SUChE 2015--program book-22 - The 8th Sino

Transcription

SUChE
SHANGHAI 2015
Http:// suce.ecust.edu.cn
The 8th Sino-US Joint Conference
of Chemical Engineering
October 12-16 • 2015 • SHANGHAI • CHINA
Program Book
NEW ERA of
CHEMICAL ENGINEERING
EAST CHINA
UNIVERSITY
of SCIENCE AND
TECHNOLOGY
Program Book
Editors of the Program book:
Prof. Yi-Fan Han
Prof. Donghui Long
CONTENTS
The 8th Sino-US Joint Conference of Chemical Engineering Program
02
Chairmen’s Message
05
Conference Co-Chairs
07
About the conference
08
About ECUST
09
Registration & Meals
10
Information about the Conference
12
Conference at a Glance
13
Campus Map
14
Plenary Lectures and Discussions
23
Space for Symposium
24
List of Symposium
25
Parallel Symposium Schedule Table
27
Parallel Symposium Descriptions
135
Poster Sessions
Page 1
Chairmen’s
Message
Welcome to the 8th Sino-US Joint Conference of Chemical Engineering
ON behalf of the organizing committee, we are pleased to welcome you to the 8th Sino-US Joint
Conference of Chemical Engineering (SUChE2015). SUChE2015 was hosted by East China University of
Science and Technology during October 12–16, 2015 in Shanghai, China. The conference was also
sponsored by the following organizations: The Chemical Industry and Engineering Society of China,
American Institute of Chemical Engineers, Chinese Academy of sciences, Chinese Academy of
Engineering, and National Natural Science Foundation of China.
There are undeniable challenges in areas such as energy, resources and the environment. The Sino-US
Joint Chemical Engineering Conference will act as a platform for scientists, engineers, and technologists
from both China and the United States to communicate the latest developments and share their
knowledge in the field of chemical engineering. The theme of the 8th conference is “New Era of
Chemical Engineering”, emphasizing not only the role of chemical engineers in the development of
clean and sustainable processes, but also exploring the frontiers for developing fundamentals needed to
tackle these challenges. The conference will foster new and substantial collaborations between
scientists and engineers from both academic institutions and industrial companies.
The Sino-US Joint Conference of Chemical Engineering started in 1982, and since then they have been
held in Beijing. This is the first time the conference is being held in Shanghai. With all the exciting
developments happening, this event promises to be a sensational gathering for all participants.
The Conference Organizing Committee is grateful to all those who have contributed to its organization,
its scientific program and the sessions. It also would like to thank ExxonMobil, National Institute of Low
Carbon and Clean Energy (NICE), National Science Foundation of USA, UOP Co. for their financial
support. We would also like to extend a warm welcome to all our colleagues in the industry who share
our interest in developing and improving Academic-Industry partnership.
We hope that you will participate in the stimulating scientific sessions as well as enjoying the special,
unique charm of Shanghai.
On behalf of the Conference
Dr. Xuhong Qian
Dr. Norman Li
East China University of Science and
NL Chemical Technology, Inc., The United
Technology, Shanghai, China
States of America
Member of Chinese Academy of Engineering
Member of US National Academy of
Engineering
Page 3
New Era of
Chemical Engineering
Organizer
Sponsors
Special Sponsors
Page 4
New Era of
Conference Co-Chairs
Prof. Kechang Xie
Prof. Jinghai Li
Dr. Xianghong Cao
Prof. Xuhong Qian
Dr. Norman Li
Vice President of
Chinese Academy of
Engineering, Member
of Chinese Academy of
Engineering
Vice President of
Chinese Academy of
Sciences, Member of
Chinese Academy of
Sciences
Sinopec Group, China;
Member of Chinese
Academy of
Engineering
Prof. of East China
University of Science
and Technology, Member
of Chinese Academy of
Engineering
President of NL
Chemical Technology,
Inc., USA; Member,
US National Academy
of Engineering
Conference Secretaries
Prof. Shan-Tung Tu, Prof. Zhong Xin (Deputy)
Local Organizing Conference
Prof. Yi-Fan Han (China), Dr. Teh Chung Ho (US)
Scientific Advisory Committee
From China
(Listed alphabetically)
Mr. Xianghong Cao (曹湘洪), Member of Chinese Academy of Engineering, China Petrochemical Corporation
Prof. Bingzhen Chen (陈丙珍), Member of Chinese Academy of Engineering, Tsinghua University
Prof. Jiayong Chen (陈家镛), Member of Chinese Academy of Sciences, Institute of Process Engineering, CAS
Prof. Junwu Chen (陈俊武), Member of Chinese Academy of Sciences, Luoyang Petrochemical Corp., China
Petrochemical Corporation
Prof. XueDuan (段雪), Member of Chinese Academy of Sciences, Beijing University of Chemical Technology
Prof. WeiyangFei (费维扬), Member of Chinese Academy of Sciences, Tsinghua University
Dr. Mingyuan He (何鸣元), Member of Chinese Academy of Sciences, Research Institute of Petroleum
Processing, China Petrochemical Corporation
Prof. Ying Hu (胡英), Member of Chinese Academy of Sciences, ECUST
Prof. Hongzhong Li (李洪钟), Member of Chinese Academy of Sciences, Institute of Process Engineering, CAS
Prof. He Tian (田禾) Member of Chinese Academy of Sciences, ECUST
Prof. Jinghai Li (李静海), Member of Chinese Academy of Sciences, Institute of Process Engineering, CAS
Prof. Enze Min (闵恩泽), Member of Chinese Academy of Sciences, Research Institute of Petroleum
Processing, China Petrochemical Corporation
Page 5
Scientific
Advisory Committee
Prof. Pingkai Ouyang (欧阳平凯), Member of Chinese Academy of Engineering, Nanjing University of Technology
Prof. Jingkang Wang (王静康), Member of Chinese Academy of Engineering, Tianjin University
Prof. KechangXie (谢克昌), Member of Chinese Academy of Engineering, Taiyuan University of Technology
Prof. Nanping Xu (徐南平), Member of Chinese Academy of Engineering, Nanjing University of Technology
Prof. Guocong Yu (余国琮), Member of Chinese Academy of Sciences, Tianjin University
Prof. Qingtang Yuan (袁晴棠), Member of Chinese Academy of Engineering, China Petrochemical Corporation
Prof. Xuhong Qian (钱旭红), Member of Chinese Academy of Engineering, ECUST
Prof. Quan Yuan (袁权), Member of Chinese Academy of Sciences, Dalian Institute of Chemical Physics, CAS
Prof. Weikang Yuan (袁渭康), Member of Chinese Academy of Engineering, ECUST
Prof. Yi Zhang (张懿), Member of Chinese Academy of Engineering, Institute of Process Engineering, CAS
Prof. Tao Zhang (张涛), Member of Chinese Academy of Sciences, Dalian Institute of Chemical Physics, CAS
Prof. Wei Huang (黄维), Member of Chinese Academy of Sciences, Nanjing University of Technology
From US
Dr. Monty Alger, Member of National Academy of Engineering of USA, Myriant Corporation
Prof. Mark A. Barteau, Member of National Academy of Engineering of USA, University of Michigan
Prof. Dibakar Bhattacharyya, University of Kentucky
Dr. Maria K. Burka, National Science Foundation
Prof. Chau-Chyun Chen, Member of National Academy of Engineering of USA, Texas Tech. University
Prof. Steven M. Cramer, Rensselaer Polytechnic Institute
Prof. L. S. Fan, Member of National Academy of Engineering of USA, The Ohio State University
Dr. Teh C. Ho, Hydrocarbon Conversion Technologies
Prof. W. S. Winston Ho, Member of National Academy of Engineering of USA, The Ohio State University
Prof. William J. Koros, Member of National Academy of Engineering of USA, Georgia Institute of Technology
Prof. James L. Lee, The Ohio State University
Dr. Norman N. Li, Member of National Academy of Engineering of USA, NL Chemical Technology Inc.
Prof. G. Glenn Lipscomb, University of Toledo
Prof. Kamalesh K. Sirkar, New Jersey Institute of Technology
Dr. James A. Trainham, Member of National Academy of Engineering of USA, RTI International
Prof. James Wei, Member of National Academy of Engineering of USA, Princeton University
Prof. Ralph T. Yang, Member of National Academy of Engineering of USA, University of Michigan
Dr. Scott Y. Zhang, Honeywell Inc.
Prof. Andrew L. Zydney, Pennsylvania State University
Page 6
About the
Conference
About the conference
The Sino-US Joint Chemical Engineering Conference will act as a platform for
scientists, engineers, and technologists from both China and the United States
to communicate the latest developments and share their knowledge in the
field of chemical engineering.
The theme of the 8th conference is “New Era of Chemical Engineering”.
The conference will foster new and substantial collaborations between
scientists and engineers from both academic institutions and industrial
companies.
List of Symposia
 S1—Advanced Technology for Air Separation and Purification
 S2—Bioengineering and Biotechnology
 S3—Catalysis and Reaction Engineering
 S4—Energy
Energy
 S5—Food and Pharmaceutical Technologies
 S6—Green Technology
 S7—Management Science for Research and Development
---How to make R&D effective and efficient
 S8—Materials and Nano Technology
 S9—Membrane Technology for Water Purification
 S10—Particle and Fluidization Technology
 S11—Petrochemicals and Fine Chemicals
 S12—Process Development and Optimization
 S13—Thermodynamics and Transport Phenomena
 S14—Separation Technology
 S15— Forum of Chemical Engineering Department Deans and Chairs
Page 7
About ECUST
About ECUST
East China University of Science and Technology (ECUST), originally named
East China Institute of Chemical Technology, was founded in 1952.
ECUST is a key research university in China
featuring Chemical Sciences & Engineering.
ECUST rank among the top 500 universities in
the world, according to the Ranking List of
Universities by ARWU, THE and QS.
East China University of Science and
Technology has a top quality teaching and
R&D staff represented by nationally
renowned educators as well as very
competitive scientific research teams based
in many state-level key laboratories and
engineering and technological research
centers. In December 2013, the Chemical
Engineering and Technology major was
accredited by ABET (6+3), which is the first
ABET accreditation in China.
ECUST is comprised of more than 1.7 million
square meters on 3 campuses. There are more
than 16,300 full time undergraduates, 8,500
graduate students studying at ECUST. The
number of faculty and staff members has
reached 3,700 among whom there are about
1,000 professors and associate professors.
Page 8
Registration
& Meals
Registration Site
All participants are kindly asked to confirm and pay for their registration fee and pick
up their conference materials at the registration desk.
The registration desk will be located:


The lobby of Yifu Building at 09:00-20:00, Oct. 12
The lobby of Yifu Building at 08:00-18:00, Oct. 13-15
M104
M105
Registration Desk
Yifu Building
M103
Conference meals
All registered participants will receive meal tickets lunch and
dinner for the three and half days (Oct. 13th to 16th ) during
the conference. Each ticket for the conference meal is valid
only for the lunch or the dinner as indicated on the ticket. The
meal tickets will not be refundable.
The place for the
conference meals is in
Youyi Restaurant and for
banquet is in Pullman
Hotel.
Page 9
Information About
the Conference
Shuttle Service
Shuttles will provide service from official hotels to and from the ECUST. Hotels include the Pullman
Shanghai South and Grand Skylight Hotel (GSH).
Date
Leaving at Hotel (PSS)
Leaving at Hotel (GSH)
Leaving at ECUST
Oct.
12
7:40, 8:40, 9:40, 10:10,
11:40, 12:40, 13:40, 14:40,
15:40, 16:40, 17:30
7:40, 8:40, 9:40, 10:10,
11:40, 12:40, 13:40,
14:40, 15:40, 16:40,
17:30
9:00, 10:00, 11:00, 12:00, 13:00,
14:00, 15:00, 16:00, 17:00, 20:00
Oct.
13
7:40, 8:40, 9:40, 10:10,
11:40, 12:40, 13:40, 14:40,
15:40, 16:40, 21:00(for
GSH and ECUST)
7:40, 8:40, 9:40, 10:10,
11:40, 12:40, 13:40,
14:40, 15:40, 16:40
9:00, 10:00, 11:00, 12:00, 13:00,
14:00, 15:00, 16:00,
17:30(for Pullman Shanghai South
only)
Oct .1
4
7:40, 8:40, 9:40, 10:10,
11:40, 12:40, 13:40, 14:40,
15:40, 16:40, 17:30
7:40, 8:40, 9:40, 10:10,
11:40, 12:40, 13:40,
14:40, 15:40, 16:40,
17:30
9:00, 10:00, 11:00, 12:00, 13:00,
14:00, 15:00, 16:00, 17:00,
18:30(for Huangpu River Night
Cruise only)
Oct.
15
7:40, 8:40, 9:40, 10:10,
11:40, 12:40, 13:40, 14:40,
15:40, 16:40
7:40, 8:40, 9:40, 10:10,
11:40, 12:40, 13:40,
14:40, 15:40, 16:40
9:00, 10:00, 11:00, 12:00, 13:00,
14:00, 15:00, 16:00, 17:00, 19:00
Oct .1
6
7:40, 8:40, 9:40, 10:10,
11:40, 12:40,
7:40, 8:40, 9:40, 10:10,
11:40, 12:40
9:00, 10:00, 11:00, 12:00, 13:00
(for Jewish Refugees
Museum visit and hotels),
15:30 (from museum to hotels and
Pudong Int’l Airport)
Please contact Dr. Jie Wang ([email protected] or 13917682730) if you need any assistance in transportation!
WiFi Network
You may access free WiFi network in the
meeting space area.
SSID: SUChE2015
Encryption Key: ecust2015
Page 10
About Tour
上海黃浦江夜遊 Shanghai Huangpu River Night Cruise
Wednesday, Oct.14 2015, 18:30-21:00
The Huangpu River is the mother river
of Shanghai. Nanpu Bridge, Yangpu
Bridge and Oriental Pearl TV Tower
compose of a huge picture scroll. The
Bund is the cultural section of Shanghai
that best represents the blending of
ancient and modern influences. This
renowned waterfront district is the
city's most famous landmark. Local
people honor the Huangpu River as
Mother River, and as you view the lights
and spectacle from the deck of your
evening cruise, you will understand why.
上海犹太难民纪念馆 Shanghai Jewish Refugees Museum
Friday, Oct.16 2015, 13:00-16:00
Located on Changyang Road in the
Hongkou District, the Shanghai Jewish
Refugees Museum was built in memory
of the time during the Second World
War when Jewish refugees sought
sanctuary from massacre. It is housed in
the former Ohel Moshe Synagogue
where the Jewish refugees gathered for
religious activities. The museum holds
many scrolls and other cultural relics.
Page 11
Conference
at a Glance
Date
Monday
Oct.12, 2015
Tuesday
Oct.13, 2015
Wednesday
Oct.14, 2015
Thursday
Oct.15 2015
Friday
Oct.16 2015
Page 12
Time
Events
9:00 - 18:00
Conference Registration (Yifu Building)
18:00-20:00
Welcome reception (Youyi Restaurant)
8:15-8:45
Opening ceremony
8:45-12:10
Plenary lectures
12:10-13:30
Lunch (Youyi Restaurant)
13:30-17:00
Parallel symposiums
18:00-21:00
Banquet (Pullman Hotel)
8:30-12:00
Parallel symposiums
12:00-13:30
13:30-17:00
Parallel symposiums
17:00-18:30
Dinner (Youyi Restaurant)
18:30-21:00
Huangpu River Night Cruise
8:30-12:00
Parallel symposiums, Poster
12:00-13:30
13:30-17:00
Parallel symposiums, Poster
17:00-19:00
Dinner (Youyi Restaurant)
8:30-10:00
Discussion on Challenges and Opportunities of Chemical
Industry
10:15- 11:45
Discussions on Future Education of
11:45-12:15
Conference Closing Ceremony including the Best Poster
Paper Awards
12:15-13:00
13:00-16:00
A Visit to the Shanghai Jewish Refugees Museum
Campus Map
Heping Building
No. 16 Building
Main Gate
East Gate
Heping Building
Youyi Restaurant
Yifu Building
Page 13
Plenary Lectures and Discussions
Plenary lectures and Plenary discussion will be held at the Hall of Yifu Building (M105).
Plenary lecture
8:459:30
Tuesday
Oct.13, 2015
Plenary lecture 1: Progress, Challenge and Perspective of Chemical
Engineering Education in China
Prof. Xuhong Qian (ECUST, Member of Chinese Academy of Engineering)
9:3010:15
Plenary lecture 2: Efficiency, Integration and Molecular Management –
The Role of Innovation
Dave Martindale (Vice President, UOP LLC)
10:4011:25
Plenary lecture 3: China's Oil Refining and Petrochemical Industry:
Looking Forward to 2030
11:2512:10
Plenary lecture 4: Development of Technologies for Clean and Low
Carbon Energy
Xianghong Cao (Sinopec, Member of Chinese Academy of Sciences)
Chang Wei (President, National Institute of Clean and Low Carbon Energy)
Plenary discussion
8:3010:00
Friday
Oct.16, 2015
1. Discussion on Challenges and Opportunities of Chemical Industry
Dr. Dingyi Hong, Dr. Xiaodong Hu, Mr. Guanglian Pang
Mr. Dave Martindale, Dr. Bing Zhang, Dr. Yi Jiang
10:2011:50
2. Discussions on Future Education of Chemical Engineering
Speakers：Prof. Guohua Chen, Prof. Daming Wang, Prof. Shan-Tung Tu
Prof. Arvind Varma, Prof. Dan Luss, Prof. James Wei
Page 14
Plenary lecture
speakers
Xuhong Qian
Xuhong QIAN Ph.D., FRSC
Professor, Bioorg. Chem. Engi. (Pesticide & Dyes)
Member, Chinese Academy of Engineering
Former President of ECUST
He was born in Baoying county, Jiangsu province in 1962.
1/2014-, Member, Advisory Editorial Board, J. Agric. Food
Chem., USA; 12/2012-, Honorary Doctor of Science,
Queen’s University , Belfast, UK; 6/2012-, Editor-in-Chief,
Chinese Chemical Letters; 12/2011-, Member, Chinese
Academy of Engineering; 7/2011-, Honorary Professor, Bath
University , UK.
3/2009-, Fellow, The Royal Society of Chemistry, UK; 5/2008-7/2014, Member, Advisory Commission for
Chemistry, National Science Foundation of China; 5/2008-10/2014, Ambassador Scientist, Alexander von
Humboldt Foundation, Germany; 3/2007-12/2008, President, Asian Pacific Confederation of Chemical
Engineering; 2007-, Vice President, Chemical Industry and Engineering Society of China; 7/2004-3/2015,
President, East China University of Science and Technology (ECUST), Shanghai; 2003-2014, Scientist-in-Chief,
National Basic Research Key Project (973), The Ministry of Science and Technology; 9/2000-6/2004.
CheungKong Chair Professor, in Dalian University of Technology. 2000. Research Grant for Outstanding
Young Scientist, National Natural Science Foundation of China; 4/1996-10/2000. Vice President, ECUST,
Shanghai; 1999. Distinguished 10 Persons in Science and Technology of Shanghai; 9/1995-3/1996. Assistant
President, ECUST, Shanghai. 8/1994-9/2000. Professor; 8/1992-7/1994. Associate Professor; 8/1988-8/1992.
Lecturer, East China University of Science and Technology (ECUST), Shanghai; 9/1990-1/1992. Alexander von
Humboldt Postdoctoral Fellow, Wurzburg University, West Germany; 8/1989-8/1990. Research Associate,
Lamar University, Texas, USA; 6/1988. Ph. D.; 4/1985. Master.; 7/1982. Bachelor, East China Institute of
Chemical Technology, Shanghai (Presently, East China University of Science and Technology).
Progress, Challenge and Perspective of Chemical Engineering Education in China
Xuhong Qian
East China University of Science and Technology
The history of Chinese chemical engineering education (CEE) is reviewed; in particular, we analyzed the
reason why the naissance of modern engineering science didn’t occur even though the outstanding chemical
production practice was achieved in ancient China. As followed, the recent progresses of CEE in China are
outlined including the development of East China University of Science and Technology, and we show, from
several aspects, that the Chinese chemical engineering is catching up with the World including United States.
Despite of this great success, we are facing new global and domestic challenges, of which some are from the
development bottleneck of modern chemical engineering discipline and some from the Chinese national
conditions. These challengers together with the opportunities are discussed. Finally, we outlook the CCE in
new era, and hope make our own contribution to the World. We suggest that multi-scale total engineering
education system, composed of self-contained knowledge hierarchy ranging from quantum chemistry to
Newton dynamics, continuous fluid dynamics and finally to chemical process design, is necessitated in order
to bring up qualified chemical engineers for the upcoming era.
Page 15
Plenary lecture
speakers
Xianghong Cao
Cao Xianghong, male, was born in June 1945, in Jiangyin, Jiangsu
Province. He worked for Sinopec Beijing Yanshan company more than 30
years, engaged in technical development, production and technical
management. Mr. Cao is a professor-level senior engineer and an expert
in petrochemical engineering field. He is now a senior member at
Sinopec Science and Technology Committee, vice president of Chinese
Petroleum Society, vice president of China Energy Research Society,
chairman of National Petroleum Products and Lubricants Standardization
Technical Committee, and committee member of the Expert Committee
of National Energy Administration.
After 2000, he served successively as general manager, director and
senior vice president, and chief engineer in Sinopec Corp., in charge of
technology development and informatization. Since the year of 2008 he
left the leadership position but remained as a senior advisor of Sinopec.
He has served as president of the chemical industry and engineering
society of china, director of Division of Chemical, Metallurgical and
Materials Engineering in Chinese Academy of Engineering
Mr. Cao was elected as member of Chinese Academy of Engineering in 1999 and elected as foreign
member of the National Academy of Engineering, USA, in February 2009. He is a member of the 11th and
12th CPPCC National Committee.
China's Oil Refining and Petrochemical Industry:
Looking Forward to 2030
Cao Xiang Hong
Sinopec, 22 Chaoyangmen North Street,Chaoyang District, Beijing, 100728
The report summarizes the current situation of China's oil refining and petrochemical industry, China
has become the major country of oil refining and petrochemical industry, but big and not strong; analysis the
challenges that China's oil refining and petrochemical industry will face by 2030, pointed out that diesel,
gasoline and oil consumption will have experience peak levels, petrochemical product consumption growth
will also slow down, the lack of market competitiveness of raw material factors, resource import
dependence continues to rise, challenging task in environment management and so on. For 2030, China's oil
refining and petrochemical industry should strengthen industrial foundation； second， develop high-end
products；third, adhere to the green low-carbon strategy；fourth，Encourage Science and Technological
Innovation；fifth，Integration of information technology；sixth， Strengthen international cooperation，
to achieve the industry target from big to strong.
Page 16
Plenary lecture
speakers
Dave Martindale
Vice President and General Manager Engineering,
Services and Equipment UOP, A Honeywell Company
Dave Martindale is Vice President and General Manager of UOP LLC’s
Engineering, Services and Equipment group. Dave is responsible for over
1500 technical personnel in 20 offices around the world. His group
provides engineering services, equipment design and project
management, commissioning support and technical services to UOP’s
global customer base.
Dave began his career with UOP in 1979. Through the years, he has held
positions in R&D and Sales and management positions in Business,
Engineering, and R&D. In 2010, Dave was named the Sr. Business Leader
for PT&E Hydroprocessing. In 2012, Dave became the Sr. Director of R&D
Development for all UOP technologies. He was named the Vice President
of Engineering, Services and Equipment in early 2015.
Dave has a Bachelor of Science degree in Chemical Engineering and an
MBA from the Loyola University of Chicago.
Efficiency, Integration and Molecular Management
-- The Role of Innovation
Dave Martindale, Vice President (Speaker) and Frank Xin Zhu, Corporate Fellow
UOP LLC, A Honeywell Company
The demand in emerging regions for refinery and petrochemicals products such as
higher quality transport fuels, fabrics and plastics continues to grow rapidly. The main
challenges to meet this increased demand are value creation and energy utilization.
These can be enabled by innovations in molecular management, refinery and
petrochemical integration and energy efficiency. This presentation will discuss these
innovations including some recently commercialized examples.
Page 17
Plenary lecture
speakers
Chang Wei
President, National Institute of Clean and Low Carbon Energy
Dr. Chang Wei is President and CEO of the National Institute of Cleanand-low Carbon Energy (NICE). Prior to his current role, Dr. Wei was an
executive at General Electric company where he worked for almost 20
years, most recently he was the General Manager responsible for the
global water R&D at GE Global Research in the US. NICE is managed by
the Shenhua Group, one of the global fortune 500 companies. At NICE,
Dr. Wei leads about 300 scientists conducting advanced research in
energy areas including coal conversion and processes; coal-based
functional materials; water technologies and processes; distributed
power and hydrogen energies. Dr. Wei holds a PhD degree in Chemistry
with 27 issued US patents and 30+ publications in referred journals.
Development of Technologies for Clean and Low Carbon Energy
Dr. Chang Wei
President, National Institute of Clean and Low Carbon Energy, Beijing, China
Formerly, General Manager, GE Global Research in USA and GE Greater China
One of the major energy sources is coal and the clean coal applications are critical to the sustainable
growth of China. This presentation outlines key technologies in clean coal field including coal refining,
coal conversion, ultra-low emission combustion and carbon capture and storage technologies. In
addition, this talk will discuss hydrogen energy and its applications, such as hydrogen production,
hydrogen transport and storage and downstream hydrogen applications. Different sources of
hydrogen, venues of transporting hydrogen, and types of hydrogen applications as well as related
economics will also be presented. The major challenges that the energy industry is facing and the
potential pathways going forward will be highlighted and discussed
Page 18
Plenary discussion
speakers
Dr. Dingyi Hong
Prof. Dr. Hong Dingyi, born in 1946, is the Standing Board Member and Senior
Counselor of The Chemical Industry and Engineering Society of China (CIESC).
Hong graduated from department of chemical engineering, Beijing Institute of
Technology in 1969 and got doctor degree of chemistry from University of
Hamburg in 1991.His former positions were: President, Research Institution,
Sinopec Yanshan CompanyVice President, PetroChina Daqing Petrochemical
Company Director, Science and Technologies Department, Sinopec Group
Director, Technology Advisory Committee, Sinopec Group Secretary General,
CIESC .Hong is also the Member of Review Committee, China Engineering
Education Accreditation Association; Vice Director of Petroleum Processing,
Chinese Petroleum Society; Deputy Editor-in-chief of Chemical Industry and
Engineering Progress; Editor-in-chief of China Synthetic Resin and Plastics and
Petroleum Knowledge.
Dr. X.D. Hu currently is the China Managing Director of Albemarle Corporation, a
listed company in New York Stock Exchange. Dr. Hu obtained his BS from South
China University of Technology, MS in Chemical Engineering from State
University of New York at Buffalo, and his Ph.D. from University of Delaware.
