and Harvard Medical School, USA
Anne M Smith, Siemens Molecular Imaging, USA
Mark F Smith, University of Maryland School of Medicine, USA
Edward J Soares, Holy Cross College, USA
Sara St. James, Brigham and Women’s Hospital, USA
Maya Stavrianakou, CERN and DAT NCSR DEMOKRITOS, Greece
Charles W Stearns, GE Healthcare, USA
Sven-Erik Strand, Lund University, Sweden, Sweden
Suleman Surti, University of Pennsylvania, USA
Tomasz Szczesniak, National Centre for Nuclear Research, Poland
Katsuyuki Taguchi, Johns Hopkins University, USA
Yuan-Chuan Tai, Washington University in St. Louis, USA
Manobu Tanaka, KEK IPNS, Japan
Richard Taschereau, University of California Los Angeles, USA
Stefaan P Tavernier, Vrije Universiteit Brussel, Belgium
Charles R Tenney, Fresno State University, USA
Kris Thielemans, Algorithms and Software Consulting, United Kingdom
Christopher J Thompson, Montreal Neurological Institute (now retired), Canada
Martin P Tornai, Duke University Medical Center, USA
David W Townsend, Clinical Imaging Research Centre, Singapore, Singapore
Andreia M A Trindade, Philips Research, Netherlands
Benjamin M. W. Tsui, Johns Hopkins University, USA
Timothy G. Turkington, Duke University Medical Center, USA
Stefaan Vandenberghe, Ghent University, Belgium
Arne Vandenbroucke, Stanford University, USA
Paul Vaska, Brookhaven National Laboratory, USA
Jaap Velthuis, Bristol University, United Kingdom
Dimitris Visvikis, U650 INSERM, France
Guobao Wang, University of California, Davis, USA
Jing Wang, UT Southwestern Medical Center, USA
Charles C Watson, Siemens Medical Solutions Molecular Imaging, USA
Irving N Weinberg, Weinberg Medical Physics, USA
Andrew G Weisenberger, Thomas Jefferson National Accelerator Facility, USA
Andy Welch, University of Aberdeen, United Kingdom
Glenn Wells, University of Ottawa Heart Institute, Canada
Kevin Wells, University of Surrey, United Kingdom
Crispin Williams, INFN Bologna, Italy
Mitchell Woodring, Pacific Northwest National Laboratory, USA
Craig L Woody, Brookhaven National Lab, USA
Yibao Wu, Digirad, USA
Claudia-Elisabeth Wulz, Oesterreichische Akademie der Wissenschaften, Austria
Jingyan Xu, Johns Hopkins University, USA
Seiichi Yamamoto, Nagoya University Graduate School of Medicine, Japan
Yongfeng Yang, University of California at Davis, USA
Rutao Yao, State University of New York at Buffalo, USA
Jeffrey T Yap, Dana-Farber Cancer Institute, USA
Zhye Yin, GE Global Research, USA
Hui Yuan, Shanghai Institute of Ceramics, China
Habib Zaidi, Geneva University Hospital, Switzerland
Gengsheng Lawrence Zeng, University of Utah, USA
Bin Zhang, Philips Medical Systems, USA
Nan Zhang, Siemens, USA
Jian Zhou, University of California, Davis, USA
Sibylle Ziegler, Nuklearmedizin Klinikum rechts der Isar der TU München,
Germany
George Zubal, Institute for NeuroDegenerative Disorders, USA
330 Acknowledgement RTSD Steering Committee
Toru Aoki, Shizuoka, University, Japan
Giuseppe Bertuccio, Politechnico di Milano, Italy
Anna Cavallini, University of Bologna, Italy
Henry Chen, Redlen, Canada
Ernesto Dieguez, Universidad Autonoma de Madrid, Spain
Martine Duff, Savannah River Nuclear Solutions, USA
Michael Fiederle, FMF Albert-Ludwigs-Universitaet, Germany
Petro Fochuk, Chernivtsi National University, Ukraine
Laura Fornaro, University of Uruguay, Uruguay
Jan Franc, Charles University, Czech Republic
Larry Franks, Consultant, USA
Zhong He, University of Michigan, USA
Jan Iwanczyk, DxRay, Inc., USA
Kelvin Lynn, Washington State University, USA
Krishna Mandal, University of South Carolina, USA