Over the years, Dr. Hu has been working in catalysis science, new materials,
green chemistry, as well as new energy field; and he is holding more than
twenty US and PCT patents. In 2003, the team led by Dr. Hu was bestowed the
US Presidential Green Chemistry Challenge Award. In 2011, Dr. Hu was granted
the Person of ‘Eleventh Five-Year’ Chemical Industry Award, by Gu Xiulian, Vice
Chairman of PRC National People’s Congress, at Beijing National Convention
Center. In 2013, he was awarded as ‘Entrepreneur with Outstanding
Contribution’, in the program of “China Petroleum and Chemical Industry •
Corporate Citizenship Model Chart”.
Dr. Xiaodong Hu
Dr. Hu served as a Visiting Professor for the MOE Green Chemistry Key
Laboratory in Tianjin University, and for South China University of Technology.
Mr. Guanglian Pang, born on 22 Sep., 1967. International Marketing Specialist,
Senior Economist. Mr. Pang has a master’s degree from Peking University since
1991.
Secretary General of International Cooperation Committee, Director of
International Affairs, China Petroleum and Chemical Industry Federation Deputy
Director General, China National Chemical Foreign Economic Cooperation
Centre.
Mr. Guanglian Pang
Mr. Pang has won Science Award from Peking University and some honorary
titles have been awarded to him by CMC, Genertec and SASAC. He published
such books as Chinese-English Foreign Economic Contracts, Dictionary of English
Stylistics, etc and so many professional articles such as On Fund Management,
Saudi Petrochemical Industry, Survey of Iranian Petroleum & Chemical Industry
Development, Low Carbon Strategy and Environmental Responsibility of
Multinational Oil & Chemical Corporations in China, Outlook of China Gas
Industry, 8 Principal Basic Tasks for China’s Shale Gas Industry. He also led the
task forces such as REACH and the Impact on China Chemical Industry.
Page 19
Plenary discussion
speakers
Dave Martindale
Dave Martindale is Vice President and General Manager of UOP LLC’s
Engineering, Services and Equipment group. Dave is responsible for over 1500
technical personnel in 20 offices around the world. His group provides
engineering services, equipment design and project management,
commissioning support and technical services to UOP’s global customer base.
Dave began his career with UOP in 1979. Through the years, he has held
positions in R&D and Sales and management positions in Business,
Engineering, and R&D. In 2010, Dave was named the Sr. Business Leader for
PT&E Hydroprocessing. In 2012, Dave became the Sr. Director of R&D
Development for all UOP technologies. He was named the Vice President of
Engineering, Services and Equipment in early 2015.
Dave has a Bachelor of Science degree in Chemical Engineering and an MBA
from the Loyola University of Chicago.
Director, Strategic Innovation & Collaboration, GE China Technology Center
Dr. Bing Zhang has been China Technology Growth Leader of GE China
Technology Center since March 1, 2011. He responsible to drive In China For
China (ICFC) technology and product initiative across all businesses. The
program invested more than 250 million USD and resulted in 70+ new
products aiming at local market needs. Since 2014, Dr. Zhang has taken on
additional responsivity as the director for Strategic Innovation&Collaboration,
to facilitate growth through collaborations with government and external
institutions and companies in strategic technology areas. The center is one of
GE’s five global research centers, covering a diverse range of industries and
technologies including Energy, Water, Oil & Gas, Healthcare, Transportation,
Aviation, Lighting, and Industrial Solutions.
Dr. Bing ZHANG
Dr. Yi Jiang
Page 20
Dr. Yi Jiang, Business Director, Corning Incorporated (USA), is responsible for
general management of Corning Advanced-Flow Reactor (AFR) business
globally, and also for Emerging Business Development (EBD) in Asia. Formerly,
the Manager of Global Reactor & Application Engineering at Corning European
Technology Center in France; the Project Manager & Research Manager at
Corning Corporate Research in USA. Before joining Corning Incorporated, Yi has
worked in chemical & petrochemical industries (Sinopec, DuPont, and
ConocoPhillips) as senior process & research engineers for industrial novel
reactor designs and process development.
Yi earned his PhD in chemical engineering from Washington University in St.
Louis (USA); holds more than 10 patents, 30+ publications in top ranking
chemical engineering journals. Yi has served as chairs/co-chairs for novel
reactor technical sessions at AIChE Annual Meetings, Asia Pacific Chemical
Reactor Engineering Conferences etc. Yi delivered track records in revenue
growth and profitability for Corning new business in emerging markets, has
received “2013 Technology Innovation Award” and “2014 Outstanding
Entrepreneur Award” from China Petroleum and Chemical Industry Federation .
Plenary discussion
speakers
Arvind Varma is the R. Games Slayter Distinguished Professor and Head, School of
Chemical Engineering at Purdue University. His research interests are in chemical and
catalytic reaction engineering, and new energy sources. Dr. Arvind Varma has served
as the R. Games Slayter Distinguished Professor and Head, School of Chemical
Engineering at Purdue University since January 2004 – he was named Jay and Cynthia
Ihlenfeld Head in 2012. Prior to joining Purdue, he was the Arthur J. Schmitt Professor
of Chemical Engineering and Director of the Center for Molecularly Engineered
Materials at the University of Notre Dame.
Prof. Arvind Varma
Dan Luss is the Cullen Professor in the Department of Chemical & Biomolecular
Engineering at the University of Houston. Dr. Luss is the co-developer, director
and lecturer in a continuous education course on Applications of
Heterogeneous Catalysis given by now to over 2000 participants in the US and
600 in Europe. He is the editor of the book series, Reviews in Chemical
Engineering and the journal editor of Catalysis Reviews, Science and
Engineering. Dr. Luss has won the Wilhelm Award and Founders Award of the
AIChE, Research Award by the Alexander von Humboldt Foundation, and the
Amundson Award. He is a Fellow of the AIChE and a member of the National
Academy of Engineering.
Prof. Dan Luss
James Wei began his career as a research scientist for Mobil Oil in 1955. Since
then, he held academic positions as Colburn Professor at the University of
Delaware, Head and Lewis Professor at MIT’s chemical engineering department,
and Dean of Princeton's School of Engineering & Applied Science. As an expert
on the environmental impact of the chemical industry, he has participated in
many governmental panels, such as the National Research Council. Dr. Wei is
the author of eight books and many papers. He is a former president of the
AIChE and a member of the US National Academy of Engineering.
Prof. James Wei
Page 21
Plenary discussion
speakers
Professor in mechanical and chemical Engineering, East China University of
Science and Technoogy. He received Ph.D degree from Nanjing Tech University
in 1988. He has been engaged in the research of thermal effect on materials,
structures and processes, and development of micro chemo-mechanical
systems. He is an author of more than 300 papers and received a number of
distinguished national and international awards. He had been a vice president of
Nanjing Tech University and East China University of Science and Technology for
many years. He is now an honorary professor of the University of Nottingham
and has been the honorary President of Chinese Pressure Vessel Institution
(since 2010) and The honorary president of Chinese Materials Institution (since
2015), Chairman of China Structural Integrity Consortium, Chairman of Asian
Oceanic Regional Committee of International Council for Pressure Vessel
Technology.
Prof. Shan-Tung Tu
Professor and Head, Department of Chemical and Biomolecular Engineering,
Director, Centre for Green Products and Processing Technologies, Fok Ying Tung
Graduate School Co-Director, Joint Centre of HK-BJ UST, Fok Ying Tung Graduate
School, The Hong Kong University of Science and Technology.
Prof. Chen is the editor of Separation and Purification Technology, editorial
board member of International Journal of Drying Technology, Chinese Journal of
Chemical Engineering, International Journal of Food Engineering, International
Journal of Environment and Waste Management, Modern Chemical Industry;
IAC member of The 8th world congress of chemical engineers and the 13th AsiaPacific Confederation Conference of Chemical Engineering; SC Member of
the 2nd International Symposium on Green Chemical Products and Process
Engineering.
Prof. Guohua Chen
Prof. Wang currently is the Professor and Chairman of Department of Chemical
Engineering in National Taiwan University. He obtained his B.S. in Chemical
Engineering from National Taiwan University and Ph.D. in Chemical Engineering
from Pennsylvania State University.
Prof. Wang has been working in membrane separation technology, molecular
simulation and tissue engineering. In 2005, he was bestowed Outstanding
Teaching Award of the NTU. He is editorial board of Journal of Applied
Membrane Science and Technology, Chinese Institute of Chemical Engineers
and Journal of Chemical Engineering of Japan, Scientific Committee Member of
Aseanian Membrane Society, Scientific Committee Member of Aseanian
Membrane Society.
Prof. Daming Wang
Page 22
Space for Symposium
M105
M103
(M105)
M203
Page 23
List of
Symposium
No.
Symposia
Session
Room
1
Advanced Technology for Air Separation and
Purification
3
C201
2
Bioengineering and Biotechnology
5
C104
3
Catalysis and Reaction Engineering
4
C204
4
Energy
4
M105
5
Food and Pharmaceutical Technologies
5
C103
6
Green Technology
5
M1004
7
Management Science for Research and Development---How to make R&D effective and efficient
2
M806
8
Materials and Nano Technology
5
C208
9
Membrane Technology for Water Purification
4
C202
10
Particle and Fluidization Technology
3
M203
11
Petrochemicals and Fine Chemicals
3
M104
12
Process Development and Optimization
3
M103
13
Thermodynamics and Transport Phenomena
5
C209
14
Separation Technology
5
M106,
No16 Building
15
Forum of Chemical Engineering Department Deans
and Chairs
1
M103
Note: M806 and M1006 are also located in Yifu Building, on the 8th floor and 10th floor, respectively.
For example, the air separation/purification symposium is assigned S1.
Page 24
Parallel Symposium
Schedule Table
Tuesday Oct.13
Afternoon
C201
Yifu
Building
No.16
Building
Thursday Oct.15
Morning
Afternoon
Morning
1-A
1-B
1-C
Afternoon
C104
2-A
2-B
2-C
2-D
C204
3-A
3-B
3-C
3-D
M105
4-A
4-B
4-C
4-D
C103
5-A
5-B
5-C
5-D
5-E
C208
8-A
8-B
8-C
8-D
8-E
C202
9-A
9-B
9-C
9-D
M201
10-A
10-B
10-C
M104
11-A
11-B
11-C
M101
12-A
12-B
12-C
15
C209
13-A
13-B
13-C
13-D
13-E
M106
14-A
14-B
14-C
14-D
14-E
7-A
7-B
6-B
6-C
6-D
6-E
M806
Yifu
Building
Wednesday Oct.14
M1004
6-A
2-E
For example, Room C201 was allocated for the 3 sessions (1-A, 1-B, 1-C) of the air separation/purification
symposium on 10/14 (am & pm) and 10/15 (am).
Page 25
Keynote & Invited Speakers
The 8th Sino-US ChE conference will comprise 3.5 days of presentations; nearly
300 oral presentations and over 550 abstracts. This handbook only publishes some
feature abstracts. For more detailed information, please see our electronic version
of the proceedings.
Page 26
Symposium 1- Advanced Technology for Air Separation and Purification ( C201)
Symposium 1- Advanced Technology for Air Separation and Purification
Chairs: Zhong Li, [email protected]; Huizhou Liu, [email protected]
John Billingham, [email protected]; Norberto Lemcoff, [email protected]
Featured Speakers
Jerry Y. S. Lin
Wednesday Oct.14, 10:20-11:00 AM
C201, Yifu Building
Dr. Jerry Y.S. Lin is a Regents‘ Professor at the Arizona State University in
Tempe. He also serves as editor of Journal of Membrane Science. Dr. Lin
was a professor of chemical engineering and co-director of the NSF Center
for Membrane Applied Science and Technology at University of Cincinnati
prior to joining ASU in January, 2005. Dr. Lin received B.S. (1982) from
Zhejiang University in China, and M.S. (1985) and Ph.D (1988) from
Worcester Polytechnic Institute in the U.S., all in chemical engineering. In
research, Dr. Lin has made significant contributions to the advancement of
inorganic membrane science and high temperature gas separation
technologies. As of
January, 2015 he has published over 255
refereed papers in chemical engineering and materials science SCI journals,
10 book chapters and 50 conference proceedings papers; he also holds
8 patents; his papers have received over 8400 SCI citations (with H-index
over 51) .
Perovksite Structured Metal Oxide Sorbents with Oxygen Vacancy OrderDisorder Transition for High Temperature Air Separation
Oxygen sorption on perovskite-structured metal oxides offers an effective solution to air separation at
high temperatures. However, the main challenges in developing this new high temperature adsorption
separation technology are large heat of adsorption and slow desorption kinetic. This talk will present a
method to minimize the heat effects and enhance desorption kinetics by taking advantage of an
endothermic process of oxygen vacancy order-disorder phase transition accompanying the oxygen
sorption process on some perovskite-structured metal oxide sorbents. The paper will report oxygen
sorption isotherms, phase diagram, exothermic heat of oxygen sorption, and endothermic heat of
order-disorder phase transition for a perovskite sorbent with composition of La0.1Sr0.9Co0.9Fe0.1O3−δ.
The conditions for zero apparent heat of sorption are determined. The strategy for heat effect
minimization is demonstrated with the results of TGA/DSC measurements at different operating
conditions. Air separation by a fixed-bed packed with the perovskite-type oxide sorbent will be
presented to demonstrate the enhancement in the oxygen adsorption and desorption rates.
Page 27
Page 1
Heqing JIANG Wednesday Oct.14, 8:30-9:15 AM
C201, Yifu Building
Prof. Dr. Heqing JIANG is the Leader of Membrane Separation & Catalysis Group, Qingdao
Institute of Bioenergy and Bioprocess Technology, Chinese Academy of Science (QIBEBT,
CAS). After his postdoctoral stay with Prof. Schueth at the Max-Planck-Institut für
Kohlenforschung in Mülheim, he joined QIBEBT as a full professor in 2013. Dr. Jiang is the
recipient of Thousand Talents Program for Distinguished Young Scholars. His main
research interest focuses on the functional materials with nanostructures and their
application in separation and catalysis. So far, Dr. Jiang has published more than 30 papers
on a number of scientific journals such as Angew. Chem. Int. Ed., Chem. Commun., J.
Membr. Sci., etc.
Oxygen transport membranes for air separation under harsh conditions
The oxyfuel technology using ceramic membranes with mixed oxygen ion and electronic
conductivity for oxygen production represents a promising technique for CO2 capture, and is
considered as one of the most advanced technologies for clean power production. The operation
environment of oxygen transport membrane (OTM) in oxyfuel process is relatively harsh, and the
membrane is exposed to a recirculated sweep gas stream to pick up the permeated oxygen, which
contains highly concentrated CO2. The stability of the membrane against CO2 corrosion is essential to
guarantee long-term operation. In addition, OTM is attracting increasing interests as the reactor for
partial oxidation of methane to syngas due to the simplicity in process design, safety in operation, and
outstanding performance in oxygen separation. To choose appropriate OTM with high oxygen
permeability and thermochemical stability is very important when constructing such kind of membrane
reactors. In this talk, we will discuss the stability of cobalt-containing perovskites and ceria-based
membranes for air separation under CO2 or reducing atmosphere.
Chu Zheng
Thursday Oct.15 , 8:30-9:10 AM
C201, Yifu Building
Chu Zheng obtained PhD Degree from East China University of Science and Technology
in 2012. He is appointed as Deputy Chief Engineer of Nanjing Chemical Industry Group,
Director of R&D Dept, and concurrently President of Research Institute of Nanjing
Chemical Industry Group, Sinopec. He is also deputy president of CCU and CO2
Mineralization Utilization Institute of Sinopec &Sichuan University. Professional Field:
Technology development and management of Gas purification, CO2 Capture and
Utilization, Catalysis, Oilfield chemicals and Fine Chemicals. Obtained more than 10
times of Provincial & Ministerial Grades Award for Science and Technology Progress.
Published more than 10 professional papers, and be granted nearly 20 patents. He is
successively awarded as “Outstanding Contribution to Sinopec Experts”, “State Council
Expert for Special Allowance” and Senior Export of Sinopec.
CCUS Technology Development in SINOPEC
The paper summarizes SINOPEC’s research findings on various types of CCUS technology, and analyzes
their overall status of R&D&D (research and development and demonstration), technology feature,
challenging difficulty, development potential, application performance and promising prospect. SINOPEC has
comprehensively integrated with whole CCUS value chain, including carbon capture, utilization and EOR. In
the aspect of CO2 capture, SINOPEC has series of proprietary CO2 capture technologies and recently
developed numerous novel technologies. Meanwhile, SINOPEC has implemented CO2 utilization technology
featured as chemical utilization (methanol), mineralization utilization (solid waste phosphogypsum) and
biological utilization (microalgae oil). CO2 capture and injection into oil reservoirs for EOR is a practical and
economical way for reducing CO2 emissions and enhancing oil recovery. SINOPEC has been planning for
constructing four large gas flooding industrial demonstration projects to carry out CO2 EOR and storage,
including Shengli, Zhongyuan, Huadong and Dongbei.
Page 28
Wei Tang
C201, Yifu Building
General Manager of Beijing Peking University Pioneer Technology Co., Ltd.
Associate Professor of College of Chemistry and Molecular Engineering of
Peking University. Major participant of the Project “Development of Highly efficient
adsorbent for air separation and large scale VPSA-O2 equipment”, which won the
first prize for Science and Technology Progress by the Ministry of Education in 2006.
Major participant of the Project “Using highly dispersed CuCl/zeolite adsorbent for
CO separation”, which won the Second Prize for National Technology Invention in
2007
Separation of CO from blast furnace gas by VPSA using adsorbent PU-1
In China, steel plants are emitting 2×1010 m3/year blast furnace gas (BFG) containing 25% CO, which
might be used as fuel or to synthesize methane, acetic acid, DMF, DMC, glycol, TDI etc.. However, 50% N2 in
BFG makes it difficult for cryogenic separation, since the boiling points of CO and N2 are too close. To solve
that problem, a highly efficient CuCl/Zeoilte adsorbent named PU-1 has been developed, which has high CO
adsorption capacity and high CO/N2 selectivity. By using PU-1 in VPSA process, over 40 large scale
equipments have been built in China to separate CO from syngas, calcium carbide tail gas etc., with CO
purity >99% and recovery >85%. As for the separation of CO from BFG, the first 67000 Nm3/h plant was
built in China in 2013. Without pretreatment of 25% CO2 in BFG, the plant produces 20000 Nm3/h CO with
purity 65～75% and recovery >77%, which has been used as the fuel for steel rolling heating furnace,
replacing 4×107 Nm3 natural gas per year. Further removing CO2 in BFG, purification to >99% CO could be
done to meet the requirement of chemical synthesis.
Qingyuan Yang
C201, Yifu Building
Qingyuan Yang was born in China in 1976. He received his Ph.D. degree (2005)
in Chemical Engineering at Beijing University of Chemical Technology, then, he
joined the group of professor Chongli Zhong. He worked as a postdoctoral
research fellow at Université Montpellier 2 in France from 2010-2011. He
currently is a professor in Chemical Engineering at Beijing University of Chemical
Technology. His main research interest focuses on employing computational
techniques to model gas adsorption, diffusion and separation in nanostructured materials including metal-organic frameworks and covalent-organic
frameworks.
Computational study of structure-property relationships of
MOFs and COFs for gas separation
Currently, the associated research on MOFs and COFs has been rapidly developed into one of the important
areas in chemistry, materials science, and multiple branches of engineering. The remarkable feature of the
two types of porous materials allows them to serve as a uniquely ideal platform for various specific
applications including gas separation. Considering the structural complexity and diversity of MOFs and COFs,
molecular modeling provides a powerful tool to give deep insight into the phenomena studied at the
molecular level compared to experimental exploration. On the other hand, structure−property relationships
are crucial for enabling a theoretically rapid screening of existing MOFs and COFs as well as for guiding the
design/synthesis of novel adsorbents with desirable structural characteristics. Thus, with the aid of a multiscale computation, some new concepts and research methods have been developed for better
understanding the structure-property relationships of MOFs and COFs for targeted gas separation, and
some quantitative models have been further derived. These models could be used to rationalize and predict
the performance of a large series of MOFs and COFs as well as guide the design of advanced materials with
outstanding performance for industrial gas separation.
Page 29
Krista S. Walton
Wednesday Oct.14, 15:20-16:00 PM
C201, Yifu Building
Krista Walton was the Tim and Sharon Taylor Assistant Professor of Chemical Engineering
at Kansas State University from 2006-2009 and then joined the faculty of the Georgia
Institute of Technology in the School of Chemical & Biomolecular Engineering in August
2009. She serves as Director in the AIChE Separations Division and Secretary/Treasurer of
the International Adsorption Society.
Metal-Organic Frameworks for Removal of Ammonia from Air
Metal-organic frameworks (MOFs) are permanently porous coordination polymers that have recently
emerged as an important new class of porous materials with the potential to make an immediate impact in
adsorption separation technologies. MOFs are synthesized by a self-assembly process in which metal or
metal-oxide vertices are connected by rigid or semi-rigid organic molecules. The rational synthesis
approach opens up the possibility for new advances in the development of new and improved adsorbents
for air purification and the removal of toxic industrial chemicals.1 MOFs have shown the potential to be
designed for adsorbate-specific interactions. However, the density of active sites is often low, and the
commercial use of MOFs is still limited by issues with water stability2 and synthesis scale-up. This
presentation will discuss our recent progress in this area and will demonstrate the applicability of MOFs in
ammonia removal from air.
Page 30
Wednesday Oct.14 (C201)
Chair : John Billingham
Title
Morning
Name
Affiliation
S1-K1
Computational study of structure-property
Qingyua
relationships of MOFs and COFs for gas
n Yang
separation (A0150)
Beijing
University of
Chemical
Technology
9:10-9:40
S1- I1
Recent advances in oxygen production by Christian
VPSA (A0104)
Voss
Linde AG,
Engineering
Division
9:40-10:10
S1- I2
8:30-9:10
Progress on removal NOx and VOCs by
environmental catalysis (A0404)
10:1010:20
10:2011:00
11:0011:40
Junhua
Li
Tsinghua
University
Jerry Lin
Arizona State
University
Tang
Wei
Beijing
Peking
University
Pioneer
Technology
Co. Ltd
Name
Affiliation
Coffee break
S1-K2
Perovksite Structured Metal Oxide
Sorbents with Oxygen Vacancy OrderDisorder Transition for High Temperature
Air Separation (A0079)
Separation of CO from blast furnace gas
by VPSA using
adsorbent PU-1
S1-K3
11:4013:30
Chair : Norberto Lemcoff
Title
Afternoon
13:3014:10
S1-K4
Oxygen transport membranes for air
separation under harsh conditions (A0143)
Heqing
Jiang
Qingdao
Institute of
Bioenergy and
Bioprocess
Technology,
CAS
14:1014:40
S1-I3
Innovative Process Design for Large
Scale Air Separation (A0125)
Stephen
Cook
Air Products
PLC UK
14:4015:10
S1-I4
Core-shell oxide catalysts for VOCs
combustion
Shen
Zhao
Tsinghua
University
Page 31
Symposium 1- Advanced Technology for Air Separation and Purification ( 201)
15:10-15:20
15:20-16:00
16:00-16:30
16:30-17:00
Coffee break
S1-K5
S1-I5
S1-I6
Metal-Organic Frameworks for Removal of
Krista
Georgia Institute
Ammonia from Air （A0155）
Walton
of Technology
Synergy Action Mechanism of Water
Vapor and Surface Chemistry of
Adsorbents for Enhancing CO2/N2/CH4
Sepration (A0279)
Jing
Xiao
South China
University of
Technology
Hydrogen separation through mixed
proton-electron conducting membrane
(A0207)
Yanying
Wei
Institute of
Physical
chemistry and
Electrochemi
stry, Leibniz
University of
Hannover
Thursday Oct.15 (C201)
Chair : John Billingham
Morning
Title
Name
Affiliation
Nanjing
8:30-9:10
S1-K6
9:10-9:40
S1- I7
9:40-10:10
S1-I8
Chu
Zheng
Air purification in industrial and commercial
Norberto
environments (A0146)
Lemcoff
CFD study of mixing performance in
Quan
Sulzer Chemtech
redistribution systems for packed columns (A0306)
Yang
Ltd
Note: S ~ Symposium K~ Keynote I~ Invited talk
Page 32
Petrochemica
l Research
Institute Co.
Ltd., China
CCUS Technology Development in
SINOPEC (A0331)
Rensselaer
Polytechnic
Institute
Symposium 2- Bioengineering and Biotechnology (C104)
Symposium 2- Bioengineering and Biotechnology
Chairs: Jianhe Xu, [email protected]; Yan Sun, [email protected]
Shijie Liu, [email protected]; Steven Peretti, [email protected]
Featured Speakers
Percival Zhang
Tuesday Oct.13, 13:30-14:10 PM
C104, Yifu Building
Percival Zhang is a professor in department of biological systems engineering at Virginia
Tech. He received his M.S. degree (1996) in biochemical engineering at East China
University of Science and Technology and PhD in chemical engineering and biochemistry
from Dartmouth College. He worked as a postdoctoral research associate at Dartmouth
College from 2004-2005. He His main research interest focuses on watershed science &
engineering and biomolecular engineering. He was deputy editor-in-chief in Energy
Science and Engineering in 2012. He serves as academic editor in PLoS One.
Biomanufacturing 4.0: in vitro Synthetic Enzymatic Biosystems
The largest production challenge of biocommodities (e.g., biofuels, renewable chemicals, and even food)
from carbohydrates, other energy sources (e.g., solar energy and methane) or other carbon sources (e.g.,
CO2 and coal) is economics, satisfying three manufacturing criteria: high product yield, fast productivity and
easy product separation. Living natural or engineered cells have their inherent constraints, such as selfduplication, bioenergetics, cell membrane, and so on, resulting in their limited success in high-energy
efficiency biotransformation, especially in the energy area. In vitro synthetic biosystems (IVSB) via the in
vitro assembly of numerous standardized and exchangeable enzymes or their complexes and/or (biomimetic)
cofactors can implement complicated biological reactions that microbes cannot do .
Guanghui Ma
Thursday Oct.15, 8:30-9:10 AM
C104, Yifu Building
Ph.D., Doctoral Supervisor, Winner of the National Science Fund for Distinguished
Young Scholars, Member of “One Hundred Person Project of The Chinese Academy
of Sciences”, Director of National Key Laboratory of Biochemical Engineering,
Director of National Engineering Research Center for Biotechnology. Her main
research field focuses on bioformulation and biomaterial engineering. She has
published more than 200 peer-reviewed journal papers, 7 English and 4 Chinese
scientific books, 96 patents (44 granted) and 4 PCT patents. Recently, She has been
awarded National Award for Technological Invention 2nd Prize (2009), Asian Young
Women Researcher Awards 1st Prize in Engineering and Technology (2009), and
YABEC Award (2012).
Utilizing Microsphere Material Technology to Promote Development of
Biochemical Engineering
Microsphere materials have played great role on development of Biochemical Engineering and related
industries in history. Microcapsule technique promoted the birth of long-acting formulation of
protein/peptide drugs. Therefore, it can be expected the invention of new microsphere materials will lead to
development of biochemical engineering. In fact, in above chemical engineering application, the size and
morphology of microsphere materials should be controlled and optimized respectively according to their
applications. However, there is few method to prepare uniform microsphere for biocompatible polymer
system such like polysaccharide, polylactide, and so on. As a result, the effect of size on application results
could not be studied systematically and precisely.
Page 33
Yu-Chen Hu
C104 Classroom, Yifu Building
Dr. Yu-Chen Hu currently is a professor in department of chemical engineering,
National Tsing Hua University, Hsinchu, Taiwan. Dr. Hu’s main research interests
include vaccine development, gene therapy and tissue engineering. Dr. Hu has won
the Asia Research Award (Society of Chemical Engineers, Japan), Outstanding
Research Award (Ministry of Science and Technology, 2006, 2014), Wu Ta-You
Memorial Award (NSC), Outstanding Academia-Industry Research Award and
Outstanding Young Investigator Award in Taiwan.
Gene Therapy Meets Cell Therapy: Applications in Regenerative Medicine
Delayed union/non-union resulting from bone fractures or serious trauma remains a challenging problem
for orthopaedic surgeons. Conversely, cartilage defect or degeneration due to trauma or joint diseases can
lead to debilitating pain and physical impairment. These problems have inspired the development of tissue
engineering, which combines cells, biomaterials and biological signals, to stimulate cartilage/bone
regeneration. Over the past decade, gene therapy has converged with cartilage and bone engineering, by
which an increasing number of therapeutic genes are explored to stimulate cartilage and bone repair.
These genes can be administered to cells via in vivo or ex vivo approaches using either viral or nonviral
vectors. This presentation will focus on the use of viral vectors for genetic engineering of mesenchymal
stem cells for cartilage/bone regeneration. In particular, emphasis is placed on the applications of
baculovirus, an emerging nonpathogenic gene delivery vector, for the repair of cartilage and bone.
Jian-Jiang Zhong
Prof. Jian-Jiang Zhong graduated from Petro-Chemical Engineering course of ECICT
(Now: East China University of Science & Technology) in 1986, and obtained his Ph.D.
degree in Fermentation Technology/Biotechnology from Osaka University, Japan in
1993. He was awarded the Cheung Kong Scholar Professorship by the Ministry of
Education of China in 1999 and the National Science Fund for Distinguished Young
Scholars by NSFC in 2002. He is a Distinguished Professor of Shanghai Jiao Tong Univ.,
and on the executive board of Asian Federation of Biotechnology (AFOB). Dr. Zhong is
Editor-in-Chief of two SCI-journals - Process Biochemistry and Biotechnology and
Applied Biochemistry. Professor Zhong's major research interests include molecular
biochemical engineering, advanced fermentation technology, and synthetic biology.
Bioproduction process intensification by innovative engineering studies
on bioreactor and cellular metabolism
Bioproduction process has "green" and some unique features which attract great interest for industrial
application as a powerful biomanufacturing platform. Reduction of production cost, which depends on the
enhancement of bioprocessing efficiency, is a critical issue to commercial success. Bioproduction process
intensification, as a key to solving the bottleneck, was here achieved by innovative engineering studies on
bioreactor and cellular metabolism. A typical example to be illustrated is production of ganoderic acids by
Ganoderma lucidum, a traditional Chinese medicinal mushroom, which have significant anti-tumor and antimetastasis activities. Their further (pre-)clinic evaluations are severely hampered by lack of sufficient
amount of the pure compounds. To overcome the problem of target compound supply, advanced
bioprocess technology and smart bioseparation protocol are very important and urgently required. Our
strategies for enhancing the production and recovery of the secondary metabolites from fermentation of
the mushroom mycelia include bioreactor innovation, two-stage cultivation strategy, signal transduction
engineering of calcium/calcineurin signaling system, metabolic engineering, novel chemical conversion and
simultaneous extraction/hydrolysis, etc. This presentation will show how the titer and productivity of
fermentation production of ganoderic acid by G. lucidum was greatly improved by innovative engineering
studies.
Page 34
Zheng Liu
Prof. Zheng Liu is a Yangtze River Scholarship Professor of biochemical engineering
at department of chemical engineering, Tsinghua University. Prof. Liu obtained his
bachelor's, master's and doctoral degrees in chemical engineering from Tsinghua
University in 1987, 1989 and 1993, respectively. He worked as a UNESCO Research
Fellow at Tokyo Institute of Technology, Japan, during 1993 to 1994. Prof. Liu’
research focuses on chemical and biomolecular engineering, with special interests in
simulation and control of protein conformational transition in vitro; design and
synthesis nanostructured enzyme catalysts for chemical synthesis; and
bioremediation of contaminated soil. He has supervised more than 40 graduate
students, published 180 peer-reviewed journal papers, and 12 patents.
Harnessing Nanostructures for Enhanced Biocatalysis
This presentation will summarize our recent progress in constructing robust and active biocatalysts through
modifying enzymes by various nanomaterials. In addition to the enhanced activity, we will show how
nanostructures are applied for an enhanced catalysis through either substrate channeling or active uptake
of substrate. The newly developed methods including aqueous synthesis of multi-enzyme embedded MOFs
and Con A mediated multi-enzyme catalyst will be described. A multi-scaled molecular dynamics simulation
of CO2 transport into the active site of carbonic anhydrase will also be presented in the context of
fabricating a carbonic anhydrase based catalysts for enhanced CO2 capture and transformation.
He Huang
Dr. He Huang was born in 1974. He obtained PhD degree in chemical engineering
at Purdue University (USA) in 2002 and established laboratory of industrial
catalysis and microbial metabolic engineering at Nanjing University of Technology
in 2004. His main research interests focus on engineering technology platform for
microbial metabolism of bio based chemicals and industrial catalytic technology
platform for bio based chemicals. So far, Dr. Huang has published more than 90
papers on a number of scientific journals such as Biotechnol. Adv. Carbon., etc. He
is reviewers of several journals such as Bioresour. Technol., Process Biochem.,
Catal. Commun., etc.
Bioproduction of nutritional chemicals in China
With the increase of economic level and the improvement of the health concerns, people are increasingly
concerned about the nutrition, safety and function of the food. Nutritional chemicals are now the trend of
fine chemical industry. Nutritional supplements could be produced by enzymatically or through microbial
fermentation.
In the present report, the historic developments and technological achievements in
nutritional chemicals production in the past several years are reviewed. The species, characteristics, market
of nutritional chemicals were firstly introduced. Subsequently, recent studies of the bio-based nutritional
chemical production are summarized. In this part, we will focus on several typical products, such as
polyunsaturated fatty acids, vitamin K2, functional sugar, and so on. Furthermore, progress in the industrial
production of several nutritional chemicals is discussed. Finally, guidelines for future studies of nutritional
chemical production are proposed in light of the current progress, challenges, and trends in the field.
Page 35
Shijie Liu
Prof. Shijie Liu currently worked in SUNY ESF, he earned his PhD degree in
Chemical Engineering from University of Alberta, Edmonton (1992). His research
interests mainly focus on bioenergy, biomaterials, sustainability bioengineering,
chemical kinetics, mass transfer, fluid particle systems process optimization, fiber
properties, applied mathematics.
Ligand-Binding Isotherm and Catalysis of Polymorphic Enzymes
While most enzymes are single-sited for binding key ligands (or substrate) for which Michaelis-Menten
equation is adequate, there exist multiple binding-site enzymes. Multiple binding sites can appear either for
simple enzymes or for conformal complex structure of enzyme molecules. The multi-site behavior of
enzymes (or enzyme complexes) leads to the concepts of coorperativity, allostery or allosteric enzymes.
Substrate binding isotherm and catalytic rate expressions have been derived for multi-site enzymes without
differentiating the different structural confirmations. The simple kinetic expressions can explain some of the
simple allosteric interactions. Still, there are enzymes present as dynamic mixtures of multiple oligomer
forms, or polymorphs. A polymorph or system of multiple oligomeric enzymes can be summarily described
quantitatively with cooperative substrate binding and catalytic reaction theory.
Page 36
Tuesday Oct.13 (C104)
Chairs : Prof. Liu, Shijie, SUNY ESF
Afternoon
Title
Name
Affiliation
13:3014:10
S2-K1
Biomanufacturing 4.0: in vitro Synthetic
Enzymatic Biosystems (B0420)
Percival
Zhang
Virginia
Institute of
Technology
S2- I1
Engineering energy metabolism based
on synthetic cofactor (B0090)
Zongbao
Zhao
Dalian Inst
Chem Phys,
CAS
S2- I2
A novel biochemical route for fuels and
chemicals production from cellulosic
biomass (B0377)
Zhiliang
(Julia) Fan
University of
California ,
Davis
Zheng Liu
Tsinghua
University
14:1014:35
14:3515:00
15:0015:30
Coffee break
Chairs : Prof. Yuan Qi-Peng, Beijing Univ Chem Technol
15:3016:10
16:1016:35
16:3517:00
S2-K2
S2-I3
Harnessing Nanostructures for Enhanced
Biocatalysis (B0094)
Novel biocompatible materials and their
applications in biomedical engineering
Lei Zhang
(B0285)
S2-I4
Enzymatic Modification of Collogen
Proteins (B0190)
Daidi Fan
Tianjin
University
Northwest
University
Page 37
Chairs : Prof. Zhang, Lei, Tianjin University
Morning
8:30-9:10
9:10-9:35
9:35-10:00
Title
S2-K3
S2- I5
S2-I6
Name
Gene Therapy Meets Cell Therapy:
Applications in Regenerative Medicine Yu-Chen Hu
(B0432)
Build competitiveness of industrial
biotechnology (B0594)
Jibin Sun
Scale-up and Optimization of the Animal
Wensong
Cell Culture Processes and Bioreactors for
Tan
Biologicals Production (B0400)
10:00-10:30
Affiliation
Tsing Hua
University
Tianjin Inst
Ind
Biotechnol,
CAS
ECUST
Coffee break
Chairs : Prof. Zhang, Percival West Virginia
10:30-11:10
11:10-11:35
S2-K4
Bioproduction process intensification by
innovative engineering studies on
bioreactor and cellular metabolism
(B0165)
Jianjiang
Zhong
Shanghai
Jiaotong
University
S2-I7
Production of courmarines and muconic
acid by metabolic-engineered E. coli
(B0337)
Qipeng
Yuan
Beijing Univ
Chem Technol
Metabolic engineering of Saccharamyces
cerevisiae for production of fumaric acid Liming Liu
11:35-12:00
S2-I8
12:00-13:30
Page 38
(B0322)
Jiangnan
University
Chairs : Prof. Zhao, Zong-Bao, Dalian Inst Chem Phys, CAS
Afternoon
13:3014:10
14:1014:35
Title
S2-K5
Name
Ligand-Binding Isotherm and Catalysis
Shijie Liu
of Polymorphic Enzymes (B0296)
Affiliation
SUNY ESF
S2-I9
Engineering bacterial biocatalysts for
Christopher
ESF, Syracuse
the production of biodegradable
Nomura
plastics (B0463)
S2-I10
Enhancement of Fatty Alcohols
Production with E. coli Modified with
Tandem Repeats Assisted Genome
Editing Method (B0124)
Jianmin
Xing
Institute of
Process
Engineering,
CAS
S2-K6
Bioproduction of nutritional chemicals
in China (B0205)
He Huang
Nanjing
University of
Technology
16:1016:35
S2-I11
Microalga Neochloris Oleoabundans
Cultivation for Biodiesel Feedstock
(B0419)
Zisheng
(Jason)
Zhang
U Ottawa
16:3517:00
S2-I12
Cellulosic ethanol production using
Jerusalem Artichoke stalks: strain
development and process integration
Xinqing
Zhao
Shanghai
Jiaotong Univ
Name
Affiliation
Guanghui
Ma
Institute of
Process
Engineering,
CAS
14:3515:00
15:00-
Coffee break
15:30
Chairs : Prof. Lin, Dong-Qiang, Zhejiang University
15:3016:10
Thursday Oct.15 (104)
Chair: Prof. Liu, Prof. Christopher Nomura
Morning
Title
8:30-9:10
Utilizing Microsphere Material
Technology to Promote Development
of Biochemical Engineering (B0508)
S2-K7
Page 39
9:10-9:35
9:3510:00
S2-I13
Rational design of mixed-mode
Dongqiang
chromatography for antibody purification
Lin
(B0149)
Zhejiang
University
Xiao
Zhang
Washington
State
University
S2-I15
Engineering clostridia for biofuels and
chemicals production from renewable
biomass (B0385)
Shangtian
Yang
The Ohio
State
University
S2-I16
Dry milling biorefinery processing of
lignocellulose biomass for production of
biofuels and biochemicals (B0095)
Jie Bao
ECUST
S2-I17
High-throughput droplet microfluidic
screening for improving protein secretion
of cell factories
Yunpeng
Bai
ECUST
S2-I14
Biomaterial from renewable
lignocellulosic biomass (B0367)
10:0010:30
Coffee break
Chairs: Prof. Sun, Yan, Tianjin Univ
10:3010:55
10:5511:20
11:2011:45
12:0013:30
Chairs : Prof. Zheng Liu (Tsinghua Univ)/Prof. Liu, Shijie, SUNY ESF
13:3015:00
Free discussion: New opportunities and challenges of industrial biotechnology
Note: S ~ Symposium; K~ Keynote lecture; I~ Invited talk
Note: Chairs will announce at the beginning of the symposium that there would be a free discussion session (2E)
on Thursday afternoon.
Page 40
Symposium 3- Catalysis and Reaction Engineering (C204)
Symposium 3- Catalysis and Reaction Engineering
Chairs: Guanzhong Lu, [email protected]; Xiaojun Bao, [email protected]
Maria Burka, [email protected]; Ted Oyama, [email protected]
Featured Speakers
Bruce C. Gates
C201, Yifu Building
Bruce Gates began his career as a researcher at Chevron. He then joined the
chemical engineering department at Delaware University. He was one of the
founders of the Center of Catalytic Science and Technology at Delaware. He
coauthored the widely-used text book “Chemistry of Catalytic Processes.” In 1992,
Dr. Gates joined the University of California Davis. His research interests are:
catalysis, nanomaterials, surface chemistry, organometallic surface chemistry, new
catalytic materials, reaction kinetics and engineering.
He made seminal
contributions to hydroprocessing, a vital petroleum refining process. He received
many awards from the AIChE, ACS, and North American Catalysis Society. He is a
member of US Academy of Engineering.
Molecular Metal Catalysts on Supports:
Organometallic Chemistry Meets Surface Science
Advances in synthesis and characterization of essentially molecular metal complexes and clusters on supports are
making a reality of catalyst design. We summarize work unraveling effects of the design variables of these siteisolated catalysts: the metal, metal nuclearity, support, and other ligands on the metal. Successful syntheses
provide structurally simple, uniform species bonded to crystalline porous supports chosen for their relatively high
degrees of uniformity: zeolites, MOFs, and MgO. The catalyst syntheses involve reactions of organometallic
precursors (e.g., Ir(C2H4)2(acac) (acac is acetylacetonate) with OH groups of the support surfaces—to give
structures such as Ir(C2H4)2, with the Ir atom bonded to two oxygen atoms of the support. The methods of
characterization of the supported species include IR, EXAFS, XANES, and NMR spectroscopies, atomic-resolution
electron, and computations at the level of density functional theory.
Tao Zhang
Dr. Tao Zhang is currently a Professor & Director General of the Chinese Academy of
Sciences from State Key Laboratory of Catalysis, Dalian Institute of Chemical Physics,
CAS. He was elected as member of Chinese Academy of Science. His research expertise
and interests are in the area of catalytic decomposition technology of aerospace nontoxic propellants, environmental catalysis, new catalytic materials, etc. So far, there
are more than 260 SCI papers and 100 patents to be published. He is the editorial
broad of Applied Catalysis, Environmental and ChemPhyChem.
Catalytic conversion of biomass to fuels and chemicals:
opportunities and challenges
Lignocellulose is the most abundant biomass. The huge and diversified resources and non-edible nature of
lignocellulose make it an ideal feedstock alternative to fossil for the sustainable production of fuels and chemicals
in a renewable way. Catalysis is intensively involved in the biorefinery of lignocellulose, as it has been doing in the
oil/coal refinery process. However, the stubborn and recalcitrant structure of lignocellulose, the high O/C ratio in
its composition, and the difficulty in separation of cellulose, hemicellulose and lignin in natural raw materials
present significant challenges in the biorefinery process. In this presentation, I will first give a summary of the
recent advances in the catalytic conversion of biomass to fuels and chemicals, and then put focus on the
development of new catalytic processes in my own group, and finally provide an outlook on the opportunities and
challenges.
Page 41
James Wei
Diffusion Regimes of Molecules in One-dimensional Zeolite Channels
The diffusion of noble gas molecules (Ne, Ar, Kr) in one-dimensional zeolite channels (VET, AFI, VFI) is simulated
by molecular dynamics. The diffusion regimes include: Knudsen Diffusion where molecule-wall collisions
dominate, Gaseous Diffusion where molecule-molecule collisions dominate, and Configurational Diffusion where
molecule and wall are in constant contact. The principal parameters in the determination of diffusivity regimes
are: the diameter ratio (dc/dm) of the channel to the molecule, and the volume density (NVm/Vc) which is the
ratio of the volume of N molecules to volume of channel. For a molecule in a channel, we define the mean stop
path (MSP) as the average distance between collisions, which may be with another molecule or with the wall; it
depends on both the mean free path and the channel diameter.
Dan Luss
Impact of cycling and catalyst configuration on reduction of NOx emission
from diesel engines
The reduction of NOx gases emitted by diesel passenger cars is usually accomplished by a Lean NOx Trap
(LNT) also referred to as NOx Storage and Reduction (NSR) technology. This process consists of periodic cycling
between a lean feed (NOx + excess O2,), leading to storage of the NOx storage on the LNT catalyst
(Pt/BaO/CeO2/Al2O3) and a rich feed (mixture of CO, H2 and hydrocarbons) that reduces the stored NOx to N2 .
The NOx conversion by the LNT is typically unsatisfactory (< 80%) at exhaust temperatures lower than 200 oC,
and higher than 400 oC. Toyota researchers developed a Di-Air (Diesel NOx aftertreatment by Adsorbed
Intermediate Reductants) process in which a high frequency injection of hydrocarbon expands the operating
temperature window of the LNT.
Page 42
Xiaojun Bao Wednesday Oct.14, 15:20-16:00 PM
Dr. Xiaojun Bao was born in April, 1963. He is currently a professor of the faculty of
Chemical Science and Engineering in China University of Petroleum (Beijing) as well as
director of The Key Laboratory of Catalysis, China National Petroleum Co. Dr. Xiaojun
Bao’s main research interests include synthesis of mesoporous materials, catalyst
development for upgrading petroleum products, catalyst and reactor development for
synthesis gas making via partial oxidation. Dr. Xiaojun Bao has been editorial members
of Chinese Journal of Chemical Engineering, Chinese Journal of Fuel Chemistry,
Petroleum Science. So far, there are more than 20 SCI papers and four monographs to
be published.
Development and Application of A Fluid Catalytic Cracking Gasoline
Hydro-Upgrading Process GARDES
More than 90% of sulfur-containing compounds and about 90% of olefins in typical refinery gasoline pools
come from fluid catalytic cracking (FCC) gasoline, thus the sulfur and olefin reduction of this stream is crucial
for producing clean gasoline. It has been widely recognized that hydrotreating is the most important
technique for producing clean transportation fuels in industrial practice, but the existing techniques can
hardly accomplish the objectives of both deep hydrodesulfurization (HDS) and olefin reduction of FCC
gasoline with acceptable loss in gasoline research octane number (RON). To solve this problem, we
developed a novel process, GARDES, by coupling high-efficient HDS and directed olefin conversion.
Michael P. Harold
Michael P. Harold is Dow Chair Professor and Chairman of the Department of
Chemical Engineering at the University of Houston. In the 1990’s, he was a
research manager of the Chemical Process Fundamentals Group in the Central
Research Department of DuPont. In this role Mike led programs to develop
breakthrough technologies for the manufacture of key industrial polymers and their
corresponding chemical intermediates, and synthetic melt-spun fibers. Mike’s
expertise and research interests are in the area of chemical reaction engineering,
with specific focus on reaction-separation devices, inorganic membrane synthesis
and applications, and catalytic and biocatalytic materials. He is the editor of the
AIChE J.
Reaction and Transport Coupling in Multi-Functional Catalysts
for Selective Oxidation of Ammonia to N2
The reduction of NOx from lean burn engine exhaust involves structured catalytic reactors wherein storage,
transport and reaction are coupled to achieve emission targets over a wide range of temperatures and
space velocities. The lean selective catalytic reduction (SCR) of NOx requires the supply of the reductant
NH3, a fraction of which may escape unconverted from the SCR reactor. For this reason an “Ammonia Slip
Catalyst” (ASC) is positioned downstream of the SCR catalyst with the purpose of eliminating the slipped
ammonia by catalytic oxidation to N2. The most active ammonia oxidation catalyst is Pt but the N2
selectivity is only high near the light-off temperature (~200-250 oC). At higher temperature NO and NO2
are the major oxidation products. The ASC combines an ammonia oxidation catalytic function containing Pt
with a NOx reduction function containing Fe- or Cu-exchanged zeolite to convert NH3 with high selectivity
to N2. In this talk we describe the performance features of the ASC reactors comprising catalyst
architectures that combine multiple active layers and/or zones containing the NH3 oxidation and NOx
reduction functions. We show how focused experiments complemented by modeling can not only lead to
deeper insight but also to “optimal” structures and operating strategies.
Page 43
Suojiang Zhang
Suojiang Zhang is Professor & Director General of Institute of Process Engineering (IPE),
Chinese Academy of Sciences (CAS). Since 2001, he started to work in IPE as the
"Hundred Talents". He won “National Science Fund for Distinguished Young Scientists”
in 2006 and “973 Chief Scientist” in 2008. Prof. Zhang mainly engages in ionic liquids
and green process engineering, including molecular design, large-scale preparation,
clean processes and system integration. He has published more than 180 SCI papers in
academic journals, and authored or edited four monographs, and filed for more than
40 patents. He served as the editor in chief of Process Engineering Journal (China), and
Editorial Board Members of Journal of Industrial & Engineering Chemistry Research,
Journal Greenhouse Gases: Science and Technology, Science China Chemistry and etc.
Ionic Liquid Catalytic Reaction for Green Process Engineering
As a green medium, ionic liquids (ILs) have been widely used in catalytic reaction, organic synthesis,
separation process and other fields due to their unique properties and great potentials in industry
applications. We focused on the investigation of ILs from fundamental studies to practical applications. On
the molecular level, we found that H-bond in ILs showed the covalent feature based on the molecular
dynamic simulation and experimental characteristic, which has been defined as a new concept of Z-bond. It
was also found that Z-bond made a great contribution to the catalytic reaction. We revealed the synergistic
catalytic effect of cations and anions, and developed series of homogeneous and supported functionalized IL
catalysts with high catalytic activity. Based on the fundamental research on Z-bond, the novel green
processes were established.
Page 44
Chair : Tao Zhang/Ted Oyama
Afternoon
Title
13:3014:10
S3-K1
14:1014:40
S3- I1
14:4015:10
S3- I2
Molecular Metal Catalysts on Supports:
Organometallic Chemistry Meets
Surface Science (C0406)
Development of Earth Abundant
Membrane Reactors for Energy Efficient
Chemical Processing (C0380)
Theoretical studies of rare earth CeO2
catalysis (C0545)
15:1015:20
Name
Bruce
Gates
Colin A
Wolden
Xueqing
Gong
Affiliation
University of
California,
Davis
Colorado
School of
Mines
ECUST
Coffee break
15:2016:00
S3-K2
16:0016:30
S3-I3
16:3017:00
S3-I4
Dalian
Catalytic conversion of biomass to fuels
Institute of
and chemicals: opportunities and
Tao Zhang
Chemical
challenges
Physics,
CAS
ExxonMobil
Bifunctional Zeolite-Metal Catalyzed
JoséG.