Douglas McGregor, Kansas State University, USA
Robert McLaren, McLaren Enterprises, USA
Andrzej Mycielski, Academy of Science Warsaw, Poland
Eugenio Perillo, University of Napoli, Italy
Conference Information and Promotion
(CIP) Committee
Rachel Avramidou, CERN, Switzerland
Melanie Bergeron, Université de Sherbrooke, Canada
Christian Bohm, Stockholm University / Physics, Sweden
Uwe Bratzler, CERN & TMU, Switzerland
Johana Chirinos, Michigan Tech University, USA
Audrey Corbeil Therrien, Université de Sherbrooke, Canada
Jerome Crocco, University de Autonoma de Madrid, Spain
Serge Duarte Pinto , CERN, Switzerland
Ralf Engels, Forschungszentrum Jülich GmbH / ZEL, Germany
Christer Fröjdh, Mid Sweden University, Sweden
Chikara Fukunaga, Tokyo Metropolitan University, Japan
Ana Ros Garcia, I3M Universitat Politecnica de Valencia, Spain
Evangelos Gazis, National Technical University of Athens, Greece
Carlos Granja, IEAP CTU Prague, Czech Republic
Ingrid-Maria Gregor, DESY , Germany
Anil Kumar Gourishetty, IIT Roorkee, India
Alberto Del Guerra, University of Pisa, Italy
Erik Heijne, CERN, Switzerland
Christoph Ilgner, CERN und Technische Universität Dortmund , Switzerland
Hiro Iwasaki, KEK, Japan
Merry Keyser, Software & Information Services, Inc., USA
Srilalan Krishnamoorthy, University of Pennsylvania, USA
Susanne Kuehn, Albert-Ludwigs Universität Freiburg / Physikalisches Institut,
Germany
Edward Lampo, UC Berkeley Lab (retired), USA
Patrick Le Du, IN2P3, France
Dariusz Makowski, Technical University of Lodz / Dep. of Microelectronics and
Computer Science, Poland
Dora Merelli, CEA Saclay, France
Raquel Munoz, CIEMAT, Spain
Anastasia Patsouli, CERN , Switzerland
Uwe Pietrzyk, Forschungszentrum Jülich, Germany
Natalia Potylitsina-Kube, DESY, Germany
Acknowledgement 331
Jean-François Pratte, Université de Sherbrooke, Canada
Francisco Ramírez-Jiménez, Instituto Nacional de Investigaciones Nucleares,
Mexico
Anatoly Rozenfeld, University of Wollongong / Centre for Medical Radiation
Physics, Australia
Judy Sanders, , USA
Christina Sanders, George Mason University, USA
Andre Sopczak, “Lancaster University, Dept of physics”, United Kingdom
Giancarlo Sportelli, Biomedical Image Technologies, Spain
Maxim Titov, CEA Saclay, France
Martin Tornai, Duke University, USA
Arne Vandenbroucke, Stanford University / Radiology, USA
Michael Weaver, University of Wollongong, Australia
Bo Yu, Brookhaven National Laboratory, USA
Contact Information
General Chair
Deputy General Chair
Tom Lewellen
[email protected]
Tony Lavietes
[email protected]
NSS Program Chair
NSS Deputy Program Chair
Maxim Titov
[email protected]
Ingrid-Maria Gregor
[email protected]
MIC Program Chair
MIC Deputy Program Chair
Vesna Sossi
[email protected]
Alex Converse
[email protected]
Michael Fiederle
[email protected]
Ralph James
[email protected]
NSS Short Course Chair
MIC Short Course Chair
Steve Derenzo
[email protected]
Jennifer Huber
[email protected]
Workshop Chair
Industrial Program Chair
Ralf Engels
[email protected]
Ronald M. Keyser
[email protected]
Barbara Lewellen
[email protected]
Carolyn Hoffman
[email protected]
Registration Chair
Scholarship Chair
Christina Sanders
[email protected]
Merry Keyser
[email protected]
Treasurer
Adam Alessio
[email protected]
Local Arrangement
Robert Miyaoka
[email protected]
Guest Editor & Webmaster
Bo Yu
[email protected]
336 Contact Information Conference Weekly Overview (1/2)
Sat. Oct 27
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
Lounge
8:30-10:00
SC2 - Nuclear Science for
Nuclear Security
SC3 - Integr.Circuit
Front Ends for Nucl.
Pulse Proc.
07:30-09:30
Registration
10:30-12:00
Nuclear Security
Pulse Proc.
13:30-15:00
Nuclear Security
Pulse Proc.
15:30-17:00
Nuclear Security
Pulse Proc.
15:30-18:30
Registration
Sun. Oct 28
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
Lounge
8:30-10:00
HT-1: Particle Therapy 1
SC4 - Advanced
Photodetectors
SC5 - Molecular Biology
for Imaging Scientists
07:30-09:30
Registration
10:30-12:00
SC4 - Advanced
Photodetectors
13:30-15:00
14:00-16-00
SC4 - Advanced
Photodetectors
15:30-17:00
16:30-18:30
SC4 - Advanced
Photodetectors
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
8:30-10:00
NP1: NSS Plenary
Session 1
R01: CdZnTe1
SC6: Medical Image
Reconstruction
SC7: Phys. and Design of
Det. for SPECT and PET
10:30-12:00
NP2: NSS Plenary
Session 2
R02: Defects
SC6: Medical Image
Reconstruction
R03: TlBr
13:30-15:00
SC6: Medical Image
Reconstruction
13:30-15:00
Homeland Security I:
Detection
Circuits I
15:30-17-00
SC6: Medical Image
Reconstruction
15:30-17-00
Mon. Oct 29 Grand Ballroom Center Grand Ballroom South AB
15:30-18:30
Registration
Exhibit Hall North
Ballroom
Grand Ballroom North
NSS Luncheon
12:00-14:00
14:00-16:00
LC1: Introduction
16:30-18:30
LC2: ILC/CLIC Accelerator and Detector
Concepts
Tue. Oct. 30
N2: Synchrotron
Radiation and FEL
Instrumentation
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
8:00-10:00
08:30-10:00
JMR: MIC/RTSD Joint
Session
Concepts & Detector
Spin-Offs
N5: Neutron Detectors
and Instrumentation I
Circuits II
N7: Simulation
10:30-12:30
10:30-12:00
R05: Applications 1
Spin-offs and ILC/CLIC
Accelerator Instr.
Homeland Security II:
Imaging
Circuits III
Scintillation Detectors I
Grand Ballroom Center Grand Ballroom South AB
07:30-18:30
Registration
N1: NSS Poster Session I
R04: RTSD Poster 1
Exhibit Hall North
Exhibit Hall South
Monorail A+B
14:00-16:00
JNM: NSS/MIC Joint
Session
16:30-18:30
JNMR: NSS/MIC/RTSD
Triple Joint Session
LC6: ILC/CLIC Accelerator Tech.for Ind. Appl. II
LC7: Forum Discussion
about LC perspectives
Homeland Security III:
Active Interrogation
N12: Astrophysics and
Space Instrumentation I
Out-of-Site
12:20-14:30
RTSD Luncheon
NSS Refresher Course 1
12:45-13:45
N13: Gaseous Detectors I
: Performance Reports
14:30-16:00
R04: RTSD Poster 2
Lounge
07:30-18:30
Registration
Exhibitor Technical
Sessions
12:00-19:00
Industrial
Exhibition
N14: NSS Poster Session II
Exhibitor Receptiom
19:00-21:00
Wed. Oct 31 Grand Ballroom Center
Magic Kingdom 1
Magic Kingdom 2
Circuits IV
7:00-8:00
MIC Refresher Course 1
8:00-10:00
08:15-10:00
M01: MIC Plenary 1
Homeland Security IV:
Active Interrogation and
Detector Arrays
10:30-12:30
M02: MIC Awards and
Plenary 2
N18: Semiconductor
Tracking and Spectroscopy Detectors I
Magic Kingdom 3
Magic Kingdom 4
Exhibit Hall South
N17: High Energy Physics Instrumentation I
N19: Data Acquisition
and Analysis Systems I
Instrumentation I
12:45-13:45
Ballroom
R08: CdZnTe 2
Exhibitor Technical
Sessions
Exhibitor Technical