Research and
Paraffin Hydroisomerization:
Santiesteba Engineering
Implications for Production of High
n
Company
Performance Distillate and Lubricants
Annandale
(C0365)
The
Kinetics and mechanism of
Ted
University of
hydrodeoxygenation of a model biomass
Oyama
Tokyo/Virgin
compound on nickel phosphide (C0049)
ia Tech
Chair : Chunming Xu/ Ted Oyama
Morning
8:30-9:10
9:10-9:40
9:40-10:10
Title
Name
Affiliation
S3-K3
Diffusion Regimes of Molecules in Onedimensional Zeolite Channels (C0378)
James Wei
Princeton
S3- I5
Electrocatalytic Dehydrogenation of 2propanol in EHP reactor
Xuemei
Wu
Dalian
Univerisity
of
Technology
S3-I6
Selective oxidation of glycerol to
dihydroxyacetone catalyzed by Pt-Bi
supported on N-doped carbon nanotubes
(C0185)
Hao Yu
South China
University of
Technology
Page 45
Symposium 3- Catalysis and Reaction Engineering(C204)
10:1010:20
10:2011:00
11:0011:30
11:3012:00
Coffee break
Chunming
Xu
China
University of
Petroleum
Goetz
Veser
University of
Pittsburgh
Andrew
Gellman
Carnegie
Mellon
University
Name
Affiliation
Dan Luss
University of
Houston
Boping
Liu
ECUST
Dalin Li
Fuzhou
University
S3-K6
Development and Application of A Fluid
Catalytic Cracking Gasoline HydroUpgrading Process GARDES (C0414)
Xiaojun
Bao
China
University of
Petroleum,
Beijing
S3-I11
Integrated Multi-functional Catalyst
Devices for Vehicle Emission Control
(A0268)
Wei Li
GM
S3-I12
Quantitative Kinetics and the Structural
Mechanism for Ni-Co Dry Reforming
Catalysts (C0065)
Haiyan
Zhao
University of
Idaho
S3-K4
S3-I7
S3-I8
12:0013:30
Composite Ionic liquid alkylation(CILA)
process produces high-quality gasoline
Bimetallic Oxygen Carriers for
Chemical Looping Conversion of
Methane (C0248)
Alloy Catalysis across Alloy
Composition Space: AuxCuyPd1-x-y
(C0055)
Chair : Xiaojun Bao/Maria Burka
Afternoon
Title
13:3014:10
S3-K5
14:1014:40
S3-I9
14:4015:10
S3-I10
15:1015:20
15:2016:00
16:0016:30
16:3017:00
Page 46
Impact of cycling and catalyst
configuration on reduction of NOx
emission from diesel engines (C0175)
One Pot Synthesis of Bimodal Molecular
Weight Polyethylene Using Cr/V
Bimetallic Catalysts
Controlled synthesis and catalytic
property of Ni-based alloy catalysts for
steam reforming of tar (C0246)
Coffee break
Chair : Suojiang Zhang/ Ted Oyama
Morning
Title
Name
Affiliation
8:30-9:10
S3-K7
Reaction and Transport Coupling in
Multi-Functional Catalysts for Selective
Oxidation of Ammonia to N2 (C0325)
Michael
Harold
University of
Houston
S3-I13
From fundamentals to industrial practice:
ordered-structure carrier materials in
hydortreating catalyst for ultra-clean
fuel production (C0309)
Yandan
Wang
China
University of
Petroleum,
Beijing
S3-I14
Bimetallic structure considerations in
the catalytic production of aromatic
amines (C0374)
Michael
Wong
Rice
University
9:10-9:40
9:40-10:10
10:1010:20
Coffee break
10:2011:00
S3-K8
Ionic Liquid Catalytic Reaction for
Green Process Engineering (C0265)
Suojiang
Zhang
Institute of
Process
Engineering,
CAS
11:0011:30
S3-I15
Catalytic Consequences of LayeredZeolite Precursor Delamination (C0081)
Alexander
Katz
UC Berkeley
Raffaella
Ocone
Heriot-Watt
University
11:3012:00
12:0013:30
Complex Reactions in a FCC Riser
S3-I16
Reactor (C0184)
Page 47
Symposium 4- Energy (M105)
Symposium 4- Energy
Chairs: Zhongmin Liu, [email protected]; FuchenWang, [email protected]
Mike Klein, [email protected]; Joseph Smith, [email protected]
Featured Speakers
Arvind Varma
Tuesday, Oct.13, 13:30-14:10 PM
M105, Yifu Building
Selected Topics Related to Energy and Chemicals
In the presentation, some selected research programs to produce energy carriers and valuable chemicals from
new or renewable sources, currently being conducted in my group, will be discussed. These include (i) hydrogen
generation for vehicle applications, (ii) catalytic upgrading of bio-oils, (iii) utilization of glycerol, a biodiesel waste
product, for its purification and production of valuable chemicals, and (iv) oxidative coupling of methane [6].
Xinbin Ma
Tuesday, Oct.13, 15:20-16:00 PM
M105, Yifu Building
Xinbin Ma is the Dean of School of Chemical Engineering and Technology, Tianjin
University. His research interests are in C1 chemical engineering, and green
chemistry and technology.
An Alternative Synthetic Route for Ethylene Glycol/Ethanol Production:
Fundamental Research and Industrial Applications
Ethylene glycol (EG) and ethanol (EtOH) are important chemicals or fuel additives used in a variety of consumer
and industrial applications. We described an alternative approach for the synthesis of EG/EtOH derived from
syngas based on an integrated technology consisting of the coupling of CO with methanol to form dimethyl
oxalate (DMO) and subsequent hydrogenation. For the key issues of copper-based catalysts faced in the
hydrogenation reaction, such as indeterminate active sites, unstable active species and the internal diffusion limit
in scale-up, new strategies were presented not only for design of a highly efficient and stable catalyst, but also for
highly chemo-selective synthesis of EtOH and EG.
……
Page 48
Jinsen Gao
Wednesday, Oct.14, 10:20-11:00 AM
M105, Yifu Building
Jinsen Gao is the dean of Chemical Engineering College in CUPB and director of
the State Key Laboratory of Heavy Oil Processing. His research interests are in
heavy oil processing technology, clean fuel oil production and computational
chemical engineering.
An Upgrading Process of Viscous Heavy Oil by
Fluid Thermo-Cata-Contacting Conversion
Pretreating inferior residues to provide feedstock with trace metals and a few asphaltenes for
downstream processes is important for refineries to process heavier crude oils. Toward this end, the
upgrading of Liaohe vacuum residue over special catalysts designed for decarbonization and demetalization,
which is called fluid thermal conversion (FTC), was investigated in a technical pilot scale riser apparatus. The
experimental results demonstrate that moderate cracking severity is favorable for obtaining the maximum
distillate (C5~500 oC) yield. Under the favorable conditions, the yield of total liquid product was 79.63 wt%,
and coke yield was 15.59 wt%, which took up 87% CCR value of the feedstock, while the gas yield was 2.11
wt%. In addition, most of the contaminants, such as above 97% asphaltenes and metals were removed.
Then, the properties of liquid products were analyzed in detail. The RON of gasoline is high up to 94,
whereas that is generally only about 60 for coker gasoline. The basic nitrogen compounds in heavy cycle oil
was 824 μg•g-1, only about 1/3 that of coker gas oil. To understand secondary processing performance of
heavy liquid products, fluid catalytic cracking (FCC) of heavy cycle oil and FTC of slurry were conducted. The
results reveals that heavy cycle oil has better FCC ability than coker gas oil, whereas FTC ability of slurry is
considerably below that of Liaohe vacuum residue.
Jingguang Chen
Wednesday, Oct.14, 13:30-14:10 PM
M105, Yifu Building
Jingguang Chen is the Thayer Lindsley Professor of Chemical Engineering in the
Department of Chemical Engineering at Columbia University. Previously, he was a
senior researcher at Exxon’s Corporate Research Laboratories. His research interests
are in understanding and developing metal carbides and bimetallic alloys as catalysts
and electrocatalysts through combined theoretical and experimental approaches over
model surfaces and supported catalysts. He is an expert in using in situ synchrotron
techniques for investigating structural and electronic properties of catalysts.
CO2 Conversion to Methanol and Syngas
Rising atmospheric concentration of CO2 is forecasted to have potentially disastrous effects on the global
climate changes and ocean acidification. A catalytic process that utilizes CO2 as a feedstock to make
methanol, carbon monoxide, or methane is potentially more desirable than sequestration. In the current
talk we will describe our recent results of CO2 conversion through heterogeneous catalysis, using
approaches involving parallel efforts in density functional theory (DFT) calculations, surface science
experiments on model systems, synthesis and evaluation of supported catalysts, and in-situ characterization
of catalysts under reaction conditions. We will compare three examples for the catalytic conversion of CO2,
to methanol over Cu-based oxides, to methane over bimetallic alloys, and to CO over metal carbides. We will
discuss general trends, challenges and opportunities for the catalytic conversion of CO2.
Page 49
Yong Yang
Wednesday, Oct.14, 15:20-16:00 PM
M105, Yifu Building
Yong Yang is the Director of research and development center of Synfuels
China Co., Ltd. His research interests is in the catalytic chemistry of coal-toliquids
Fischer–Tropsch synthesis process development:
from laboratory to commercial scale
Milestone advances using Synfuels China’s Fischer–Trospch (F–T) synthesis technology have been made
towards commercialization of Fischer-Trospch synthesis technology in China. A four million ton/a coal-toliquids (CTL) plant is under construction in Ningxia province following the successful technology
demonstration at 4000 bbl/d scale in Inner Mongolia. The CTL process development by Synfuels China
started from solid fundamental studies with more than twenty years experience accumulation in catalysis
and kinetic studies, which led to the demonstration of Synfuels China’s medium temperature FT (MTFT)
synthesis process. Density Functional Theory (DFT) together with the sophisticated catalyst property
characterization tools has been routinely applied during catalyst development. Fundamental R&D efforts
integrating all aspects of chemical engineering have greatly been enhanced by combining the fundamental
tools covering the F–T synthesis mechanism, reaction engineering, and process optimization.
Joseph Smith
M105, Yifu Building
Joseph D. Smith currently holds the Laufer Endowed Energy Chair at Missouri University
of Science and Technology (formally Missouri Rolla) where he also serves as Director of
the Energy Research and Development Center, positions to which he brings over 25
years of diversified experience in academia and industry. Dr. Smith has served as an
expert witness for Flare Performance and Hydrocarbon Processing. He has significant
experience in the fossil energy industry, including application of multi-physics CFD based
models for coal combustion, biomass gasification, and industrial furance optimization.
Resilient Energy through Hybridization in Microgrid Applications
In the future, the electric grid must be more resilient and adaptable to local catastrophes including fires,
severe storms, and heat waves. Microgrids represent a way to improve energy resilience because they
would allow smaller regions (neighborhoods, towns, cites) to disconnect from the national electric grid and
become islands of stable, independent power to support critical infrastructure including hospitals, airports,
food distribution, communication centers, etc. The work reported here describes efforts to develop resilient
energy through hybridization in Microgrid applications. These efforts are focused on incorporating clean,
low-carbon energy resources together with efficient energy storage and local on-site energy management
systems. These microgrids will help meet carbon reduction goals as we explore concept that integrate
various technologies into the larger grid, including electric vehicles.
The focus of our work has been to assess the viability of a microgrid to manage renewable energy
together with conventional energy resources to meet electric power demand while minimizing adverse grid
impacts. Our work examines the use of microgrid controller/energy management systems coupled with
renewable energy resources (i.e., solar, wind, geothermal, hydro, biomass) in a hybridized energy system.
Our work examines the economic impact replicating deployment of renewable-based microgrids for
commercial, industrial, and mixed-use applications.
……
Page 50
Tuesday, Oct.13 (M105)
Chair : Zhongmin Liu
Afternoon
13:30-14:10
S4-K1
14:10-14:40
S4-I1
14:40-15:10
S4-I2
Title
Name
Affiliation
Selected Topics Related to Energy and
Chemicals (D0506)
Arvind
Varma
Prudue
University
Dalian
Recent researches on coal pyrolysis in DUT Haoquan
University of
(D0583)
Hu
Technoloy
North Carolina
Tailored Transition Metal Oxides for Light Fanxing
State
Paraffin Conversion (D0053)
Li
University
15:10-15:20
Coffee break
15:20-16:00
S4-K2
An Alternative Synthetic Route for
Ethylene Glycol/Ethanol Production:
Fundamental Research and Industrial
Applications (D0566)
16:00-16:30
S4-I3
High Energy Density Chemistries for
Redox Flow Batteries (D0203)
16:30-17:00
S4-I4
17:00-17:30
S4-I5
Recent Progress in Heavy Oil
Hydroconversion (D0379)
Xinbin
Ma
Tianjin
University
Levi
University of
Thompson Michigan
Min
Chang
Ultra-deep Reactive Adsorption
Desulfurization of FCC Gasoline over Ca- Hao Ling
Doped Ni/ZnO-Al2O3-SiO2 Adsorbents
Alpha
Management
Consulting
Services
ECUST
Wednesday, Oct.14 (M105)
Chair : Michael Klein; Xinbin Ma
Morning
Title
Name
Affiliation
Xinjin
Zhao
ExxonMobil
8:30-9:10
S4-K3
The Outlook for Energy: A View to 2040
(D0195)
9:10-9:40
S4- I6
Molecular Characterization and Modeling
Shu Wang AspenTech, Inc.
for Crude Oil and Reactors (D0066)
S4-I7
Chemical Looping Gasification with
University of
Catalytic Oxygen Carrier for Hydrogen- Kunlei Liu
Kentucky
Rich Syngas Production (D0409)
9:40-10:10
10:10-10:20
Coffee break
Page 51
10:20-11:00
S4-K4
11:00-11:30
S4-I8
11:30-12:00
S4-I9
12:00-13:30
An Upgrading Process of Viscous Heavy
China
Oil by Fluid Thermo-Cata-Contacting Jinsen Gao University of
Conversion (D0399)
Petroleum
Evaluation of CO2 capture from flue gas by
two successive VPSA units in an existing Ping Li
coal power plant (D410)
Beyond Carbon Neutral (D0327)
ECUST
Mark
Barteau
University of
Michigan
Energy
Institute
Name
Affiliation
Chair : Joseph Smith; Jinsen Gao
Afternoon
Title
CO2 Conversion to Methanol and Syngas Jingguang
Chen
(D0375)
Columbia
University
13:30-14:10
S4-K5
14:10-14:40
S4-I10
Research and application of SE gasification Xiaolei
technology of pulverized coal (D0525)
Guo
14:40-15:10
S4-I11
RD&D Activities of SNG Production from Zhongshan Dalian Institute
Yuan
Syngas Methanation at DICP
of Chem Phy
15:10-15:20
15:20-16:00
16:00-16:30
Coffee break
S4-K6
S4-I12
Fischer–Tropsch synthesis process
development: from laboratory to
commercial scale (D0590)
Synfuels China
Yong YangTechnology Co.,
Ltd
Software Tools for Molecular-Level Kinetic
Michael
Modeling in Thermochemical
Klein
Conversions(D0166)
16:30-17:00
S4-I13
Co-feeding of biomass liquids with fossil
feedstocks to FCC unit for production of Siauw Ng
renewable transportation fuels (D384)
17:00-17:30
S4-I14
Hydrogen production from biomass using
an integrated process (D0442)
Page 52
ECUST
Suping
Zhang
University of
Delaware
Canmet
ENERGY,
Natural
Resources
Canada
ECUST
Thursday Oct.15 (M105)
Chair : Michael Klein; Fuchen Wang
Morning
Title
8:30-9:10
S4-K7
Resilient Energy through Hybridization in
Microgrid Applications (D0396)
9:10-9:40
S4-I15
Understanding the influences on coal ash
slag viscosity at gasification condition
(D0453)
9:40-10:10
S4-I16
10:10-10:20
S4-I17
10:50-11:20
S4-I18
11:50-13:30
Affiliation
Missouri
Joseph University of
Smith
Science and
Technology
Institute of
Jin Bai Coal Chemistry,
CAS
Soil-based Microbial Fuel Cell for
Indore Institute
Mukund
Electricity generation using Shewanella and
of Science &
Mishra
Geobacter bacteria present in soil (D0580)
Technology
Coffee break
10:20-10:50
11:20-11:50
Name
S4-I19
FCC co-processing of oil sands bitumen
and shale oil (D0401)
Canmet
ENERGY
Yi Zhang Devon, Natural
Resources
Canada
Molecular-Level Modeling on the
Linzhou
Composition, Conversion and Separation of
Zhang
Heavy Petroleum (D0495)
Biomass Conversion to Hydrogen with
Suppressed COx formation via Alkaline Ah-Hyung
Thermal Treatment and integrated Carbon
Park
Capture (D0593)
China
University of
Petroleum
Columbia
University
Page 53
Symposium 5- Food and Pharmaceutical Technologies (C103)
Symposium 5- Food and Pharmaceutical Technologies
Chairs: Yingjin Yuan, [email protected]; Bangce Ye, [email protected]
Daniel Hsieh, [email protected]; Shang Tian Yang, [email protected]
Featured Speakers
San Kiang
Tuesday Oct.13 , 13:30-14:10 PM
C103; Yifu Building
Dr. San Kiang work as an Director Process R/D for Bristol-Myers Squibb Company. Bristol-Myers Squibb
Company (BMS) is a global biopharmaceutical company. The Company is engaged in the discovery,
development, licensing, manufacturing, marketing, distribution and sale of biopharmaceutical products
on a global basis.
The role of particle engineering in designing pharmaceutical particles and
pharmaceutical composite material (PCM)
In solid dosage processes, the Active Pharmaceutical Ingredient (API) is generally blended with excipients
via wet or dry granulation. In some cases, direct blending is also possible. The size and shape of the API
particle can be modified in a way so that the formulation process and the drug product performance can
be optimized. Some common particle engineering approaches will be reviewed. A relatively new area of
particle engineering is to study how certain commonly used excipients can be combined with API in more
deliberate and controlled manner. This approach leads to the design of pharmaceutical composite
material (PCM). In the field of material science, there are many examples of composite materials. Two
well-known composite materials in everyday use are Concrete (stones and cement), and fiber reinforced
polymer. The composite approach combines two or more material in a specific way in order to produce a
material with different physical or chemical properties. PCM can be designed to solve some of the
common issues related to solid dosage production such as material flow, stability, release profile,
bioavailability, content uniformity and taste.
Ren Xiang Tan
C103, Yifu Building
Ren Xiang Tan is a professor in State Key Laboratory of Pharmaceutical
Biotechnology, Nanjing University. His research focuses upon natural products,
including the discovery methods, structural analysis, functional identification
and biosynthetic pathway in novel molecules from plants and microbes.
Published more than 300 papers in a broad range of journals such as Nat.
Commun., Proc. Natl. Acad. Sci. USA, J. Am. Chem. Soc., Angew. Chem. Int. Ed.,
Nat. Prod. Rep., Chem. Rev., et. al.
Mycosynthetic generation of new bioactive molecules
The impact of natural products on drug discovery pipelines keep kindling the interest in structurally
unpredictable low-molecular-weight biomolecules as an unforeseeable source of pharmaceutical leads. But
scientists are being more or less frustrated by re-isolations of described compounds from new organism
collections since countless natural products have been characterized since Serturner’s isolation of morphine
in 1806. To overcome this frustration and the limitation in the organism-based affordability and chemical
space expansion of minor new natural products, chemical synthesis has been performed to produce
complex molecules and natural product-like compounds with privileged scaffolds found in nature. To add
more skills to the existing arsenal of searching for new bioactive molecules, this talk will present the
mycosynthetic generation of unnatural hybrid molecules with biological function by taking the advantage of
evolutionally acquired fungal bioassembly lines. The key points and advantages of the mycosynthetic
approaches will be mentioned for enabling fungi to produce more novel alkaloids and polyketides as well as
the alkaloid-polyketide hybrid molecules.
……
Page 54
Zhixian Gao
Wednesday Oct.14 , 8:30-9:10 AM
C103; Yifu Building
Dr. Zhixian Gao works as the Director of Hygiene Monitoring
Center of PLA. Dr. Gao’s research focus on Bionsensing and Food
safety detection.
Development of rapid detection technology and
equipment for drinking water and food safety
With increasing requirements of drinking water safety under special conditions(such as more affairs
activities 、more emergencies 、more natural disasters、more international affairs，and so on ), How to
insure safety for drinking water and food ?we developed rapid screening ,monitoring technologies and risk
monitoring technological system of typical harmful factors in drinking water and food safety,established the
preparation technologies for molecularly imprinted polymers ,and then developed nanoparticle molecular
imprinted materials for small molecular chemical pollutant and macromolecular SE toxin. High specific
antibodys of typical pesticide and veterinary drug were prepared with selection of antibodies by ribosome
display library. MIPs-chemiluminescence sensor and MIP-SPR immunosensor used for the detection small
molecular chemical contaminant were fabricatied.we have established high-throughput 3-D agrose
immunochip technology for the multiple detection of mycotoxins and suspension array technology for the
detection of a variety of chemical contaminates and some pathogenic bacteria.A series of rapid detection
kits , strips based on cadmium telluride quantum dots and photonic crystal and it’s portable mini-sized
detectors were developed for drinking water and food safety.
Y. Martin Lo
C103, Yifu Building
Dr. Y. Martin Lo is the CEO & President of Biointellipro LLC. He serves as the first
Ambassador for the International Union of Food Science and Technology
(IUFoST) and received from White House the US Presidential Volunteer Service
Award in 2012. As a FDA-recognized Process Authority, Dr. Lo reviews and
certifies scheduled process for food companies to meet FDA/USDA regulations
on high risk acidified and low-acid canned foods. His area of expertise are food
Sciences, food processing safety, and biochemical engineering
Food safety and agriculture challenges and call for actions
Food safety has become an emerging issue globally, especially with interwoven food supply chain that not only
increases challenges but also adversely impacts human health. There is a dire need to establish a sound and
effective mechanism to reduce and minimize food safety hazards. While movements toward risk-based
management are evident in recent years, voids remain when it comes to foster environmentally benign,
sustainable agriculture. Additional to the guiding principles, this talk intends to address the practices and
challenges when assessing food safety risks on a global level, as well as how to integrate various tools from a
broad spectrum in order to attain safe and quality foods for the ever-increasing global population.
Page 55
Daijie Chen
Wednesday Oct.14 , 13:30-14:10 PM
C103; Yifu Building
Dr. Daijie Chen, Microbial Biochemical Pharmaceuticals (Shanghai
Institute of Pharmaceutical Industry.), Professor and doctoral
tutor, vice dean of pharmacy school, Shanghai Jiaotong University.
Four stage anaerobic technology
Two sets of 20T four stages anaerobic reactor system were established and were used to treat sewage from
spiramycin and etimicin production respectively. The results showed that the COD degration rate reached
90% and 95% which were much more higher than those in one stage anaerobic reactor system. Some other
parameters such as antibiotics degration rate, the time course of pH and activated sludge were also
investigated. After more than 6 months tests, we concluded that antibiotic production sewage could be
treated using such multistage-anaerobic technology more effectively to substitute one stage anaerobic
reactor system commonly used nowadays. In addition, the anaerobic degradation behaviors of spiramycin I
by sludge were investigated. Structural determination was then performed by nuclear magnetic resonance
and MS/MS spectra, and data indicated that hydroxylation and hydrolysis were main reactions during the
anaerobic digestion of spiramycin I. P-1 is the intermediate of hydroxylation, and P-2 is the intermediate of
hydrolysis. P-3 is the final product of the both reaction. This study revealed a hydroxylation and hydrolysis
mechanism of macrolide in anaerobic digestion.
Jing Wu
C103; Yifu Building
Dr. Jing Wu is a professor in Wuxi Medical School of Jiangnan University. Her
research interests are in Peptide drug molecular pharmacology and Replication
mechanism of DNA polymerase mismatch and cell damage
Study on the Preparation of Cyclodextrin
Cyclodextrins (CDs) are unique natural materials, which can bind hydrophobic molecules within their
internal cavities and carry them into aqueous solution. These advantageous properties have led to their
widespread use in many industrial fields. Cyclodextrin glycosyltransferases (EC 2.4.1.19, CGTases) could
catalyze the conversion of starch or starch derivatives into mixtures of -, -, and -cyclodextrins. Starch is
composed of D-glucose units linked together by -1,4-glucosidic linkages and -1,6-glucosidic linkages. Due
to CGTases’ incapability of hydrolyzing -1,6-glucosidic linkages, only a part of starch could be used to be
transformed into CDs. In order to improve the yield of starch conversion, a new synchronous bioconversion
process was applied, in which both the isoamylase and CGTase (- or - CGTase) were used simultaneously.
The yield of α- and γ-cyclodextrin was turned out to be 79.8% and 72.5% (w/w), respectively.
Y-H Percival Zhang
C103, Yifu Building
Percival Zhang is a professor in department of biological systems engineering at Virginia
Tech. He received his M.S. degree (1996) in biochemical engineering at East China
University of Science and Technology and PhD in chemical engineering and biochemistry
from Dartmouth College. He worked as a postdoctoral research associate at Dartmouth
College from 2004-2005. He His main research interest focuses on watershed science &
engineering and biomolecular engineering. He was deputy editor-in-chief in Energy
Science and Engineering in 2012. He serves as academic editor in PLoS One.
Out-of-the-box Solutions:
Making Synthetic Starch and Zero-Calorie Sweetener from Nonfood Biomass
The global food system is experiencing profound changes as a result of anthropegenic pressures.
Increasing population to 9 billion and food consumption per capita means that the global food demand
could increase by 70% by 2050. Food security is placing unprecedented demands on agriculture and natural
resources, such as water, land, fertilizers, and fossil fuels. The World Health Organization (WHO) and Food
and Agricultural Organization (FAO) recommend population nutrient intake goals for preventing diet-related
chronic diseases in terms of caloric uptake: total carbohydrate (55-75%), total fat (15-30%), and protein (1015%), where free sugars (i.e., monosaccharides and disaccharides) in the diet accounts for less than 10% of
carbohydrate intake. A properly balanced diet is important to lower health risks, such as obesity, type 2
diabetes, cardiovascular diseases, hypertension, cancer and so on.
……
Changsheng Zhang
Thursday Oct.15, 10:20-11:00 PM
C103, Yifu Building
Dr. Changsheng Zhang works as a professor in South China Sea
Institute of Oceanology, China. His research focus on discovery,
biosynthesis and metabolic engineering of marine microbial
natural products
Biosynthesis and Metabolic Engineering of Pharmaceutically Relevant Polycyclic
Natural Products from Marine-derived Actinomycetes
Marine-derived actinomycetes are emerging as the most important new sources for discoverying novel natural
product possessing excellent bioactivities with pharmaceutical significance. Our findings demonstrate that
marine-deirved actinomycetes are rich in taxonomical diversity and are prolific in producing bioactive
compounds, as exemplified by bisindole alkaloids with unprecedented spiro-rings, and several polycyclic
natural products with diverse bioactivities. Biosynthetic studies revealed different mechanisms to form
polycyclic rings. Xiamycin A is an indolosesquiterpene isolated from a marine-derived Streptomyces sp. SCSIO
02999. Genetic and biochemical experiments demonstrated that a cascade of oxidative cyclization reactions
were involved in the formation of the pentacyclic ring in xiamycin A. In contrast, a reductive cyclization
strategy was unveiled for the biosynthesis of ikarugamycin, a polycyclic tetramate macrolactam. The
biochemical mechanism to form an inner five-membered ring, catalyzed by the NAD(P)H-dehydrogenase IkaC,
was unveiled by labelling studies using stereospecifically deuterated NADPH cofactor and/or deuterium
oxide,mechanistcally analogous to a [1 + 6] Michael addition reaction. Intriguingly, spontaneous cyclizations
occured during the biosynthesis of polycyclic macrolactams heronamides, which also featuring double bond
migrations in the side chain. We also reported the production of structure variants of polycyclic naturla
products via metabolic engineering.
Canping Pan
C103, Yifu Building
Canping Pan is a Professor at China Agricultural University. His interested topic
are Pesticide residue, MRM analytical methods, food safety, pollutants,
environment, MRLs, GAP, dietary risk assessment, QSPR, Codex CLXs, CCMAS,
CCPR, and JMPR
Progress on Pesticide Residue Analytical Methodology
and International Risk Management
Pesticide/veterinary residue analysis is advancing very rapidly, which is required by monitoring market
samples in many countries for both domestic and international trading, regulatory enforcement, risk
assessment of dietary intakes, organic food verification, environmental research and so on. At the same
time, analytical methods for pesticide/veterinary determination are facing challenges with various demands,
for ins. rapid screening, on-site detection. For most methods, the key procedures of pesticide/veterinary
residue analysis are: cleanup of sample extracts in order to avoiding interferences from complicated
matrices, increasing powerful resolution and determination ability of analyzers.
Maximum Residue Limits (MRLs) are set by risk assessment bodies based on scientific reviews on residue
data of field trial (or monitoring) and toxicological findings of pesticides. MRLs differ among countries for
some crop/pesticide combinations, due to reasons such as: different GAP use patterns, residue data
variations as of climate, geographic zone or crop species; also there are other factors such as risk analysis
differentiations of: dietary data of national population, risk assessment model or policy, trade
considerations etc. The speaker will concentrate on the introduction and comparison of crop grouping
system for MRL setting used now in China and other countries/organizations, and on the representative
crops for residue data evaluations. Experimental data of field trials on Leaf vegetables and Brassicas may
give some examples for representative crop selection/extrapolation. Minor crop problems of herbs,
mushrooms, and bean sprouts products in China will also be addressed and discussed.
Page 56
Chair :Shangtian Yang
Afternoon
13:30-14:10
14:10-14:40
14:40-15:10
Title
S5-K1
S5- I1
S5- I2
15:10-15:20
Affiliation
The role of particle engineering in
Bristol Myers
designing pharmaceutical particles and San Kiang
Squibb
pharmaceutical composite material (E0179)
The Secondary Drying and the Fate of
Organic Solvents for Spray Dried
Dispersion Drug Product (E0215)
Daniel
Hsieh
Selective DDRs Inhibitors as Novel
Therapeutic Agents for Human Cancers and Ke Ding
Pulmonary Fibrosis (E0105)
Bristol-Myers
Squibb
Company
Guangzhou
Institute of
Biomedicine
and Health,
CAS
Coffee break
Mycosynthetic generation of new bioactive Renxiang
molecules (E0100)
Tan
15:20-16:00
S5-K2
16:00-16:30
S5-I3
A material sparing predictive approach
employing dry coating for enabling
continuous tablet manufacturing (E0182)
S5-I4
Interrogation of Streptomyces avermitilis
for efficient production of avermectins
(E0099)
16:30-17:00
Name
Rajesh
Dave
Lixin
Zhang
Nanjing
University
New Jersey
Institute of
Technology
Institute of
Microbiology
, CAS
Chair : Daniel Hsieh
Morning
8:30-9:10
9:10-9:40
Title
S5-K3
S5- I5
Name
Development of rapid detection technology
Zhixian
and equipment for drinking water and food
Gao
safety (E0564)
Affiliation
Tianjin Institute
of Health and
Environment
Medicine
Anthocyanins can exert preventive effect
China
against the diverse acrylamide toxicity Fang Chen Agricultural
(E0115)
University
Page 57
9:40-10:10
S5-I6
10:10-10:20
Low-cost Microfluidic Devices for Food
Peng Zuo
Safety Detection (E0111)
ECUST
Coffee break
S5-K4
Biointellipro
Food safety and agriculture challenges and Y. Martin
LLC University
call for actions (E0139)
Lo
of Maryland
11:00-11:30
S5-I7
Research and application of aroma blending Zuobing
and control release (E0137)
Xiao
11:30-12:00
S5-I8
10:20-11:00
Discovery of Cycloxaprid as cisNeonicotinoids (E0148)
Shanghai
Institute of
Technology
Zhong Li
ECUST
Title
Name
Affiliation
S5-K5
Four stage anaerobic technology (E0112)
Daijie
Chen
Shanghai
Institute of
Pharmaceutical
Industry
14:10-14:40
S5-I9
Design of a pH responsive “Smart”
biopolymer-blend hydrogel for
encapsulation and controlled release of
anthocyanins (E0321)
14:40-15:10
S5-I10
Imidazolium-based ionic liquids: Novel
reaction media for the chemical synthesis
of peptides (E0324)
12:00-13:30
Chair :Yingjin Yuan
Afternoon
13:30-14:10
15:10-15:20
Ming
Chen
University of
Bonn
Jing Wu
Jiangnan
University
Coffee break
15:20-16:00
S5-K6
16:00-16:30
S5-I11
Page 58
Gonul The Ohio State
Kaletunc
University
Study on the Preparation of Cyclodextrin
(E0096)
Technology trends in process development
WuXi AppTec
and manufacturing in biopharmaceutical Yuan Wen Biopharmaceuti
industry (E0162)
cals
Chair :Bang-Ce Ye
Morning
8:30-9:10
9:10-9:40
9:40-10:10
Title
Name
Affiliation
S5-K7
Out-of-the-box Solutions: Making
Y-H
Synthetic Starch and Zero-Calorie
Percival
Sweetener from Nonfood Biomass (E0138) Zhang
Virginia Tech
S5-I12
Intelligent Microbial Heat Regulating
Engine for Improving the Thermotolerance and Efficiency of
Biotransformation (E0097)
Chun Li
Beijing
Institute of
Technology
S5-I13
Anti-solvent Crystallization of
Erythromycin Ethylsuccinate in the
Presence of a Liquid-Liquid Phase
Separation (E0297)
Xiang
Li
Tianjin
University
Chang
sheng
Zhang
South China
Sea Institute
of
Oceanology
10:10-10:20
Coffee break
10:20-11:00
S5-K8
Biosynthesis and Metabolic Engineering
of Pharmaceutically Relevant Polycyclic
Natural Products from Marine-derived
Actinomycetes (E0098)
11:00-11:30
S5-I14
Tailor-designed biocatalyst towards
bioproducts
Dongzhi
Wei
ECUST
S5-I15
Rational Engineering of Bacteria and Yeast
for Overproduction of Isoprenoids (E0101)
Kang
Zhou
National
University of
Singapore
Name
Affiliation
11:30-12:00
12:00-13:30
Chair :Chun Li
Afternoon
Title
13:30-14:10
S5-K9
Progress on Pesticide Residue Analytical
Methodology and International Risk
Management (E0147)
14:10-14:50
S5-K10
Research progress in the development and
Xichang
quallity evaluation of freshwater fish
Wang
emulsions
College of
Canping Science, China
Pan
Agricultural
University
Shanghai
Ocean
University
Page 59
15:00-15:30
15:30-16:00
16:00-16:30
S5-I16
3D fluorescent cell-based high-throughput
Shangtian The Ohio State
screening (HTS) for cytotoxicity assay and
Yang
University
drug discovery (E0356)
S5-I17
Qingdao
Institute of
Bioenergy and
Zhijie Sun
Bioprocess
Technology,
CAS
S5-I18
Synergistic benefits of Chinese luzhouflavor-liquor solid state fermentation
process (CLSSF) on hydrothermal
pretreatment of rice husks (E0358)
DNA-stabilized nanozyme and its
application on colorimetric assay
（E0603）
Page 60
Wei Li
Tianjin
University
Symposium 6- Green Technology (M1004, Yifu Building)
Symposium 6- Green Technology
Chairs: Xuhong Guo, [email protected]; Biaohua Chen, [email protected]
Winston Ho, [email protected]; Giulio C. Sarti, [email protected].
Featured Speakers
Yushan Yan
M1004, Yifu Building
Yushan Yan is the Distinguished Engineering Professor in the Department of
Chemical and Biomolecular Engineering and the Associate Dean for Research and
Entrepreneurship for the College of Engineering at the University of Delaware. He
received his B.S. in Chemical Physics from the University of Science and Technology
of China in 1988, and Ph.D. in Chemical Engineering from the California Institute of
Technology in 1997. He studied heterogeneous catalysis at the Dalian Institute of
Chemical Physics of the Chinese Academy of Sciences from 1988 to 1992. He
worked for AlliedSignal Inc. as Senior Staff Engineer and Project Leader for two
years (1996-1998) before beginning his academic career at the University of
California Riverside.
Toward a distributed renewable electrochemmical energy and mobility system:
Polymer electrolytes and electrocatalysis
One of the grand challenges facing humanity today is the development of an alternative energy system
that is safe, clean, and sustainable and where combustion of fossil fuels no longer dominates. A distributed
renewable electrochemical energy and mobility system (DREEMS) could meet this challenge. At the
foundation of this new energy system are a number of electrochemical devices including fuel cells,
electrolyzers, and flow batteries. For all these devices polymer electrolytes and electrocatalysis play a
critical role in controlling their performance and cost, and thus their commercial viability. In this
presentation, I will focus on our recent work on hydroxide exchange membrane fuel cells which can work
with non-precious metal catalysts and inexpensive polymer electrolytes, and thus can be economically
viable. More specifically I will show how we have discovered a super-stable organic cation, why hydrogen
oxidation reactions are slower in base than in acid, and what we have developed as the most active nonprecious metal hydrogen oxidation reaction catalysts.
Page 61
Benjamin Chu
Benjamin Chu is a Distinguished Professor at the State University of New York in
Stony Brook, New York; his research interests are in Physical Chemistry, Polymer
Physics and Materials Science & Engineering.. He is one of the founders of
Liquidity Corporation in California and is an Honorary Member of the Society of
Polymer Science, Japan.
Application of Green Technology to Fibrous Separation
Membranes for Water Purification
The ultra-thin cellulose nanofibers have been isolated by using a variety of methods. Among them, the
combined TEMPO oxidation/mechanical treatment has been a very successful way to fabricate nanofibers
with cross-sections of a few nanometers and a high degree of crystallinity. Non-woven nanofibrous
scaffolds have unique properties, including interconnected pores, a very large surface-to-volume ratio, and
a high capacity for surface modifications. The hierarchical fibrous structure with fibers of different crosssections, together with the use of directed water channels in the barrier layer and surface functionalization,
permits us to fabricate high throughput separation media. In this presentation, we discuss the fabrication
and characterization of those nanofibers and their applications to micro-, ultra-, and nano-filtration.
Kamalesh Sirkar
amalesh K. Sirkar, PhD, is a Distinguished Professor of Chemical Engineering
K
and the Foundation Professor in Membrane Separations at New Jersey Institute
of Technology (NJIT). He is an internationally renowned expert in membrane
separation technologies. He is the inventor of the commercialized membranebased solvent extraction technology for which Hoechst Celanese received
Honorable Mention in the 1991 Kirkpatrick Award. He has pioneered among
others the notion of microporous membranes as membrane contactors of two
immiscible fluid phases as well as the contained liquid membrane. Sirkar was a
professor of Chemical Engineering at IIT, Kanpur as well as at Stevens Institute
of Technology.
Polyamidoamine-facilitated Poly (ethylene glycol)/Ionic Liquid based Pressure
Swing Membrane Absorption Process for CO2 Removal from Shifted Syngas
A novel cyclic 5-valve pressure swing membrane absorption (PSMAB) process is being developed for
CO2 removal from lower-temperature shifted syngas at ~ 100oC in hollow-fiber membrane contactors using
ionic liquid (IL) absorbent, 1-butyl-3-methyl-imidazolium dicyanamide ([bmim][DCA]). Separation
performance is considerably enhanced by adding nonvolatile polyamidoamine (PAMAM) dendrimer
Generation 0 to the IL at higher temperatures for a 40% CO2, 60% He (surrogate for H2) feed. Absorption
performance in the cyclic process depends on selective sorption and other absorbent properties especially
viscosity and hollow-fiber membrane contactor module design employing microporous hydrophobized
polyether ether ketone (PEEK) hollow fiber-based membranes. Equilibrium CO2 solubility and CO2-He
selectivity for IL, [bmim][DCA], has been compared with those for poly(ethylene glycol) (PEG) 400 which
yields improved equilibrium CO2-He selectivity and CO2 absorption with/without 20 wt% PAMAM dendrimer
over the temperature range 50-100oC. The PSMAB process separation performance has been explored
using PEG 400-based absorbent in two hollow-fiber membrane contactor modules with improved designs in
series at temperatures up to 100oC and feed-gas pressures up to 1724 kPag (250 psig).
Page 62
Zhigang Lei
Lei Zhigang is now a Professor in State Key Laboratory of Chemical Resource
Engineering (BUCT, China). His current research interests include process
intensification in chemical engineering and its molecular thermodynamics. He
has contributed to more than 40 papers (indexed by SCI) as the first author or
corresponding author in international journals such as Chemical Reviews, AIChE
J., and Chemical Engineering Science. He has received one National Science and
Technology Progress Award (second rank), two ministry-level Science and
Technology Progress Awards and one ministry-level Natural Science Award (first
rank).
Structured Catalysts and Reactors: A Green Chemical Technology
Structured catalysts and reactors have been becoming significant green chemical technologies in gassolid and gas-liquid-solid reactions due to the unique advantages they offer such as controlling
hydrodynamics, transport phenomena and reaction kinetics, so that energy efficiency would be improved
and generation of hazardous substances would be reduced or eliminated. In this work, for gas-solid reaction
with structured catalysts, we focus on selective catalytic reduction (SCR) for NO (nitrogen oxide) removal,
and try to identify the relationship between the internals of SCR system and mixing performance for
controlling ammonia (NH3) slip (<5 ppm). On the other hand, for gas-liquid-solid reaction with structured
catalysts, the transfer and reaction performances for the alkylation of benzene with propylene to produce
cumene over monolith catalysts as well as structured catalytic packings were investigated by means of the
combination of experiments and computational fluid dynamics (CFDs) .
Sumith Wickramasinghe
Wickramasinghe joined the Department of Chemical Engineering at the
University of Arkansas in 2011 where he holds the Ross E Martin Chair in
Emerging Technologies and leads the Membrane, Science, Engineering and
Technology Center (MAST). Prof Wickramasinghe has published over 100 peer
reviewed journal articles, several book chapters and is co-editor of a book on
responsive membrane and materials. He is active in AIChE and was the Meeting
Program Chair of the 2014 Annual Meeting in San Francisco. He has also served
on the Board of Directors of the North American Membrane Society.
Catalytic Membranes for Production of Biofuels and Chemicals
Catalytically active membranes may be used to catalyze a reaction and separate the product in one step
leading to significant process intensification. Here we focus on biomass hydrolysis and dehydration for
production of biofuels and chemical intermediates. Ceramic membranes have been functionalized by
growing poly(styrene sulfonic acid) (PSSA) chains as well as polymeric ionic liquid (PIL) chains from the
surface of ceramic membranes. A UV initiator based on a benzoin ether derivative and 2-bromobutyryl
bromide (ATRP initiator) were immobilized on the ceramic membrane surface. Next ATRP of sodium 4styrenesulfonate was conducted followed by UV initiated free radical polymerization of 1-vinylimidazole(VI).
The density of the PSSA and PIL chains was varied by varying the incubation times of the two different
initiators. Modified membranes were characterized using X-ray Photoelectron Spectroscopy, Infrared
Spectroscopy and Scanning Electron Microscopy.A membrane reactor was designed and tested using feed
streams consisting of cellulose and hemicellulose and glucose in water and water/ionic liquid,
acetonitrile/ionic liquid, dimethylacetamide/ionic liquid, -valerolactrone/ionic liquid mixtures. Reduced
sugars as well as chemical intermediates such as hydroxymethylfurfural, furfural and levulinic acid were
collected in the permeate. We have tuned the membrane pore structure in order to maximize recovery of
the desired products in the permeate. Our results indicate the feasibility of designing a catalytic membrane
reactor for production of biofuels and chemicals.
Page 63
Weihong Zhu
Prof. Weihong Zhu is a professor of East China University of Science &
Technology (ECUST), and a deputy director in 2006. He has published over 150
SCI papers in international journals. He has received several awards, such as
Oriental Scholar (2009) and NSFC for Distinguished Young Scholars (2013). His
current research interests are focused on functional chromophores, including
fluorescent sensors, photochromism, and metal free solar cell sensitizers.
Insight into D−A−π−A featured sensitizers: a reliable route to
highly efficient and stable dye-sensitized solar cells
The practical application of DSSCs requires further improvements in the power conversion efficiency and
long term stability. Recently, we have systematically studied a novel concept of D−A−π−A model for the
molecular engineering of organic photosensitizers. We highlights recent advance in the D−A−π−A based
photosensitizers, specifically focusing on the mechanism of efficiency and stability enhancements. Also we
take insight into the additional acceptor as well as the trade-off of long wavelength response. The basic
principles are involved in the molecular engineering of efficient D−A−π−A sensitizers, providing a clear road
map how to rationally extend the response wavelength, enhance molecular extinction coefficients, and step
by step optimize photovoltaic efficiency.
Page 64
Tuesday Oct.13 (M1004, Yifu Building)
Chair : Winston S. Ho
Afternoon
13:3014:10
S6Keynote 1
S6-
14:1014:40
Invited
talk 1
14:4015:10
S6- I2
Title
Name
Affiliation
Can we predict gas solubility and
permeability in glassy polymeric
membranes? (F0033)
Giulio
Sarti
University of
Bologna
Advances in Developing Iptycenecontaining Polymer Membranes for
Gas Separation (F0227)
Ruilan
Guo
University of
Notre Dame
Olefin/Paraffin Separations by
Membranes: An Industrial Perspective
(F0326)
15:1015:20
15:2016:00
16:0016:30
Xiaotong
(Tony)
Wei
SABIC
Coffee break
S6-K2
Design and synthesis of synergic multimetallic nanocatalysts towards highly
active and stable catalysts for oxidation
and hydrogenation reactions (C0455)
S6-I3
Recent Development of Thin-sheet
Molecular Sieve Membranes for Air
Dehumification and Conditioning
(F0510)
Binghui
Chen
Wei Liu
Xiamen
University
Pacific
Northwest
National Lab
Wednesday Oct.14 (M1004, Yifu Building)
Chair : Xuhong Guo, Giulio C. Sarti
Morning
Title
8:30-9:10
S6-K3
9:10-9:40
S6-I4
9:40-10:10
10:1010:20
S6-I5
Toward a distributed renewable
electrochemmical energy and mobility
system: Polymer electrolytes and
electrocatalysis (F0153)
Designing polymer-matrix
nanocomposite membranes for specific
applications in water treatment and
reuse (F0236)
Recovery and separation of Europium
and Yttrium ions by using supported
liquid membrane with strip dispersion
(F0354)
Coffee break
Name
Affiliation
Yushan
Yan
University of
Delaware
Newark
Baolin
Deng
University of
Missouri
Da-Ming
Wang
National
Taiwan
University
Page 65
Chair : Xuhong Guo, Giulio C. Sarti
Morning
Title
10:20-
S6-
11:00
K4
11:0011:30
S6-I6
Name
Affiliation
Effective removal of nitrogen-containing
waste gases from chemical industry by the
zeolite catalysts
Runduo
Zhang
Beijing
University of
Chemical
Technology
Graphene Oxide Membranes for Fouling
Control in Pressure Retarded Osmosis
(F0241)
Baoxia Mi
University of
California
11:30-
13:30
Chair : Biaohua Chen, Wei Liu
Title
Name
Affiliation
S6K5
Application of Green Technology to
Fibrous Separation Membranes for Water
Purification (F0035)
Benjamin
Chu
Stony Brook
University
S6-I7
Impregnated Membranes for Water
Purification by Forward Osmosis (F0228)
Haiqing
Lin
SUNY at
Buffalo
Afternoon
13:3014:10
14:1014:40
14:40-
Coffee break
14:50
14:5015:30
15:3016:00
Page 66
S6K6
The oxidative removal of typical volatile
organic compounds over porous catalysts
Hongxing
Dai
Beijing
University of
Technology
S6-I8
Controlled assembly of polymers in water:
towards soft nanoparticles for potential
applications in biology and environment
Junyou
Wang
Wageningen
University
Thursday Oct.15 (M1004, Yifu Building)
Chair : Haiqing Lin
Morning
Title
8:30-9:10
S6-K7
9:10-9:40
S6-I9
Polyamidoamine-facilitated Poly (ethylene
glycol)/Ionic Liquid based Pressure Swing Kamalesh
Membrane Absorption Process for CO2
Sirkar
Removal from Shifted Syngas (F0295)
Robust CO2 separation membrane
composed of double network gel
Hideto
containing amino acid ionic liquid
Matsuyama
(A0333)
9:40-9:50
9:50-
11:00
Affiliation
New Jersey
Institute of
Technology
Kobe
University
Coffee break
S6-K8
10:30
10:30-
Name
S6-I10
Structured Catalysts and Reactors: A
Green Chemical Technology (F0498)
Zhigang
Lei
Bimodal Comb Block Polyolefins by
Serial Reactors
Andy Tsou
(C0102)
11:00-
Beijing
University of
Chemical
Technology
ExxonMobil
Chemical
Company
13:30
Chair : Xiaotong (Tony) Wei
Afternoon
Title
Name
Affiliation
13:30S6-K9
Catalytic Membranes for Production of
Biofuels and Chemicals (F0252)
Sumith
Wickramasinghe
University of
Arkansas
S6-I11
Osmotic Membrane Bioreactors for Water
Reclamation and Energy Recovery
Chuyang Y.
Tang
The
University of
Hong Kong
Insight into D−A−π−A featured sensitizers:
a reliable route to highly efficient and
S6-K10
stable dye-sensitized solar cells
Weihong
Zhu
ECUST
Graphene oxide composite membranes for
pervaporation
Wei Song
Hung
Chung Yuan
University
14:10
14:1014:40
14:40-
Coffee break
14:50
14:5015:30
15:3016:00
S6-I12
Page 67
Symposium 7- Management Science for Research and Development （M806, Yifu Building)
Symposium 7- Management Science for Research and Development
--------How to make R&D effective and efficient
Chairs: Jane Li, [email protected]; Zaiku Xie, [email protected];
Tieju Ma, [email protected]
Featured Speakers
Willibrord A. Groten Wednesday Oct.14, 13:30-14:30 PM M806, Yifu Building
Dr. Will Groten is currently Vice President of Research & Development for
CB&I, the world’s most complete energy infrastructure company. Additionally,
he holds titles of Managing Director of CDTech and President of Chemical
Research & Licensing LLC, now wholly owned subsidiaries of the Technology
group of CB&I since 2011. In his current capacity he oversees R&D, technology
evaluations, intellectual property and the fabrication of proprietary CDTech
products, for CB&I.
In prior roles, Dr. Groten held numerous R&D roles leading to the
development of new process technologies for CDTech including that of
Director of Technology. He also served for several years with Criterion
Catalysts & Technologies, L.P as VP Process Technology & Projects for
Criterion, overseeing their clean fuels technology programs.
Dr. Groten earned a Bachelor of Science & Engineering in Fuels and Materials Engineering at the Royal Military
College of Canada in 1982 and served in the Canadian Armed Forces as an officer and Search & Rescue pilot. He
retired from military service with the rank of Captain in 1987 and went on to earn his PhD from Queen’s
University, Kingston, Ontario in the field of catalysis and reaction engineering. He is author or co-author on a
dozen papers and named inventor on two dozen patents. Over the course of his engineering career, he has been
involved in the successful development and launch of more than 20 new, innovative process technologies into
the refining and petrochemical industry.
Innovation and culture in the engineering firm
It is fitting that the subject of this symposium be now included in the Sino-US Chemical Engineering
Conference. Innovation, although an often overused buzz word, is central to economic growth and wellbeing of society in general. For businesses, it is an essential ingredient in a sustainable business model.
The fundamental driver of the process of innovation is, of course, the associated human factor. Thus,
managing the process of innovation in the field of Chemical Engineering will necessarily require both “art”
and “science”. The innovation process does not occur in a void but rather occurs in a particular context.
Broadly speaking, this can include the internal organization of a company, its culture, and the external
world environment, which typically includes a marketplace populated by competitors all aimed to deliver
their innovative technology solutions to solve and address a customer’s problems and needs. Using
CB&I’s history of innovation in the chemical process industry, a generic framework of the innovation
process will be presented, capturing specific experiences, and address a few of the unique challenges
found along the way. This presentation is meant to be thought provoking and set the stage for a
successful first R&D Management Science Symposium.
Page 68
Page 1
Symposium 7- Management Science for Research and Development (M806, Yifu Building)
Medhat Tannous
M806, Yifu Building
Dr. Medhat Tannous is currently Sr. Director for Regional R&D. He is
responsible for strategic development and direction of UOP regional R&D
programs, including: providing technology support to the UOP regional General
Managers and developing strategic and operational plans for regional R&D
customer engagements. He also provides oversight to regional labs in India and
Saudi Arabia. Prior to that, Medhat was R&D Director for the Middle East where
he established collaborative development projects and activities with key
customers and Universities in the area. Medhat joined UOP in 1985. In the
past 30 years, he held different technical and managerial positions in R&D,
Manufacturing Technology and Catalyst business. Medhat has a Ph.D. in
Chemical Engineering and an MBA. He is also a Honeywell certified Six Sigma
Master Black Belt and Six Sigma Lean expert. Medhat is the author of 4 patents
and several publications.
Enhancing the effectiveness of R&D
The goal of every R&D department is to develop new technologies to support business growth. For over one
hundred years, UOP has been providing the oil, gas and petrochemicals industries with groundbreaking
technical innovations resulting from its pioneering research work in catalysis, separations and process
design. The key factors for a successful R&D operation are acquiring and retaining talents, providing
researchers with the tools and capabilities that are necessary to perform cutting edge science, and aligning
research programs with business objectives that are based on customer needs, market trends, regulations
and competitive analysis. Needless to mention that having the best talents, resources and capabilities alone
will not enhance the effectiveness of R&D unless disciplined, integrated and cross functional work processes
are strictly deployed. Among such work processes are strategic planning, technology road mapping, voice of
the customer, portfolio management, open innovation and technology delivery process. Such work
processes, enabled with the six sigma methodology and tools are key to an efficient and effective R&D
operation designed to enhance the growth of the business and maximize the return on R&D investment.
Examples of such work processes and tools will also be described.
Page 69
Page 1
Special lecture Wednesday Oct.14, 11:00-12:00 AM
M806, Yifu Building
Sergei Ikovenko, Dr.-Eng., Ph.D., P.E.,
Dr. Sergei Ikovenko is one of leading consultants in innovation technology of design. He is
the President of the International TRIZ Association and is an adjunct professor at
Massachusetts Institute of Technology (Cambridge, USA).
He has conducted more than 900 courses on innovation and TRIZ (Theory for Inventive
Problem Solving) topics for Fortune 500 companies worldwide. Dr. Ikovenko was the
primary instructor on TRIZ at Procter & Gamble,Mitsubishi Research Institute, Samsung,
Intel, Siemens, General Electric Global Research, Hyundai Motor Company, and other
companies.
Dr.Ikovenko holds two doctorate degrees –in Industrial Engineering and in Environmental Engineering and
Sciences, and a Master degree in Patent Law. He is the author of more than 100 publications, and 104 patents in
various engineering fields.
Innovative Technology of Design – TRIZ
Sergei Ikovenko
International TRIZ Association and Massachusetts Institute of Technology, Cambridge, MA, USA, 02139
[email protected]
TRIZ (a Russian acronym for Theory for Inventive Problem Solving) is a powerful suite of tools and methodologies
for improving existing products (such as by reducing cost, improving functionality, or both) and for developing new
generation products.
In the conventional wisdom, innovation is an inefficient and ineffective process. Limited resources, psychological
inertia, limited breadth of technical knowledge, information overload, tendency to compromise, inability to
objectively forecast the technological future and, finally, choosing the wrong problem to solve have all been cited
as reasons that prevent innovation. Because of these so called "innovation killers", most innovations are
incremental at best and are aimed at improving already existing products.