Sessions
09:00-18:00
Industrial
Exhibition
14:00-16:00
N21: Neutron Detectors
and Instrumentation II
N22: Photodetectors
and Radiation Imaging
Detectors I
N23: Data Acquisition
and Analysis Systems II
N24: High Energy Physics Instrumentation II
R09: Applications 2
16:30-18:30
M04: Image Reconstruction Methods 1
Effects I
Scintillation Detectors II
N27: Experimental Reactor Instrumentation and
Measurement
N28: Experimental Software Developments
R10: CdTe
Conference Reception (on the lawn)
Monorail A+B
Sleeping Beauty
Lounge
R07: Semiconductor
Films
M03: Emission Tomography Instrumentation
(PET,SPECT) 1
19:00-21:00
Lounge
07:30-18:30
Registration
WIE Session
Conference Weekly Overview (2/2)
Thu. Nov 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
N31: Gaseous Detectors
II : New techniques
N32: Trigger and Frontend Systems I
08:30-10:00
R11: Alternative Semiconductor Materials
N35: High Energy Physics Instrumentation III
R12: Alternative Semiconductor Materials &
Neutron Detectors
7:00-8:00
8:00-10:00
08:15-10:00
M05: High Resolution
& Preclinical Imaging
Instrumentation, Techniques and Systems
08:15-10:00
M06: Imaging in Radiotherapy
N29: Semiconductor
Tracking and Spectroscopy Detectors II
Scintillation Detectors III
10:30-12:30
M07: Image Processing
and Parametric Imaging
M08: Simulation and
Modeling of Medical
Imaging Systems
Effects II
N34: Photodetectors
Detectors II
12:45-13:45
14:00-16:00
16:30-18:30
Exhibit Hall North
Ballroom
Magic Kingdom 1
M11: Data Acquisition
and Signal Processing /
Multi-Modality Systems
OpenPET Users Group
Meeting
N36: Astrophysics and
Space Instrumentation II
Bio-Medical Research
N38: Gaseous Detectors
III : LHC upgrades and
ILC R&D
Instrumentation II
M12: Emission Tomography Instrumentation
(PET,SPECT) 2
Solid-State Detectors I
Scintillation Detectors IV
N42: Accelerator Technologies and Beam Line
Instrumentation
N43: Computing Challenges
Magic Kingdom 1
Magic Kingdom 2
Magic Kingdom 3
Magic Kingdom 4
Solid-State Detectors II
NR01: NSS/RTSD Joint
Session
N45: Photodetectors
Detectors III
N46: HEP Software
M09: POSTER: Data
Acquisition and Signal
Processing / Image reconstruction methods 1
M10: POSTER: Simulation and Modeling of
Medical Imaging Systems
/ Multi-Modality Systems
Exhibit Hall South
8:00-10:00
08:15-10:00
M13: New Detector
Materials/Technologies
for Medical Imaging
08:15-10:00
and Quantitative Imaging Techniques 1
NP3: NSS Plenary
Session 3
14:00-16:00
16:30-18:30
M19: Image Reconstruction Methods 2
Sat. Nov 3
Grand Ballroom Center
7:00-8:00
8:15-10:00
10:30-12:30
Sleeping Beauty
Lounge
09:00-18:00
Industrial
Exhibition
12:40-14:00
STIR / SimSET /
ASIM
07:30-17:00
Registration
Exhibitor Technical
Sessions
R13: CdZnTe 3
R14: RTSD Award +
CZT Detectors
GOLD
7:00-8:00
10:30-12:30
Monorail A+B
Exhibitor Technical
Sessions
19:00-21:00
Fri. Nov 2
Mark Twain
and Quantitative Imaging Techniques 2
M20: Other Medical
Imaging Technologies (CT, MR, Optical,
Ultrasound, etc.)