TRIZ bypasses typical innovation killers by using:
Analytical tools that identify the right problems
Objective and statistically proven Trends of Evolution for Engineering Systems
Problem-solving tools that solve engineering problems without compromise, often leading to breakthrough
solutions
The power of TRIZ lies in its ability to make innovation a predictable, and, therefore, risk-averse process by
applying a scientific and methodological framework to solving engineering problems. Importantly, TRIZ is not a
substitute for intelligence. Rather, it can be viewed as a multiplication constant to intelligence that serves as a
stimulator, an optimizer, and a filter to make the innovation process significantly more productive, efficient, and
effective.
Page 70
Symposium 7- Management Science for Research and Development （M806, Yifu Building)
Chair : Jane Li
Morning
Title
08:30-
S7-K1
09:30
09:30S7- I1
10:10
Name
Affiliation
Enhancing the Effectiveness of Medhat
R&D
TANNOUS
Honeywell/U
Accelerating Innovation with
integrated Six sigma
implementation
Selena CHU
Asia Pacific
R&D, Dow
Chemical
Yongwei SUN
National
Institute of
low carbon
and
Clean
Energy
OP
Coffee break
10:00-10:20
Chair : Jane Li
10:20-11:00
S7- I2
S711:00-12:00
Special
Accelerating Innovation for
Chemical Engineering R&D
projects by Design for Six Sigma
Innovative Technology of Design – Seigei
TRIZ
IKOVENKO
Lecture
12:00-13:30
International
TRIZ
Association and
Massachusetts
Institute of
Technology
Chair : Zaiku Xie
Afternoon
13:3014:30
14:3015:10
15:10-15:20
S7-K2
S7-I3
Title
Name
Affiliation
The Science (and Art) of
Innovation at CB&I
Willibrord
GROTEN
CB&I
Some thoughts for improving the
efficiency of an industrial research Xiangchen
institute and their application FANG
results
Fushun
Research
Institute of
Petroleum
and
Petrochemica
ls, SINOPEC
Coffee break
Page 71
Chair : Tieju Ma
15:20-16:00
S7-I4
Mission and exploration of
Research Center of Meso-science
(COM) in R&D of process
engineering
Ning
YANG
Institute of
Process
Engineering,
CAS
Yi JIANG
Corning, NY
Best Practice in Implementing
Safety Measures in Fine &
16:00-16:40
S7-I5
Specialty Chemical
Manufacturing
16:40-17:20
S7-I6
R & D program strategy and
Bing
decision
ZHANG
Note: S ~ Symposium K~ Keynote I~ Invited talk.
GE China
Technology
Center
Symposium
8- Materials
andand
Nanoand
Technology
(C208)
Symposium
11Petrochemicals
Fine
Chemicals
Symposium
11- Petrochemicals
Fine
Chemicals
(M104)
Symposium 8- Materials and Nano Technology
Chairs: Chunzhong Li, [email protected]; Jieshan Qiu, [email protected]
James Lee, [email protected]; Liming Dai, [email protected]
Featured Speakers
Dongyuan Zhao
C208, Yifu Building
Dr. Dongyuan Zhao was born in Northeastern of China, he received
B.S. (1984), M.S. (1987) and PhD (1990) from Jilin University. He was
a post-doctoral fellow in the Weizmann Institute of Science (1993–
94), University of Houston (1995–96), University of California at
Santa Barbara (1996–98). Now he is a Professor (Cheung Kong and
HaoQing Professorship) in the Department of Chemistry at Fudan
University, Currently, he is a fragmental professor in Department of
Chemical Engineering, Monash University. He was a member of
Chinese Academy of Sciences and The World Academy of Science
(TWAS), Council Member of IZA, President of International
Mesostructured Materials Association (IMMA). He has received
many prizes from China and international awards such as CRN Rao
Award from India Chemical Research Society (2013); Muetterties
Memory Award (2012); The Ho Leung Ho Lee Award (2009), TWAS
Prize (2008); IMMS Award (2008); DuPond Award (2005). He is now
appointed as senior Editor of ACS Central Science. He was Editor-inChief of Journal of Materials Chemistry, and co-editor of Journal of
Colloid and Interface Science before. He published more than 550
peer-review papers, 40 patents and is listed as one of highly cited
researchers in ISI (Total citation ~ 50,000, h index 105). His research
interests mainly include designed synthesis, assembly, structure and
application of ordered mesoporous materials.
http://www.mesogroup.fudan.edu.cn
Interfacial Assembly and Engineering of Ordered Functional Mesoporous
Materials for Applications
With recent progresses made in modern nanoscience and nanotechnology, ordered mesoporous materials
have been one of the hottest research topics in scientific community spanned chemistry, materials science,
physics and biology. The construction of mesoporous materials is mainly concerned with building monodispersed
mesosized (2-50 nm) pore voids and arranging them in a long-range ordered array. Generally, two kinds of
templates are used to produce the mesopores: supramolecular aggregates such as surfactant micelle arrays, and
rigid preformed solids such as ordered mesoporous silica, carbon, and colloidal crystals. Noticeably, besides the
templates, the interface also plays a central role in the synthetic process, because it provides a rich and crucial
space for the assembly and construction of mesostructures. Generally, two kinds of interfaces involve in the
synthetic system. The first one is at between surfactant templates and guest species, which has been extensively
investigated. Another important interface is the two-phase (solid, liquid and gas) one, including liquid-solid, gasliquid, liquid-liquid, gas-solid, and solid-solid interface, which has been well developed for the synthesis of
ordered mesoporous materials. Compared with the one phase synthesis referring to homogeneous nucleation
and growth, the introduction of a two-phase interface in the system can change the growth behaviors of
mesoporous materials and lead to the formation of molding or multifunctional mesoporous materials.
Page 72
Page 1
Symposium
8- Materials
andand
Nanoand
Technology
(C208)
Symposium
11Petrochemicals
Fine
Chemicals
Symposium
11- Petrochemicals
Fine
Chemicals
(M104)
Zhonglin Wang
C208, Yifu Building
Dr. Zhong Lin (ZL) Wang is the Hightower Chair in Materials Science and
Engineering, Regents'Professor, College of Engineering Distinguished
Professor and Director, Center for Nanostructure Characterization, at
Georgia Tech. Dr. Wang has made original and innovative contributions to
the synthesis, discovery, characterization and understanding of fundamental
physical properties of oxide nanobelts and nanowires, as well as applications
of nanowires in energy sciences, electronics,optoelectronics and biological
science. He invented and pioneered the in-situ technique for measuring the
mechanical and electrical properties of a single nanotube/nanowire inside a
transmission electron microscope. Dr. Wang is a pioneer and world leader in
nanoscience and nanotechnology for his outstanding creativity and
productivity.
Dr. Wang was elected as a foreign member of the Chinese Academy of Sciences in 2009, member of
European Academy of Sciences in 2002, fellow of American Physical Society in 2005, fellow of AAAS in 2006,
fellow of Materials Research Society in 2008, fellow of Microscopy Society of America in 2010. He is an
honorable professor of over 10 universities in China and Europe. He received 1999 Burton Medal from
Microscopy Society of America, 2001 S.T. Li prize for Outstanding Contribution in Nanoscience and
Nanotechnology, the 2000 and 2005 Georgia Tech Outstanding Faculty Research Author Awards, Sigma Xi
2005 sustain research awards, Sigma Xi 1998 and 2002 best paper awards, and the 2009 Purdy Award from
American Ceramic Society. His breakthrough researches in the last 15 years have been featured by over 50
media world wide including CNN, BBC, FOX News, New York Times, Washington Post, NPR radio, Time
Magazine, National Geography Magazine, Discovery Magazine, New Scientists, and Scientific America.
Nanogenerators for self-powered systems and piezotronics for smart devices
Developing wireless nanodevices and nanosystems is of critical importance for sensing, medical science,
environmental/infrastructure monitoring, defense technology and even personal electronics. It is highly desirable
for wireless devices to be self-powered without using battery. Nanogenerators (NGs) have been developed based
on piezoelectric, trioboelectric and pyroelectric effects, aiming at building self-sufficient power sources for
mico/nano-systems. The output of the nanogenerators now is high enough to drive a wireless sensor system and
charge a battery for a cell phone, and they are becoming a vital technology for sustainable, independent and
maintenance free operation of micro/nano-systems and mobile/portable electronics. An energy conversion
efficiency of 55% and an output power density of 500 W/m2 have been demonstrated. This technology is now
not only capable of driving portable electronics, but also has the potential for harvesting wind and ocean wave
energy for large-scale power application. This talk will focus on the updated progress in NGs.
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Stuart Cooper
C208, Yifu Building
Stuart Cooper currently is a professor of department of chemical and biomolecular
engineering from Ohio State University, he earned his PhD degree at Princeton
University (1967). Prof. Stuart Cooper won AIChE Founders Award for Outstanding
Contributions to the Field of Chemical Engineering (2014) and Chemistry of
Thermoplastic Elastomers Award from American Chemical Society‘s Rubber Division
(2013)，and National Academy of Engineering (2011). His main research interests
focus on polymer science and engineering, properties of polyurethanes and Ionomers,
polyurethane biomaterials, blood-material interactions and tissue engineering.
Polyurethanes and Ionomers: High Performance Elastomers and Plastics Self
Reinforced with Nanoscale Structure
Elastomeric (AB)n-type segmented copolymers are systems which exhibit properties similar to crosslinked
rubbers, but are thermoplastic and may therefore be processed by conventional molding and extrusion
techniques. At use temperature, one component is viscous or rubbery (soft segment), while the second
block is glassy or semi-crystalline in nature (hard segment). Typically, polyurethane segmented elastomers
exhibit phase separation on the scale of nanometers with the hard segment domains acting as physical
crosslinks and/or filler particles for the flexible soft segment matrix. Ionomers are copolymers where a low
concentration ionic monomer is polymerized within a hydrophobic backbone. In the solid state the ionic
species aggregate into nanoscale reinforcing domains which impart unique physical properties to these
materials
Changsheng Liu
C208, Yifu Building
Dr. Changsheng Liu is currently vice president of East China University of Science
and Technology and a director of Engineering Research Center of Biomedical
Materials under Ministry of Education. Dr Liu has devoted for decades into the
fundamental and application research of biological materials and has obtained a
series of outstanding achievements in the field of bone regeneration. He won an
international Fellow of Biomaterials Science and Engineering (2012).
Dr Liu has a Ph.D. in Chemical Engineering in East China University of Science and
Technology in 1996. He has visited University of Pennsylvania, Philadelphia, USA as
a visiting professor from March to Sept, 2005. He has successfully applied 50
invention patents (including 2 international PCT Patent and 3 USA Patent) and
published more than 170 SCI articles. He won the Second-prize of National Award
for Natural Science (China) in 2014 (the first rank) and the Second-prize of National
Award for Science and Technology Progress (China) in 2003 (the first rank), the Firstprize of Award for Natural Science (Shanghai) in 2013 (the first rank).
.
Bioinspired 2D/3D architecture-mediated cell response and tissue regeneration
Critical size bone defects raise great demands for efficient bone substitutes. Development of advanced bone
substitutes with excellent osteogenic capability that can support damaged tissue, induce osteogenic
differentiation and re-establish original geometry and function of the impaired tissue is highly desired. Insitu guided tissue regeneration based on the functional materials and growth factor represents a new
strategy and is being rapidly developed nowadays. For this promising strategy, the key is to explore 2D/3Dmediated cell response and tissue formation. Here, we show some interesting results about the 2D
interface/surface-induced protein adsorption and cell response, and 3D hierarchical architecture and bone
regeneration. Combining experiment and molecular dynamic simulations, we found that the 2D
nanostructured HAPs could modulate the way of adsorption of rhBMP-2, and thus the recognition of BMPRIA and the bioactivity of rhBMP-2. Compared with 2D CPC surface, 5MCPC could strongly enhance the
attachment, morphology, focal adhesion formation, actin filaments assembly and osteogenic differentiation
of BMSCs. With 3D Macro-micro-meso bioactive glass and PHBHHx/SMC scaffolds, we investigated the
effects of the surface morphology, porous structure, etc on the cell response, mass transfer and bone
regeneration in details. The results obtained in this study might provide new thoughts on the design and
development of future orthopedic biomaterials.
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Liming Dai
C208, Yifu Building
Liming Dai is currently a professor of CWRU in the Department of Macromolecular
Science and Engineering. He is also director of Case4Carbon. He received a PhD from the
Australian National University in 1991. He was a postdoctoral fellow at the University of
Cambridge,a visiting fellow at the University of Illinois, and spent 10 years with CSIRO in
Australia. He was a professor at the University of Akron and at the University of Dayton.
His research interests mainly focus on the synthesis, chemical modification, and device
fabrication of conjugated polymers and carbon nanomaterials for energy and bio-related
applications.
Carbon-based metal-free electrocatalysts for energy conversion and storage
As a building block for carbon materials of all other dimensionalities (e.g., 0D buckyball, 1D nanotube, 3D
graphite) , the two-dimensional (2D) single atomic carbon sheet of graphene has emerged as an attractive
candidate for energy applications due to its unique structure and properties. Recently, a new class of
graphitic carbon nanomaterials has been discovered as metal-free electrocatalysts to replace commercially
available noble metal (e.g., Pt, Ru) electrocatalysts for energy conversion and storage. For instance, we have
demonstrated that nitrogen-doped graphene (N-graphene) could actively electrocatalyze ORR via a fourelectron process free from the CO-poisoning effect with a higher electrocatalytic activity and better longterm durability than that of commercially available Pt/C electrocatalysts. On the basis of these experimental
observations and quantum mechanics calculations, we have attributed the observed ORR electrocatalytic
activities of the graphene-based catalysts to the electron-accepting ability of the chemically-bonded
nitrogen atoms. The N-doping induced charge-transfer could create a net positive charge (via intramolecular
charge-transfer) on adjacent carbon atoms in the nanocarbon structures to effectively change the O2
adsorption mode and to readily attract electrons from the anode, facilitating the oxygen reduction reaction
(ORR) on the metal-free cathode in fuel cells.
Shuhong Yu
C208, Yifu Building
Prof. Shu-Hong Yu is the Cheung Kong Chair Professor of Chemistry in the
Department of Chemistry at the University of Science and Technology of China
(USTC), P.R. China. He serves as the Director of the Division of Nanomaterials and
Chemistry, Hefei National Laboratory for Physical Sciences at Microscale and the
Deputy Dean of the Suzhou Advanced Study Institute, USTC. He was elected as a
Fellow of the Royal Society of Chemistry in 2013 and now serves as a General
Secretary and a Council member of the International Solvothermal Hydrothermal
Association (ISHA) since 2010. His research interests include bio-inspired synthesis of
nanostructures, self-assembly of nanoscale building blocks, nanocomposites, their
related properties and applications. He has authored or co-authored 390 refereed
journal publications, and 17 invited book chapters.
Macroscopic Nanoparticle Assemblies: Integration, Functionalization and Applications
The huge diversity of hierarchical micro-/nano- rigid structures existing in biological systems is
increasingly becoming a source of inspiration of materials scientists and engineers to create next generation
advanced functional materials. Recently, accompanied with the development of nanotechnology, some
biologically hierarchical rigid structures have been duplicated and mimicked in artificial materials through
hierarchical organization of micro-/nanosized building blocks. Although the properties of nanomaterials are
frequently superior to those of their bulk counterparts, translating the unique characteristics of individual
nanoscale components into macroscopic functional devices still remains a challenge.
In this lecture, we discuss how to assemble nanoscale building blocks into ordered assemblies as well as
their functionalities, and how to integrate them with already existing macroscopic structures and realize
their functionalization. A family of nanowire or nanoplate assemblies in form of thin films or 3D integrated
structures can be generated, demonstrating that it is possible to access a variety of high quality hybrid
materials with tunable mechanical property and other multifunctionalities. These assembled structures
show enormous application potential in diverse fields such as electronics, elastomeric conductors,
electrocatalysis, and super adsorbents.
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Bogeng Li
C208, Yifu Building
Dr. BoGeng Li currently is a Professor from Department of Polymer Science and
Engineering, Zhejiang University. His research interests include polymer reaction
engineering and synthesis of polymer materials. He has published more than 200
papers in international journals, presented more than 10 invited talks in
international conferences, and holds more than 30 Chinese patents. Now he is the
Chief Scientist of the “973 Program (National Basic Research Program of China)”
project “Preparation and Processing of High Performance Thermal Plastic
Elastomers”. He is presently Qiushi Chair Professor and Dean of Engineering of the
ZJU, and Associate Editor of Ind. & Eng. Chem. Res., an ACS journal.
Controlled Manufacturing of Polymers with Complex Chain Microstructure
Precise control over chain microstructure in a large-scale industrial production of polymer is an exciting
emerging research area and it is driven by the practical demands not only for superior physical properties and
special functionalities of the polymer materials, but also for value addition to polymerization processes and raw
materials. Constrained by the conventional mechanisms, the current industrial practices can only control average
chain properties such as average molecular weight, average copolymer composition, tacticity, etc. Based on the
CLRP and LCP mechanisms and polymerization kinetics, we have derived process models for the semi-batch CLRP
and LCP copolymerization, and used the models to design computer-programmed comonomer feeding policies
for production of polymers with targeted chain microstructures. Using this methodology, copolymers with various
chain microstructures, including uniform, random, linear, inverse linear, gradient, hyperbolic, di-block and triblock copolymers and polymers having complex topologies such as V-shape gradient, hyper-branched, crosslinked,
and multi-armed star polymers were experimentally synthesized.
Weishen Yang
C208, Yifu Building
Dr. Weishen Yang is Professor of the State Key Laboratory of Catalysis at Dalian
Institute of Chemical Physics, Chinese Academy of Sciences, China. He received his PhD
from the Chinese Academy of Sciences in 1990. He has a background in catalysis,
inorganic membranes (H2 permeable membrane, O2 permeable membrane, and
zeolite membrane) and fuel cells (Solid Oxide Fuel Cell). Prof. Yang has published ~260
referred journal papers (SCI citations > 7000；H-index 43), 4 book chapters and 20
patents on material synthesis with strong emphasis on the rational design and
molecular-level engineering of functional nano-materials for applications in catalysis,
separation and fuel cells.
Molecular sieving nanosheets of metal-organic framework
as building blocks for H2/CO2 separation
Separation of H2 from CO2 with membranes is an energy-efficient and environmentally friendly alternative
to cryogenic and absorptive or adsorptive gas separation processes. To obtain high membrane separation
performance, i.e., to fast screen molecules with high resolution, ultrathin membranes possessing regular pores
with precise size is long-cherished. Molecular sieving nanosheets (MSNs) are the ideal building blocks to put this
kind of membranes into reality. We prepare 1-nm-thick MSNs with large lateral area and high crystallinity from
layered metal-organic framework precursor and report their use in fabricating highly selective and ultrapermeable molecular sieving membranes. Unlike previous membranes performance reported to date, we found
an unusual proportional relationship between H2 permeance and H2 selectivity for the MSNs membranes, and
we achieved a simultaneous increase in both permeance and selectivity by suppressing lamellar stacking of the
MSNs so as to avoid pore blockage of the MSNs.
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Guangsheng Luo
C208, Yifu Building
Dr. Guangsheng LUO is a professor of chemical engineering at Tsinghua University. He is
currently the Director of the State Key Lab of Chemical Engineering. His research
interests revolve around micro-structured chemical systems, separation science and
technology, mass transfer phenomena, and controllable preparation of functional
Materials. He is the co-author of more than 300 peer reviewed papers and more than
70 invention patents in China. He received his BSc. Degree in applied chemistry in 1988
and his Ph.D. in chemical engineering in 1993 at Tsinghua University. He worked at Caen
University as a Postdoctoral Research fellow from 1995 to 1996, and as a visiting
scientist from 2001 to 2002 at Massachusetts Institute of Technology. He is the
recipient of several awards. He obtained the “National Outstanding Young Scientist
Award” from the National Natural Science Foundation of China in 2005 and he was
appointed as a Chungkung Professor by the Ministry of Education of China in 2009.
Preparation of microcapsules and nanoparticles with microflows
Microflow engineering and technology have high promising prospects for the development of
controllable preparation processes for materials, because they could have safety, fast mixing, and high
mass and heat transfer rate. More than ten years ago we began to develop micro-structured chemical
systems for developing controllable processes for material preparation. Multiphase microflows
including gas-liquid, liquid-liquid, gas-liquid-liquid, liquid-liquid-liquid, gas-liquid-solid systems have
been realized. Uniform bubbles and droplets could be generated with microdevices. Controllable
preparation of nanoparticle and microcapsule in microstructured chemical systems have been tested.
The results show that the microstructured systems are very controllable. The particle size and the
morphologies of the prepared materials can be well controlled. In this presentation, we will show some
cases for the development of controllable processes for material preparation with microstructured
systems.
Changjun Liu
Dr. Chang-jun Liu is a Chang Jiang Distinguished Professor in Tianjin University and
Fellow of the Royal Society of Chemistry. He is now in charge of the Program of Clean
Utilization of Fossil Fuels of Tianjin Co-Innovation Center of Chemical Science and
Engineering (COIC_CSE). His research interests include catalysis, energy material and
plasma science. He served as the 2010 Program Chair of Fuel Chemistry Division (now
Energy and Fuels Division) of the American Chemical Society and Vice Chair of
Committee on Plasma Science & Technology of Chinese Society of Theoretical and
Applied Mechanics. He was guest editors of ACS Symposium Series, Catalysis Today,
Green Chemistry, ChemCatChem and Energy & Environmental Science. He was the
Advisory Board Member of Energy & Environmental Science.
Nano and nanostructured materials created by room temperature electron reduction
Electron is the greenest reducing agent for the reduction of noble metal ions to prepare nanoparticles or
nanostructured materials. Two methods have been developed with electron as reducing agent: electron
beam irradiation and room temperature electron reduction with glow discharge or radio frequency
discharge as the resource of electrons. In this presentation, we attempt to summarize the current status of
electron reduction with those non-hydrogen discharges as electron resource. Future development has been
addressed too. The room temperature electron reduction via discharges is excellent for size and structure
control with fast nucleation and slow crystal growth. It is a simple, easy, cheap and energy efficient way to
reduce metal ions. It is also excellent to load noble metal particles into channels of ordered porous
materials, like SBA-15, with no need of complex chemical modification. The room temperature operation
makes it very useful for the preparation of noble metal catalysts supported on thermal sensitive substrates
like peptide, porous organic materials, conducting polymers, ultrahigh surface area carbon, peptides and
proteins.
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Youqing Shen
C208, Yifu Building
Prof. Youqing Shen is a chair professor in department of chemical and biological
engineering from Zhejiang University. Shen’s main research interests include polymer
reaction engineering, biomaterials, bionano engineering and nanomedicines, gene
and drug delivery. Shen has won the National Outstanding Dissertation Award (1999)
and National Distinguished Young Investigator (2008). He is also a director of center
for bionano engineering and a adjunct professor in Soft Materials Laboratory (SML)
and Department of Chemical & Petroleum Engineering at University of Wyoming.
Cancer Drug Delivery: A CAPIR Cascade and Nanocarrier Design
The cancer drug delivery process is a cascade of five steps consisting of circulation in blood, accumulation
and penetration into the tumor, cellular internalization and intracellular drug release, or the CAPIR cascade.
Thus, the most challenging aspect of cancer nanomedicine design is the integration and synchronization of
all functions required to accomplish the CAPIR cascade into one system, particularly, many of which are in
opposite in different CAPIR steps. Here, we present a nanocarrier likened to a “ cluster bomb” capable of
releasing small pH-sensitive drug-carrying nanoparticles (bomblets). This cluster bomb-like nanocarrier
synchronizes pegylation-to depegylation, large-to-small size, and neutral-to-positive charge transitions
essential for accomplishing the CAPIR cascade, enabling the carried drug to reach cells deep in the tumor,
significantly enhancing its in vivo antitumor efficacy.
Zhongyi Jiang
C208, Yifu Building
Prof. Zhongyi Jiang is a professor at School of Chemical Engineering and Technology of
Tianjin University. He obtained a Ph.D. degree from Tianjin University in 1994. He was
a visiting scholar of University of Minnesota with prof. Edward Cussler in 1997 and
California Institute of Technology with prof. David Tirrell in 2009. He is the winner of
National Science Fund for Distinguished Young Scholars in China. His research interest
includes biomimetic and bioinspired membranes and membrane processes,
biocatalysis, photocatalysis. Till now, he has coauthored over 330 SCI papers, and the
total citation times is over 6000 and the h-index is 41.
Tunable nanochannels along graphene oxide nanosheets to achieve
high-performance proton exchange membrane
Simultaneous manipulation of topological and chemical structures to induce ionic nanochannel formation
within solid electrolytes is a crucial but challenging task for the rational design of high-performance
electrochemical devices including proton exchange membrane fuel cell. Herein, we present a novel generic
approach for the construction of tunable ion-conducting nanochannels via direct assembly of graphene
oxide (GO)/poly(phosphonic acid) core-shell nanosheets prepared by surface-initiated precipitation
polymerization. Using this simple and rapid approach to engineer GO/polymer nanosheets at the molecularlevel, ordered and continuous nanochannels with interconnected hydrogen-bonded networks having a
favorable water environment can be created.
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Guangzhao Mao
C208, Yifu Building
Professor Guangzhao Mao is currently a professor of chemical engineering and
materials science of Wayne State University (WSU), an adjunct professor of biomedical
engineering, the director of the multidisciplinary research incubator program in
nanotechnology and nanomedicine. Her research group is developing a wide range of
nanomaterials including molecular nanowires for electrochemical sensing, gold
nanoparticle carriers for targeted drug delivery in spinal cord injury and cancer
therapies, and bioreducible polymer coatings for localized and sustained gene delivery.
Bioreducible Layer-by-layer Films for Sequential Gene Delivery
Layer-by-layer (LbL) films containing nucleic acids are promising biomaterials for localized gene delivery
applications including DNA vaccine delivery and tissue regeneration. Gene delivery applications require that
LbL films degrade and release film contents in physiological conditions. Our research focuses on the
synthesis and engineering of bioreducible poly(amido amine)s containing the disulfide bond as gene delivery
vectors. This talk describes a method to achieve sequential DNA release from LbL films containing
strategically placed bioreducible and nonbioreducible polycations. In order to control DNA release sequence,
the LbL film assembly and disassembly were studied by in situ atomic force microscopy, fluorescence
spectroscopy, and dynamic light scattering. We found that the LbL film containing alternating layers of
poly(amido amine) and DNA underwent fast degradation in reducing solution with micrometer particles
released from the surface. This bulk degradation behavior was changed into a sequential DNA release
pattern with nanometer products by periodic insertion of a nonbioreducible polycation poly(ethylenimine).
The insertion also resulted in improved transfection of human embryonic kidney 293 cells. We will present
results that directly link the LbL film structure with DNA release dynamics and cell transfection efficiency.
Our work demonstrates a simple method for the designing of LbL films for sequential and sustained DNA
release for gene delivery applications.
Liangyin Chu
C208, Yifu Building
Dr. Liang-Yin Chu is a dean of School of Chemical Engineering in Sichuan University
and Distinguished Professor of " Yangtze River scholar “. He is Honorary Professor
of School of Chemical Engineering in University of Birmingham, also fellow of the
Royal Society of Chemistry. He won National Science Fund for Distinguished Young
winner before. His current research interests include: Membrane materials and
technology, Smart controlled-release and targeting drug delivery systems,
Microfluidics, Mass transfer and Separations, and Biomaterials.
Drop microfluidics: A versatile and promising approach to
fabricate functional granular materials
Functional granular materials with typical sizes of 1~1000 µm have received considerable attention for
many applications. Generally, the overall functions of these microparticles strongly rely on both of their
structures and the properties of their component materials. Thus, the combination of unique structures with
functional materials provides an important route for developing advanced functional granular materials. In
this presentation, we highlight the recent effort for microfluidic fabrication of granular materials with welldesigned functions for potential biomedical applications, along with the development of microfluidic
techniques for producing the versatile emulsion templates. The phase-separated multiple emulsions allows
utilization of a variety of functional materials to generate compartment microparticles including hollow, coreshell, multicore/shell and hole-shell structures for controlled encapsulation/release, selective capture, and
confined bioreaction. We envision that the versatility of microfluidics for microparticle synthesis could open
new frontiers and provide promising and exciting opportunities for fabricating brand-new functional
microparticles with broad implications for myriad fields.
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Zidong Wei
Wednesday Oct.14 .15 9:10-9:40
Prof. Zidong Wei currently is the dean of school of chemical engineering at
Chongqing University. Prof. Wei’ is a supervisor of PhD, person selected for New
Century Talents Project, who has been awarded the Cheung Kong Scholar
Professorship by the Ministry of Education (MOE) and enjoys the special allowance of
the State Department. Prof. Wei’s main research interests include electrochemical
reaction engineering, molecular Catalysis and materials chemistry of new energy.
Palladium, a most possible alternative for Platinum used in fuel
Palladium, iridium, ruthenium and silver based catalysts have been widely investigated as alternatives to
Pt in fuel cell applications. Among them, Pd has received considerable attention in comparison with other
metal catalysts because of its relatively high activity for the oxygen reduction reaction (ORR), stability,
abundance, and low cost. Our latest research shows that the electronic structure of Pd is tuned to be close
to that of Pt when Pd is supported on an exfoliated two dimensional oxide nanoplatelet (montmorillonite,
MMT). 10 Further investigation revealed that a thin PdOx layer with Pd–O–MMT junctions, formed at the
particle/support interface, alters the electronic structure of Pd and diminishes the bonding strength of the
adsorbed O, and thus, leading to an enhanced ORR activity and stability.11 In addition, our study on a
reduced polyoxometalate (rPOM) supported Pd nanoparticle catalyst show that the ORR activity of Pd is
superior to that of the commercial Pt/C catalyst in alkaline medium due to the assist catalytic effect and
the electron delocalization effect of the rPOM support.
Jieshan Qiu
Jieshan Qiu is CheungKong Distinguished Professor, Director of Liaoning Key Lab for
Energy Materials & Chemical Engineering, Director of Center for Nano Materials and
Science, Co-Director of the PSU-DUT Joint Center for Energy Research, Executive
Director of the Institute for Energy Science and Technology; Dean for Research and
International Collaboration, Faculty of Chemical, Environmental & Biological Science
and Technology, Dalian University of Technology (DUT), China. His research interests
have been focused on the development of new methodologies for synthesis of
functional carbon materials, and their uses in catalysis, energy conversion/storage
and environment protection. .
Preparation and Functionalization of Graphene Materials for Water treatment
The low-cost preparation and functionalization of graphene materials with tuned structure and
properties have drawn much attention, and remain a big challenge up to now. With an aim of developing
techniques for making functional materials based on graphene for water treatment, and energy storage &
conversion, we have made efforts to explore the potential of producing graphene from coal, and the simple
yet effective new approaches to functionalized graphene via chemical and physical ways. In this talk, I will
report on the preparation of graphene from coal, the reduction of graphene oxides (GO) by microwave and
dielectric barrier discharge techniques, the synthesis of graphene aerogels with unique structure and
properties via self-assembly schemes by tuning the GO with chemicals containing NH2 groups, and the
applications of graphene aerogels in oil/water separation. I also will report a new strategy for high
performance membrane capacitive deionization (MCDI) by designing a novel graphene-based cationselective coating material over film-like electrospun carbon fibers. The composites function to minimize the
co-ion expulsion effect that is not uncommon for traditional CDI process，leading to an enhanced
electrosorption capacity and an improved charge efficiency. This may open up a new avenue for highperformance, energy-efficient and cost-effective MCDI, and for wide applications of functional graphenebased materials..
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Tongwen Xu
C208, Yifu Building
Tongwen Xu is a professor of The University of Science and Technology of China. He
received his Ph.D degree of Chemical Engineering in 1995 from Tianjin University,
China and Post-Ph.D of Polymer Science in 1997 from Nankai University, China. His
research interests cover membranes and the related process with a focus on ion
exchange membrane as well as the controlled release.
Advanced Ion Exchange Membrane for Enhanced Ion Transportation
via Molecular Design
The depletion of conventional energy sources and the pollution of the environment have put great
pressure on the human beings. Seeking for alternative energy and methods to diminish environmental
pollution is currently the most urgent task. In this context, ion exchange membrane research has attracted
intensive research interests over the past decades.
Ion exchange membranes are composed of a polymeric backbone and fixed groups (either anionic or
cationic), which are utilized for the transportation of counter-ions. Over the years, researcher of the
membrane community have continued to design series of anion exchange membranes and cation exchange
membranes. Our work also falls into this category. Since 1997, we have designed several types of ion
exchange membranes.
We have employed atomic transfer radical polymerization, polyacylation, Suzuki-Miyaura coupling,
Menshutkin reaction etc. to precisely control the membrane morphology, mechanical properties, topology,
ion transportation properties and so on. In this meeting, we will introduce our most recent work on
advanced ion exchange membrane for enhanced ion transportation based on molecular design.
Yifan Han
C208, Yifu Building
Dr. Yi-Fan Han is a professor of East China University of Science and Technology.
Currently, he is also the head of School of Chemical Engineering and Energy in
Zhengzhou University (adjunct). Yi-Fan Han received his master degree in chemistry
from the ECUST in 1994. After obtaining his Ph.D from the ECUST in 1997 under the
supervision of Prof. Ren Wang, he worked as a postdoctoral fellow with Prof. JingFa
Deng at the department of chemistry of Fudan university (Shanghai) and with Prof. R. J.
Behm at Catalysis and Surface Chemistry department of ULM university (Germany) and
Prof. D. W. Goodman and Prof. J.H. Lunsford at the chemistry department of Texas
A&M University (USA). From 2004.11 until 2009.9, he was a senior research fellow of
Institute of Chemical and Engineering Sciences (A*STAR, Singapore).
.
New Strategies to Characterize Dynamic Structure of Functional
Materials: Advances in Operando Techniques
The structure of functional materials is usually significantly affected by the environmental media
during working processes. For instance, the surface structure for catalysts, absorbers and sensors are
likely changed more or less by the interaction with molecules around or adsorbed on the surfaces. The
establishment of the structure-performance relationship is of paramount importance for the rational
design and controllable synthesis of those functional materials. Up to date, Operando/in situ
spectroscopy, as cutting-techniques, are developed for this aim. More recent advances in this field and
a case study will be introduced.
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Yong Wang
C208, Yifu Building
Prof. Yong Wang earned his PhD from Institute of Chemistry, the Chinese Academy of
Sciences in 2005, and worked as Research Scientist at Procter&Gamble and as Humboldt
Fellow at the Max Planck Institute of Microstructure Physics from 2006 to 2009. He is
currently Professor at the College of Chemical Engineering and also at the State Key
Laboratory of Materials-Oriented Chemical Engineering, Nanjing Tech University. He is
leading a group of about 20 members focused on homoporous membranes (HOMEs,
membranes having homogenous pore sizes and pore geometries). He serves as Co-chair of
the Organizing Committee of the 10th International Congress on Membranes and
Membrane Processes (ICOM2014), and Member of the Editorial Board of Technology of
Water Treatment. Prof. Wang has (co)authored ~100 peer-reviewed papers and 17 patents.
Ordered nanoporous polymers by selective swelling of amphiphilic block copolymers
Nanoporous materials are finding extensive applications in a diversity of fields ranging from membrane
separation to drug delivery to optoelectronics. In these applications pore geometries and size uniformity
play important roles in dictating the performances of the materials; therefore, it is highly demanding for
efficient and affordable strategies to produce materials with well-defined porosities. In this lecture, we will
talk about our recent works on highly ordered nanoporous polymeric materials derived from block
copolymers (BCPs). When exposed to selective solvents preferential only to the more polar blocks of BCPs,
(e. g. the P2VP block in polystyrene-block-poly (2-vinyl pyridine), PS-b-P2VP), P2VP domains will be swollen
selectively by ethanol and mesopores form upon ethanol removal, while the major, nonpolar PS block holds
the infrastructure of the BCP material mainly unchanged because PS chains are in the glassy state during the
swelling treatment. The sizes of pores in the BCP layer can be tuned either by changing swelling conditions,
e. g. time and temperature, or by using BCPs with different molecular weights. Interestingly, due to the
immigration of the polyelectrolyte-natured blocks onto the pore wall, the resulting porous materials possess
an intrinsically active surface with enhanced hydrophilicity, fouling resistance, and even a stimuli-response
function.
Hao Jiang
C208, Yifu Building
Dr. Hao Jiang is currently a Full Professor in the School of Materials Science and
Engineering, East China University of Science and Technology (ECUST). He obtained
his Ph.D. degree at the ECUST in 2009. He joined Temasek Laboratories, Nanyang
Technological University (NTU) in Singapore, as a research scientist in 2009-2011.
He was awarded the Professor of Special Appointment (East Scholar) at Shanghai
Institutions of Higher Learning in 2012, the New Century Excellent Talents in
University of Ministry of Education of China in 2013. In 2015, he became the winner
of the National Science Fund for Excellent Young Scholars. Hao mainly focuses on
the controlled preparation of new energy electrode materials by means of chemical
engineering principles and methods for applications in supercapacitors and lithiumion batteries (LIBs). As the first or corresponding author, Hao published above 30
SCI papers in recent 5 years, including Energy Environ. Sci., Adv. Mater., etc.
Controlled synthesis of hierarchical nanostructured electrode materials for
energy storage applications
In this topic, we mainly focus on the design and synthesis of novel hierarchical nanostructures electrode
materials by confined reaction. Firstly, the heterostructures have been fabricated via the spray-assisted
combustion. For example, SnO2 nanorod@TiO2 hybrids are obtained by a modified flame spray pyrolysis
approach, showing high power conversion efficiency. Secondly, the interlayer nanocomposites have been
prepared by the intercalation assembly methods in the channel in two-dimensional layers. Typically, we
designed a new two-dimensional hybrid nanosheet superstructure consisting of the layer-by-layer interoverlapped single-layer MoS2 and mesoporous carbon (m-C) nanosheets by the confined reaction in the MoS2
interlamilation. The hybrids created rich atomic interface for lithium ion storage. Thirdly, the host-guest
composites of mesoporous materials with semiconductor and conductive polymer have been constructed by
the confined reaction in the mesopores. The relationship between material structure and application
performance is also developed. Our studies are expected to provide new materials for energy storage
applications.
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Symposium
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Symposium
11- Petrochemicals
Fine
Chemicals
(M104)
Luyi Sun
C208, Yifu Building
Dr. Sun received his B.S. degree in Chemical Engineering from South China University
of Technology and his Ph.D. degree in Chemistry from the University of Alabama.
After that, he worked as an Assistant Research Engineer at Texas A&M University. Dr.
Sun was a Senior Research Engineer at TOTAL Petrochemicals USA, Inc. from 20062009, and an Assistant Professor at Texas State University from 2009-2013. He joined
University of Connecticut in Fall 2013.
High Performance Multi-functional Nanocoatings
Biomimetic organic/inorganic hybrid nanocoatings with a nacre-like microstructure were prepared via a
facile coassembly process. The formed nanocoatings typically possess a very low thickness of less than one
micron, and their thickness can be easily controlled. Slightly different from conventional polymer
nanocomposites, such nanocoatings contain a high concentration of nanosheets, which can be well aligned
along the substrate surface. Moreover, the nanosheets and polymer matrix can be chemically cocrosslinked. As a result, the nanocoatings exhibit exceptional mechanical properties (high stiffness and
strength), barrier properties (to both oxygen and water vapor), and flame retardancy, but meanwhile they
are highly transparent (the coated substrates can typically maintain more than 85% of their original
transmittance to visible light). The nanocoatings can be applied to various substrates (such as various
polymers, glass, metals, wood) and regular or irregular surfaces. Because of their excellent performance and
high versatility, such nanocoatings are expected to find practical daily applications such as food packaging,
etc.
Clemens Burda
C208, Yifu Building
Dr. Clemens Burda is the director of the Center for Chemical Dynamics and
Nanomaterials Research in the Chemistry Department, Case Western Reserve
University. Since 2001 he is appointed as a faculty in Physical Chemistry specializing on
Nanoscience and Nanotechnology. His interests revolve around optically active or
activatable nanomaterials for energy conversion, environmental studies, and health
applications. This applies in areas such as photovoltaics, photocatalysis, photobiology
andbiomedicine, including bioimaging, therapy and tissue targeting for drug delivery
Perovskites as Energy Materials: Synthesis and Femtosecond
Laser Spectroscopy Studies
Perovskite films were prepared using solution deposition at different annealing temperatures and
annealing times. The crystal structure, phases and grain size were investigated with XRD, XPS and SEM/EDX.
The prepared films show a typical orientation of tetragonal perovskite phase and a gradual transition at
room temperature from the yellow intermediate phase to the black perovskite phase. Films with high purity
were obtained by sintering at 100 °C. In addition, the intermediate phase could be transformed to the
perovskite phase upon Photoirradiation. These CH3NH3PbI3 perovskite were deposited as layered films on
substrates with and without a titania support structure and studied using femtosecond time-resolved
transient absorption (fs-TA) spectroscopy in the visible light range (450-800 nm). The electron relaxation
dynamics from the photoexcited perovskite layers to the neighboring film structures could be directly
monitored via the transient bleaching dynamics of the perovskite at ~750 nm and thus systematically
studied as a function of the layer-by-layer architecture. We could also spectrally distinguish transient
bleaching at ~750 nm from laser induced fluorescence that occurs red-shifted at ~780 nm. Carrier trapping is
found to be enhanced on mesoporous titania due to the possibility of grain boundaries within perovskite
and PbI2 nanocrystals at the TiO2 interface. As a result of device and material degradation, PbI2 nanocrystals
can be conveniently verified in the fs-TA spectra as transient bleach signal at ~510 nm.
Page 83
Symposium
8- Materials
andand
Nanoand
Technology
(C208)
Symposium
11Petrochemicals
Fine
Chemicals
Symposium
11- Petrochemicals
Fine
Chemicals
(M104)
Xiangping Zhang
Prof. Xiangping Zhang received her Ph.D. degree in 2002 from Dalian University of
Technology. She has been a professor of Institute of Process Engineering (IPE), CAS since
2008.Her current research focuses on the green process system integration, properties
and thermodynamic models of ionic liquids, industrial applications of ionic liquids and
cleaner processes. She has published about 132 papers in peer-reviewed journals, and
obtained 15 issued Chinese invention patents and 1 issued PCT patent. She was awarded
the National Award for Natural Sciences, the Nomination Award of the 4th Top Ten
Outstanding Women in CAS in 2012. She was the Winner of the National Science Fund for
Distinguished Young Scientists in 2014.
Ionic liquid-based material for gas separation
Gas separation was regarded as an important operation to remove harmful and toxic gas emissions to
resolve the environmental problems, and also separate impurities from gas mixtures to improve the gas
product quality. As emerged promising alternatives, ionic liquid-based materials have great potentials to be
applied in gas purification and separation.
In order to develop a new gas separation process, the fundamentals research has been conducted
focusing on the structure-property relationship of ILs, the simulation and characterization of gas absorption
mechanism, the molecular design of IL structure, the new thermodynamic model for predicating
physicochemical properties of ILs, and the transfer properties and fluid dynamic models of gas-ionic liquids
system.
Changchun Zeng
Dr. Changchun Zeng is currently an Associate Professor of Industrial and
Manufacturing Engineering of FAMU-FSU College of Engineering, and a principle
investigator of High-Performance Materials Institute of Florida State University. Dr.
Zeng’s main research interests are porous polymeric materials, polymer
composites and nanocomposites, and synthesis and processing of materials using
supercritical fluids. Prior to join FSU, he was a Senior Research Engineer at Hexcel
Corporation, one of the world leaders in carbon fiber and aerospace composite
materials. Dr. Zeng received his PhD in Chemical Engineering from The Ohio State
University, and MS (Chemical Engineering) and BS (Polymer Engineering) degrees
from Zhejiang University.
Porous Polymers as Smart Materials
Novel functional materials such as nanostructured materials and smart materials have the potential to
fundamentally change the way materials are used. Comparing to conventional materials they are of lighterweight and significantly higher performance, and may offer functionalities that do not exist today.
Manufacturing these materials in an efficient, environmentally benign process is also of paramount
importance for sustainability.
Widely used in many applications, porous polymeric materials have been intensely investigated. In this
paper we discuss our effort in exploring porous polymers as smart materials for sensing, energy harvesting,
and biomedical applications. We illustrate the utilization of environmentally benign supercritical carbon
dioxide enabled process to fabricate several types of porous polymer based smart materials and their
property enhancement by nanomaterials. Examples will be given to highlight how fundamental
understanding in chemical engineering and thermodynamics, materials science and engineering, and design
principles work together to create these materials. Their performance characteristics and applications will
also be discussed.
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andand
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Symposium
11Petrochemicals
Fine
Chemicals
Symposium
11- Petrochemicals
Fine
Chemicals
(M104)
Kewen Tang
Thursday Oct.15 , 11:00-11:30
Kewen Tang, who is professor, post-doctor, doctoral supervisor, winner of
Education Ministry's program for New Century Excellent Talents in University,
winner of Outstanding Youth Fund of Hunan province, leading scholars in
higher education of Hunan province, and director of key laboratory on
catalysis and separation in fine petrochemical engineering of Hunan province,
mainly engages in the research area of chiral separation, reaction kinetics,
simulation and optimization of chemical process. He presided 5 National
Natural Science Foundation Projects. More than 120 academic papers is
published by him in international journals including AIChE Journal, Chemical
Engineering Science, Industrial & Engineering Chemistry Research and so on.
He is one of the Most Cited Authors of Chemical Engineering Science in 2011.
One of the paper is the Top cited AIChE Journal Paper in 2014.
Experimental and Model Studies on Continuous Separation of 2-Phenylpropionic Acid Enantiomers by
Enantioselective Liquid–Liquid Extraction in Centrifugal Contactor Separators
Multistage enantioselective liquid-liquid extraction (ELLE) of 2-phenylpropionic (2-PPA) enantiomers using
hydroxypropyl-β-cyclodextrin (HP-β-CD) as extractant was studied experimentally in a counter-current
cascade of centrifugal contactor separators (CCSs). Performance of the process was evaluated by purity
(enantiomeric excess, ee) and yield (Y). A multistage equilibrium model was established on the basis of
single-stage model for chiral extraction of 2-PPA enantiomers and the law of mass conservation. A series of
experiments on the extract phase/washing phase ratio (W/O ratio), extractant concentration, the pH value of
aqueous phase and the number of stages was conducted to verify the multistage equilibrium model. It was
found that model predictions were in good agreement with the experimental results. The model was applied
to predict and optimize the symmetrical separation of 2-PPA enantiomers. The optimal conditions for
symmetric separation involves a W/O ratio of 0.6, pH of 2.5 and HP-β-CD concentration of 0.1 mol/L at
temperature of 278 K, where eeeq (equal enantiomeric excess) can reach up to 37% and Yeq (equal yield) to
69%. By simulation and optimization, the minimum number of stages was evaluated at 98 and 106 for eeeq >
95% and eeeq > 97%.
Shuangfeng Yin Thursday Oct.15, 11:30-12:00 AM
C208, Yifu Building
Dr. Shuang-Feng Yin is currently Professor and Deputy Director of College of Chemistry
and Chemical Engineering, Hunan University, Hunan Province, P.R. China. He went to
study in Beijing University of Chemical Technology and received B.Sc. degree in 1996.
Then he moved to Research Institute of Petroleum Processing and got his Master
Degree in 1999. He furthered his study in Tsinghua University and received Ph.D. in
2003. He had postdoctoral research in HK with Professor Au from 2002 t0 2004. From
2004 to present, he worked as lecturer and later full professor (2006) in the college of
chemistry and chemical engineering, Hunan University. From 2004 to 2006, he visited
Japan as a JSPS fellow. Prof. Yin’s main research interest includes industrial catalysis,
CO2 capture and use, new energy, and novel materials. He has 42 patents and over 130
research papers on international journals such as JACS, Angew Chem. AIChE J.
Bismuth-containing nano-photocatalysts: controlled synthesis and applications
Through the construction of novel structures, exposure of active facets, and/or fabrication of
heterojunctions, we developed bismuth-containing materials that show excellent visible-light-induced
activity.2-6 (1) Flower-like BiOX (X= Cl, Br, I, CO3) with high exposure of (110) faces can be easily synthesized
at room temperature. (2) Composites with BiOI/Bi2O2CO3, g-C3N4/Bi2O2CO3, and g-C3N4/Bi2O3 p-n
heterjunctions can efficiently facilitate the dye-sensitizing and charge-carriers separation processes. (3)
Cu2O-BiVO4 composites can synergistically remove dyes and Cr(VI) from water. The composites can be
synthesized by a two-step solvothermal method. (4) Hollow and branched Bi2O3-Bi2S3 heterostructures can
be generated by an environment-friendly “etching and re-growth” method, and the method can be applied
to synthesize other Bi2S3-sensitized photocatalysts. The as-fabricated materials display high photocurrent
response as well as high activity towards dye degradation under visible light. Most recently, by unifying
Bi2WO6 microflowers with g-C3N4-Bi2MoO6 as well as other bismuth-containing composites, we prepared
photocatalysts that exhibit high activity towards the selective oxidation of organics.
Page 84
Symposium
8- Materials
andand
Nanoand
Technology
(C208)
Symposium
11Petrochemicals
Fine
Chemicals
Symposium
11- Petrochemicals
Fine
Chemicals
(M104)
Zongwu Bai Thursday Oct.15, 14:10-14:40 PM
C208, Yifu Building
Dr. Zongwu Bai is a Senior Research Scientist in Materials & Manufacturing
Directorate, Wright-Patterson Air Force Base and University of Dayton Research
Institute, University of Dayton. His research interests revolve around Design and
synthesis of functional polymers, and Nanoparticle and nanocomposite synthesis.
Nanocomposites and Nanotechnology in Proton Exchange Membranes Materials
All polymeric electrolyte fuel cells have typically been operated in a temperature range between
approximately 50 and 90oC. The temperatures above the polymer glass transition temperature (~110oC for
Nafion) can cause polymer chain rearrangements, which can lead to structural changes in the membrane
and lower the membrane stability, performance, and lifetime. Polymeric membranes able to operate above
120oC could benefit from both enhanced carbon monoxide (CO) tolerance and improved heat removal. The
addition of nanofunctions into a polymeric membranes to form a nanocomposites can alter and improve
polymer properties such as glass transition temperature, elastic modulus, tensile strength, solvent
permeability, hydrophilicity, water uptake and proton conductivity while enabling the polymeric
membranes to maintain its suitability for operation in the fuel cells.
Highly sulfonated polyarylenethioethersulfones (SPTES) polymers were successfully synthesized. To
improve the high temperature performance of the SPTES membranes in the fuel cell application, the
nanoparticles, such as ZrP or Clay, sulfonated poly(p-phenylene benzobisimidazole) (SPBI) were introduced
into the SPTES membranes to form nanocomposite membranes. The interesting feature of the
nanoparticles is that it can retain water at high temperature, and it was found that the swelling of the
nanocomposite membranes was reduced due to the reduced water uptake of the nanocomposite
membrane. The morphology changes of the nanocomposite membranes were examined by a combination
of techniques such as X-ray diffraction (WAXD), scanning electron microscopy (SEM) and transmission
electron microscopy (TEM) to confirm the dispersion of SPBI and nanoparticles as well as nanophase
separation. The membrane electrode assembly (MEA) performance of the nanocomposite membranes was
preliminary studied for H2/O2 fuel cells applications
Page 86
Symposium
8- Materials
andand
Nanoand
Technology
(C208)
Symposium
11Petrochemicals
Fine
Chemicals
Symposium
11- Petrochemicals
Fine
Chemicals
(M104)
Yingwei Li
Dr. Yingwei Li is currently the deputy dean of School of Chemistry and Chemical
Engineering at the South China University of Technology. He received his B.S. degree in
1998 and Ph.D. in 2003 from Tsinghua University. Following postdoctoral work at the
University of Calgary (Canada) and the University of Michigan (Ann Arbor) from 2003 to
2007, he joined the South China University of Technology as a full professor. His
research interest focuses on design and synthesis of new metal-organic framework
(MOF) materials for heterogeneous catalysis and gas adsorption /separation. In the past
10 years, he has published more than 60 papers on MOFs in the peer reviewed journals.
Metal-organic frameworks encapsulated metal nanoparticles for
heterogeneous catalysis
In this talk, we focus on two aspects of MOFs’ catalysis applications: the use of MOF materials as
scaffold for the incorporation of metal nanoparticles, and the preparation of metal/carbon materials from
thermolysis of MOFs.We employed stable MOFs as support for highly dispersed metal. The metal-doped
MOFs are shown to be highly efficient for a variety of chemical conversions. In order to encapsulate metal
NPs within MOFs, we have developed a novel synthesis strategy through ligand design prior to MOF
assembly, achieving uniformly distributed metal NPs inside the cavities of MOFs. On the other hand, taking
advantage of their ordered structures and relatively low thermal stability, MOFs could be utilized for the
preparation of new metal oxides or carbon nanomaterials by thermal decomposition. Here we show that
Co nanoparticles embedded in nitrogen-doped carbon prepared from MOFs thermonlysis could catalyze a
variety of organic transformations, such as aerobic oxidation of alcohols to esters, low-temperature CO
oxidation, and oxidative amidation of aldehydes.