Exhibit Hall North
R15: Pixeldetectors
M16: POSTER: Emission Tomography
Instrumentation 1 / New
Detector Materials and
Technologies for Medical
Imaging
R16: Contacts and
Defects
M17: POSTER: Image
Reconstruction Methods
2 / Intra-Operative
Probes and Portable
Imaging Systems
Tomography Instrumentation 2/ Other Medical
Imaging Technologies
He-1: Perspectives on
He-3 Replacments for
Neutron Detection I
Lounge
07:30-12:00
Registration
M15: POSTER: Data
Corrections and
Quantitative Imaging
Techniques
He-2: Perspectives on
He-3 Replacments for
Neutron Detection II
Exhibit Hall South
Lounge
M21: POSTER:
High Resolution &
Pre-Clinical Imaging
Instrumentation
M22: POSTER: Imaging
in Radiotherapy / Image
Processing and Parametric Imaging
07:30-09:00
Registration
2013 NSS/MIC/RTSD
Dear Colleagues,
It will be our great pleasure to welcome you to Seoul and to the
2013 IEEE Nuclear Science Symposium and Medical Imaging
Conference, together with the 20th International Workshop on
Room-Temperature Semiconductor X-ray and gamma-ray Detectors.
The 2013 Conference will be held, for the first time in the AsianPacific region, in the beautiful and historical city of Seoul, Korea,
from October 27th - November 2nd, 2013 at the spacious and
modern COEX Convention Center.
The conference center is located in the south part of the city, with easy
access to the airport and within walking distance of a broad range
of hotels. It is conveniently linked to the city center, the historical
museums, and the ancient palaces either by walking or by public
transport.
Our theme for 2013 is “Beyond Imagination of Future Science.” The
Organizing Committee is planning a high scientific level meeting that
will include both oral and poster presentations and refresher courses
on important topics. A commercial exhibition that will showcase
state-of-the-art products and services from a wide range of companies
will be held in parallel to the scientific programs. The exhibit space
will be specifically designed to allow both the exhibitors and attendees
ample space for discussions and exploration of common interests.
This meeting has always been a great opportunity to meet with
old friends, make new ones, exchange ideas, and share knowledge
and experience in the nuclear science, medical imaging, and roomtemperature semiconductor detector fields. This meeting anticipates
a greatly expanded Asian-Pacific attendance that will make the 2013
IEEE NSS/MIC conference exceptionally special, meaningful, and
memorable.
The City of Seoul not only provides an excellent venue for our
professional meeting, but is also an ideal location for attendees to bring
their families. A variety of interesting tours will be offered so attendees
and their companions can fully experience Seoul and the surrounding
region. City Tour buses are the most convenient and comfortable way
to explore the city, as most major sights and attractions are presented
on a single tour. Nestled around the Han River is the Korean capital
Seoul, a city of old and new. With thousands of years of history, it has
well preserved royal palaces, historical relics, and cultural treasures,
yet state-of-the-art facilities and infrastructure as well. Seoul has been
the capital of Korea for about 600 years and has developed into a
bustling metropolis, acting as the hub for political, economic, social,
and cultural matters.
On behalf of the organizing committee, I encourage you to make
plans now to attend the 60th exciting NSS/MIC conference of
the IEEE Nuclear and Plasma Sciences Society. I look forward to
welcoming you to Seoul in October 2013.
Hee-Joung Kim
2013 NSS/MIC/RTSD General Chair
USA
Return Address:
Thomas K. Lewellen
University of Washington
Portgage Bay Building, RM 222
PO Box 357987
Seattle, WA 98195
The Institute of Electrical and Electronics Engineers

Program - NSS/MIC

Transcription

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