Ling Zhang
Dr. Zhang Ling has a Ph.D. in Materials Processing Engineering graduated from
Sichuan University. She is currently a Professor in East China University of Science
and Technology and also a member of Key Laboratory for Ultrafine Materials of the
Ministry of Education. Her research focuses on surface modification of nanoparticles,
the design and synthesis of new reinforcement with specific structure, and their
application in polymer composites. In the past 10 years, she presided over a number
of national and provincial projects. She has published more than 50 journal articles
and is the inventor/co-inventor of 21 Chinese patents.
Highly conductive and flexible polymer composites based on carbon
nanotube/graphene network
Here, the carbon nanotubes and graphene were prepared into 3D carbon aerogel (CA) structures by
using organic sol-gel method. Meanwhile, we also creatively designed a new stretchable conductive
material that integrates 3D CNTs/reduced graphene oxide (rGO) network with a porous PDMS (p-PDMS)
elastomer (pPCG). This reciprocal architecture not only alleviates the aggregation of carbon nanofillers but
also significantly improves the conductivity of pPCG under large strains. The simulation of the mechanical
properties of the p-PDMS model demonstrates that an extremely large applied strain can be
accommodated through local rotations and bending of cell walls. Thus, after a slight decrease, the
conductivity of pPCG can continue to remain constant even as the strain increases to 50%. In general, this
architecture of pPCG with a combination of a porous polymer substrate and 3D carbon nanofiller network
possesses considerable potential for numerous applications in next-generation stretchable electronics.
Page 87
Symposium
8- Materials
andand
Nanoand
Technology
(C208)
Symposium
11Petrochemicals
Fine
Chemicals
Symposium
11- Petrochemicals
Fine
Chemicals
(M104)
Chunzhong Li
Symposium Chair
Dr. Chunzhong Li received B.S. (1989), M.S. (1992) and PhD (1997) from East
China University of Science and Technology (ECUST). He became a full professor
of school of materials science and engineering in 1998, and now he is the
director of Key Laboratory for Ultrafine Materials of the Ministry of Education at
ECUST. He was elected as a Fellow of the Royal Society of Chemistry in 2015,
became the Cheung Kong Distinguished Professor in 2014, the winner of the
National Science Fund for Distinguished Young Scholars in 2009. As the first
accomplished person, he has achieved the second-class prize of the National
Science and Technology Progress Award in 2009, the first Class Prize for
Shanghai Natural Science Award in 2014, the first class prize for the science and
technology progress award of the Ministry of Education of China in 2010, and
the first class prize of the Science and Technology Progress Award of Shanghai
City in 2009, 2006 and 2004 respectively. He published more than 350 peerreview papers (Total citation ~ 8,400, H index 46), and more than 90 invention
patents in China. His research interests mainly include designed synthesis of
functional nanomaterials based on the principle and methods of chemical
engineering, the synthesis and processing polymer based nanocomposites, and
the engineering properties and process scale-up for nanomaterials.
Page 88
Symposium 8- Materials and Nano Technology (C208)
Chair : Changsheng Liu, Stuart Cooper
Afternoon
13:30-14:10
14:10-14:40
14:40-15:10
Title
S8-K1
Name
Nanogenerators for self-powered systems Zhong Lin
and piezotronics for smart devices
Wang
Affiliation
Georgia
Institute of
Technology
S8- I1
Cancer Drug Delivery: A CAPIR
Cascade and Nanocarrier Design
(H0093)
Youqing
Shen
Zhejiang
University
S8- I2
Tunable nanochannels along graphene
oxide nanosheets to achieve highperformance proton exchange
membrane (H0413)
Zhongyi
Jiang
Tianjin
University
15:10-15:20
Coffee break
East China
Changsheng University of
Liu
Science and
Technology
15:20-16:00
S8-K2
Bioinspired 2D/3D architecturemediated cell response and tissue
regeneration
16:00-16:30
S8-I3
Bioreducible Layer-by-layer Films for
Sequential Gene Delivery (H0251)
Guangzhao
Mao
Wayne State
University
S8-I4
Drop microfluidics: A versatile and
promising approach to fabricate
functional granular materials (H0218)
Liangyin
Chu
Sichuan
University
16:30-17:00
Page 89
Chair : Liming Dai, Shuhong Yu
Morning
Title
Name
Interfacial Assembly and Engineering of
Dongyuan
Ordered Functional Mesoporous Materials
Zhao
for Applications (H0490)
Affiliation
Fudan
University
8:30-9:10
S8-K3
9:10-9:40
S8-I5
Palladium, a most possible alternative
for Platinum used in fuel cells (C0163)
Zidong
Wei
Chongqing
Univ.
S8-I6
Preparation and Functionalization of
Graphene Materials for Water treatment
(H0376)
Jieshan
Qiu
Dalian
University of
Technology
Stuart
Cooper
Ohio State
University
9:40-10:10
10:10-10:20
10:20-11:00
11:00-11:30
11:30-12:00
Coffee break
S8-K4
Polyurethanes and Ionomers: High
Performance Elastomers and Plastics
Self Reinforced with Nanoscale
Structure (H0201)
S8-I7
Advanced Ion Exchange Membrane for
Enhanced Ion Transportation via
Molecular Design (H0220)
Tongwen
Xu
Univ. of
Science and
Technology of
China
S8-I8
New Strategies to Characterize Dynamic
Structure of Functional Materials:
Advances in Operando Techniques
(H0435)
Yifan Han
ECUST
Title
Name
Affiliation
Carbon-based metal-free electrocatalysts
for energy conversion and storage (H0439)
Liming
Dai
Case Western
University
12:00-13:30
Chair : Weishen Yang, Guangzhao Mao
Afternoon
13:30-14:10
S8-K5
14:10-14:40
S8- I10
14:40-15:10
S8-I10
15:10-15:20
Page 90
Ordered nanoporous polymers by selective
Yong
swelling of amphiphilic block copolymers
Wang
(H0488)
Controlled synthesis of hierarchical
nanostructured electrode materials for
Hao Jiang
energy storage applications (D0526)
Coffee break
Nanjing Tech
University
ECUST
Shuhong
Yu
Univ. of
Science and
Technology
of China
Luyi Sun
University of
Connecticut
Perovskites as Energy Materials: Synthesis
Clemens
and Femtosecond Laser Spectroscopy
Burda
Studies (H0357)
Case Western
Reserve
University
15:20-16:00
S8-K6
Macroscopic Nanoparticle Assemblies:
Integration, Functionalization and
Applications (H0407)
16:00-16:30
S8-I11
High Performance Multi-functional
Nanocoatings (H0027)
16:30-17:00
S8-I12
Chair : Jieshan Qiu, Clemens Burda
Morning
Title
Name
Affiliation
S8-K7
Controlled Manufacturing of Polymers
with Complex Chain Microstructure
Bogeng Li
Zhejiang
University
9:10-9:40
S8-I13
Ionic liquid-based on material for gas
separation (H0492)
Xiangping
Zhang
Institute of
Process
Engineering
9:40-10:10
S8-I14
Porous Polymers as Smart Materials
(H0271)
Changchun Florida State
Zeng
University
8:30-9:10
10:10-10:20
10:20-11:00
Coffee break
S8-K8
11:00-11:30
S8-I15
11:30-12:00
S8-I16
12:00-13:30
Molecular sieving nanosheets of metalorganic framework as building blocks for
H2/CO2 separation (H0276)
Weishen
Yang
Experimental and Model Studies on
Continuous Separation of 2Kewen
Phenylpropionic Acid Enantiomers by
Tang
Enantioselective Liquid–Liquid Extraction
in Centrifugal Contactor Separators
Bismuth-containing nano-photocatalysts:
Shuangfeng
controlled synthesis and applications
Yin
(H0403)
Dalian Institute
of Chemical
Physics, CAS
Hunan
Institute of
Science and
Technology
Hunan
University
Page 91
Chair : Bogeng Li, Guangsheng Luo
Afternoon
13:30-14:10
14:10-14:40
14:40-15:10
Title
Affiliation
S8-K9
Preparation of microcapsules and
Guangsheng
nanoparticles with microflows (H0103)
Luo
S8-I17
Nanocomposites and Nanotechnology in
Proton Exchange Membranes Materials
(H0353)
Zongwu
Bai
AFRL/RXC
C-UDRI
S8-I18
Metal-organic frameworks encapsulated
metal nanoparticles for heterogeneous
catalysis (H0535)
Yingwei
Li
South China
University of
Technology
Changjun
Liu
Tianjin
University
Ling
Zhang
ECUST
15:10-15:20
Tsinghua
University
Coffee break
15:20-16:00
S8-K10
16:00-16:30
S8-I19
Nano and nanostructured materials
created by room temperature electron
reduction (H0170)
Highly conductive and flexible polymer
composites based on carbon
nanotube/graphene network
Note: S ~ Symposium; K~ Keynote; I~ Invited talk
Page 92
Name
Symposium 9- Membrane Technology for Water Purification (C202)
Symposium 9- Membrane Technology for Water Purification
Chairs: Zhenliang Xu, [email protected]; Weihong Xing, [email protected]
Ranil Wickramasinghe, [email protected]; Xianghong Qian, [email protected]
Featured Speakers
Tongwen Xu Tuesday Oct.13, 13:30-14:10 PM
Tongwen Xu is a professor of The University of Science and Technology of China. He
received his Bachelor’s degree in 1989 and Master’s degree in 1992 from Hefei
University of Technology, China. Till now, he supervised more than 100 graduate
students and published more than 300 papers in peer-reviewed international journals
with over 4500 citations and H-index 40. He applied 62 invention patents (32 License).
He was selected as Fellow of Royal Society of Chemistry in 2013 and as Changjiang
Scholars Program Chair Professor in 2014.
.
Ion exchange membrane-based separation technologies
Ion exchange membranes are of the corresponding resins in membrane shape. Electro-membranes and
related processes have attracted more and more attention and have found numerous applications in
resource recycling, energy conversion, and environmental protection. These vital technologies are
developing as a new platform in industrial ecosystems because they can realize some novel separation and
production to achieve the maximal utilization of resources and pollution prevention. The economical and
environmental benefits of electro-membranes technologies are flexibly coupled with many other
technologies to achieve a synergistic technological intensification. In this Keynote report, the recent
developments of the most commonly used ion exchange membrane-based separation technologies such as
diffusion dialysis (DD), conventional electrodialysis (CED) and bipolar membranes electrodialysis (BMED) will
be presented with following sub-titles.
Zhenliang Xu
Dr. Zhen-Liang Xu is a professor of State Key Laboratory of Chemical Engineering and
National Engineering Research Center of Ultrafine Powder at East China University of
Science and Technology (ECUST) of China. He applied 42 invention patents (15
Licenses). Prof. Xu was selected as “Project Coordinator of Ministry of Science and
Technology of China in 2012 and as the expert of China Membrane Industry
Association in 2009. Prof. Xu are serving as the editors and editorial boards of 7
Chinese journals and edited five Chinese books including “New Progresses and
Engineering Applications of Membrane Technologies (2013)”. His research interests
cover asymmetric and composite membranes, Functional membrane materials.
Novel Fluoropolyamide NF Membranes and Separation Properties
A novel composite nanofiltration (NF) membrane was prepared by interfacial polymerization of 2,2’bis(1-hydroxyl-1-trifluoromethyl-2,2,2-trifluoroethyl)-4,4’-methylenedianiline (BHTTM) and trimesoyl
chloride (TMC) on polyethersulfone (PES) supporting membrane. Different preparation conditions and NF
membrane performances were discussed. The membrane structures of composite NF membranes were
characterized by attenuated total reflectance infrared (ATR-IR), scanning electron microscope (SEM) and
atomic force microscopy (AFM). The results showed that the NF membrane prepared under the optimum
condition exhibited Na2SO4 rejection of 85.3% and the water flux of 10.1 l.m-2.h-1. The NF membrane was
treated by 5000 ppm chlorine solution for 1 h. The salt rejection and water flux of the treated membrane
reached to 94.5% and 94.8 l.m-2.h-1. The rejection of two NF membranes for inorganic electrolyte solutions
decreased in the order of Na2SO4, MgSO4, MgCl2, NaCl, which were typical characteristics of negatively
charged membranes.
Page 93
Enrico Drioli
Professor Enrico Drioli has been working in Membrane Science and Membrane
Engineering for many years. He is a Full Professor at the Department of Chemical
Engineering and Materials at the University of Calabria, where he founded the
Institute of Membrane Technology of the Italian Research Council in 1993. He is
also the author of more 530 scientific papers, 18 patents in the field of Membrane
Science and Technology, and 10 scientific books .
.
Membrane engineering for water purification and reuse in mining industry
High water stress, increasing energy consumptions and mineral depletion are all already critical issues.
Process engineering is one of the disciplines more involved in the technological innovations necessary to
face these strongly inter-connected problems. As a matter of fact, water is also needed for energy
generation (e.g. as cooling component); energy is also needed in desalination and for raw material
production (especially in mining where large amount of energy and water are necessary). Membrane
technology can represent a problem-solver with inter-correlated solutions. In the last years membranes
operations have been already assigned a key role in water reclamation schemes that are aimed at higher
water quality reuse applications (i.e., reverse osmosis is considered one of the most promising technologies
for desalting salty waters). Moreover, the traditional membrane separation operations (e.g., MF, UF, NF,
RO), widely used in many different applications, are today combined with new membrane systems such as
MD, MCr, PRO, RED. At present, redesign of important industrial production cycles by combining various
membrane operations suitable for separation and conversion units, and thus realizing highly integrated
membrane processes, is an attractive opportunity because of the synergistic effects that can be attained. In
this work, integrated membrane-based desalination have been considered for the extraction of fresh water
and metals of interest from seawater and high concentrated brine streams of the desalination plants.
Wanqin Jin
Dr. Wanqin Jin is a professor of Chemical Engineering at Nanjing Tech University
(former name: Nanjing University of Technology), the Deputy-director of the State Key
laboratory of Materials-oriented Chemical Engineering and the Chief-scientist of the
National Basic Research Program of China (973 Program). He has published over 200
SCI tracked journal publications with over 5800 citations, and edited 5 books and had
32 authorized patents. He presented over 30 plenary, keynote lectures and invited
speeches in international conferences, and was chair of the 10th International
Congress on Membrane and membrane Processes (ICOM2014).
Molecular Separation Membranes Derived from Graphene Oxide nanosheets
A facile silane-graft modification approach proposed by our group was demonstrated to be an efficient
way to improve the quality of the GO film formed on the porous ceramic substrate. Based on this, we
further demonstrated a scalable fabrication of GO membranes on ceramic hollow fiber substrate and
showed good PV dehydrotion of aqueous organic solution. The as-prepared membrane exhibited excellent
water permeation for dimethyl carbonate/water mixtures. In addition, we also proposed a novel type of
membrane with fast and selective gas-transport channels of GO laminates enabled by polymer-GO hydrogen
bonding.[4] Featuring molecular-sieving interlayer spaces and straight diffusion pathways, the assembled
graphene oxide laminates endow the gas separation membranes with excellent CO2 permeation
performance and extraordinary operational stability which is believed to be attractive for implementation in
practical CO2 capture. Recently, we demonstrated a novel bio-inspired strategy that utilizes the synergistic
effect of a hydrophilic polymer and GO laminates to realize fast water-transport channels for constructing
high-efficiency membrane. Because GO nanosheets can be easily mass-produced by chemical oxidization
and ultrasonic exfoliation from inexpensive raw graphite, it is expected that GO-based material is promising
for membrane based process, including PV dehydration and gas separation
Page 94
Ingo Pinnau
Ingo Pinnau is Director of Advanced Membrane and Porous Materials Research
Center and named Professor of Chemical and Biological Engineering, Physical
Science and Engineering. His research interests are in membrane processes for
separation of gases and liquids-natural gas treatment, CO2 sequestration, hydrogen
recovery, olefin/paraffin separation, and water purification. His research focuses
on: Synthesis of high-performance polymers; Development of high-performance
membranes for gas and liquid separations; Hybrid organic/inorganic membranes;
Nanostructured microporous polymer membranes.
Elucidation of the microstructure of interfacially polymerized
reverse osmosis membranes
Today, the most commonly used commercial membranes for brackish and seawater desalination are
based on thin-film polyamide composite membranes formed by interfacial polymerization of multifunctional
aromatic or cycloaliphatic diamines and acid chlorides. The resulting thin films are typically 200 to 2000 Å
thick with various topologies ranging from smooth and continuous to highly heterogeneous, ridge and valley
structures. Optimized RO membranes exhibit salt rejection of 99+%, indicating that the highly water
permeable, salt rejecting polyamide layer is essentially defect-free. It has been postulated that transport
across the polyamide layer occurs by a solution/diffusion mechanism similar to that well accepted in gas
permeation processes. In this work, we investigated the microstructure of RO membranes by means of
water transport studies (RO and FO mode), gas permeation experiments as well as tomography, TEM and
FESEM studies. Our results confirm that the water flux of RO membranes can be optimized by incorporation
of various porous and non-porous nanofillers, such as POSS and ZIF-8, without loss in salt rejection.
Kamalesh K. Sirkar Wednesday Oct.14, 15:20-16:00 PM
Kamalesh K. Sirkar is a Distinguished Professor of Chemical Engineering at New
Jersey Institute of Technology (NJIT) in Newark, New Jersey, USA. He is also the
Foundation Professor of Membrane Separations and Director of the NJIT Center for
Membrane Technologies. He is internationally recognized as an expert in
membrane separation technologies.
Experimental and Modeling Studies in Membrane Distillation
We have studied direct contact membrane distillation (DCMD) using porous polypropylene hollow fiber
membranes (HFMs) having a highly porous plasma polymerized fluorosiloxane coating on the outside
surface. These fibers are arranged in a rectangular module with hot brine in cross-flow. When such a
module is fed with hot de-oiled produced water (Chevron), we can recover as much 80% of the water by
DCMD without scaling damage on the membranes. Since this water is hot, no heat source is needed.
Although the feed had many constituents, the permeate produced was highly purified; conventional
treatment for this produced water involved 7-8 steps. Steam assisted gravity drainage (SAGD) process of
producing oil from Canadian oil-shale yields a produced water at 2-4 atm and 130-150oC+. We have studied
successfully a DCMD process to recover water using flat and HFMs of polytetrafluoroethylene (PTFE) and
polyvinylidene fluoride (PVDF) from simulated SAGD-produced water at high temperatures. To evaluate the
influence of membrane properties on DCMD, many commercially-available microporous hydrophobic flat
membranes of PVDF and PTFE (varying pore size and thickness) were studied over a range of hot brine
temperatures. Membrane properties, e.g., the maximum pore size and tortuosity, were experimentally
determined for use in modeling Knudsen and the transition regimes. The heat transfer coefficients in the
membrane cell and membrane surface temperatures were determined from experimental data via Wilson
plots.
Page 95
W.S. Winston Ho
W.S. Winston Ho is Distinguished Professor of Department of Chemical &
Biomolecular Engineering and Department of Materials Science and Engineering, the
Ohio State University. He experts in molecularly based separations including definition
of approaches, design of practical systems, scale-up and commercialization.
Specialized in membranes and separations including polymer and liquid membranes,
fuelcell fuel processing and membranes, separations with chemical reaction,
supported liquid membranes, reverse osmosis, gas treating, pervaporation, and
facilitated transport.
New Fouling-Resistant High-Flux Membranes for Seawater Desalination
We have synthesized high flux membranes by incorporating a hydrophilic additive in the aqueous amine
solution during interfacial polymerization, resulting in increasing water flux significantly through an
additional pathway for water transport while maintaining high salt rejection via charge repulsion. For
seawater desalination using synthetic 3.28 wt% NaCl solution at 800 psi (5.52 MPa) and 25oC, the
membrane synthesized with the hydrophilic additive showed a very high flux of 1.81 m3/m2/day (44.4
gallons/ft2/day (gfd)) and a salt rejection of 99.41%. This flux was 83.5% higher than the membrane
synthesized without the hydrophilic additive. The high-flux membrane was further tested using seawater
from Port Hueneme, CA and exhibited a very good and stable desalination performance for 30 days. FTIR
confirmed the good membrane stability. The membrane synthesized with hydrophilic additive showed
significantly improved fouling resistance using sodium alginate as the model foulant. With 25 ppm sodium
alginate in the synthetic feed solution, the water flux reduction of the membrane synthesized with the
hydrophilic additive was 11.0% compared to 18.2% for the membrane synthesized without the additive.
Analysis of the fouling resistance using the resistance-in-series model indicated that the values of the ratio
of the mass transfer resistance due to the foulant for the membrane synthesized with the additive to that
for the membrane without the additive were 0.30 and 0.29 for 25 ppm and 50 ppm sodium alginate in the
feed solutions, respectively. Analysis using atomic force microscopy showed a smoother membrane surface
for the membrane incorporated with the hydrophilic additive.
Page 96
Chair : Ranil Wickramasingle, Zhenliang Xu
Afternoon
13:30-14:10
14:10-14:40
14:40-15:10
Title
Name
Affiliation
S9-K1
University of
Ion exchange membrane-based separation Tongwen Science and
technologies (I0221)
Xu
Technology
of China
S9-I1
Design of Multiwalled Carbon Nanotubes
Functionalization for Optimizing
Dispersion in Mixed-Matrix Membranes
for Advanced Separations (I0286)
S9- I2
15:10-15:20
Elena
Tocci
ITM-CNR
Institute of
Affinity membranes for dynamic
Chuanfang
Process
adsorption of heavy and precious metals
Yang
Engineering,
CAS
Coffee break
S9-K2
Novel Fluoropolyamide NF Membranes
and Separation Properties (I0130)
ZhenLiang
Xu
ECUST
16:00-16:30
S9-I3
Coupling Magnetic Pickering Emulsions
with Membranes for Fouling-Free
Oil/Water Separations (I0031)
David
Jassby
University of
California
16:30-17:00
S9-I4
15:20-16:00
Blend Polymer Membranes with Filtration Bao-Ku
and Absorption Property (I0223)
ZHU
Zhejiang
University
Chair : Ranil Wickramasingle, Zhenliang Xu
Morning
Title
Name
Affiliation
8:30-9:10
Membrane engineering for water
purification and reuse in mining industry
Enrico
Drioli
King
Abdulaziz
University
Research on novel membranes and
processes designed for membrane
Xiaolong
Tianjin
Polytechnic
9:10-9:40
S9-K3
S9- I5
distillation purpose
Lv
University
Page 97
9:40-10:10
S9-I6
10:10-10:20
Enhanced membrane antifouling and
separation performance by manipulating
phase separation and surface segregation
behaviors through incorporating versatile
modifier (I0418)
Zhongyi
Jiang
Tianjin
University
Wanqin
Jin
Nanjing Tech
University
Coffee break
10:20-11:00
S9-K4
Molecular Separation Membranes
Derived from Graphene Oxide
Nanosheets (I0466)
11:00-11:30
S9-I7
Adsorptive Membranes for Ammonia
Removal
Xianghong University of
Qian
Arkansas
Development of high efficient MEAbased solvents for CO2 capture (I0467)
Beijing
Weidong University of
Zhang
Chemical
Technology
11:30-12:00
S9-I8
12:00-13:30
Chair : Xinhong Qian and Weihong Xing
Afternoon
13:30-14:10
Title
S9-K5
Elucidation of the microstructure of
interfacially polymerized reverse osmosis
membranes (I0393)
Name
Affiliation
Ingo
Pinnau
King
Abdullah
University of
Science and
Technology
The
University of
Hong Kong
Baolin
Deng
Universityof
Missouri
Kamalesh
Sirkar
New Jersey
Institute of
Technology
14:10-14:40
S9-I9
Doppler optical coherence tomography: a
Chuyang
novel method to characterize fluid
Tang
dynamics and membrane fouling for a
spacer-filled membrane system
14:40-15:10
S9-I10
Antibacterial TFC membranes enabled by
chemically-bound metal nanoparticles
15:10-15:20
Coffee break
15:20-16:00
S9-K6
Experimental and Modeling Studies in
Membrane Distillation (I0225)
16:00-16:30
S9-I11
Effect of membrane structure on
membranes performance during
membrane distillation (I0254)
16:30-17:00
S9-I12
Treatment of pharmaceutical wastewater
for reuse by coupled membrane-aerated
biofilm reactor (MABR) system (I0364)
Page 98
Sumith
University of
Wickram
Arkansas
asinghe
Baoan Li
Tianjin
University
Chair : Ranil Wickramasingle, Weihong Xing
Morning
Title
Name
8:30-9:10
S9-K7
New Fouling-Resistant High-Flux
Membranes for Seawater Desalination
(I0216)
Winston
Ho
S9-I13
Surface Engineering of Electrospun
Polymeric Nanofibers For Membrane
Distillation(I0362)
Yunxia
Hu
S9-I14
Unique Transport Phenomena in
Graphene Oxide Membranes for Water
Purification
Baoxia
Mi
9:10-9:40
9:40-10:10
Affiliation
The Ohio
State
University
Yantai
Institute of
Coastal Zone
Research,
ChineseAcad
emy of
Sciences
University of
California,
Berkeley
Note: S ~ Symposium K~ Keynote; I~ Invited talk
Page 99
Symposium 10- Particle and Fluidization Technology (M203)
Symposium 10- Particle and Fluidization Technology
Chairs: Fei Wei, [email protected]
Qingshan Zhu, [email protected]
Marc-Olivier Coppens, [email protected]; Alissa Park, [email protected]
Featured Speakers
Liang-Shih Fan
M203 Classroom, Yifu Building
Prof. L.-S. Fan is the Distinguished University Professor and C.J. Easton Professor in
the Department of Chemical and Biomolecular Engineering at The Ohio State
University. Prof. Fan also serves as the Director of the Clean Energy Research
Laboratory at The Ohio State University. Prof. Fan is widely recognized for the
development of clean energy technologies such as the removal of SOX/ NOX, As and
Se using super-reactivity limestone sorbents, CO2 separation from flue gases using
high reactivity metal oxides, chemical looping combustion of coal, enhanced H2
production with in-situ CO2 capture, and CO2 mineral sequestration using Mgbearing minerals. He is an elected member of the U.S. National Academy of
Engineering and an Academician of the Academia Sinica, and a foreign member of
the Australian Academy of Technological Sciences and Engineering, the Chinese
Academy of Engineering, and the Mexican Academy of Sciences.
Chemical Looping Processes: Role of Fluidization and Particle Science
The concept of chemical looping reactions has been applied to processes used in chemical industries.
Fundamental and applied research on chemical looping reactions in energy systems has been extensively
carried out. Fossil fuel chemical looping applications started with the steam-iron process using syngas from
coal as feedstock in the 1900s through the 1940s and were demonstrated at a pilot scale with the carbon
dioxide acceptor process in the 1960s and 1970s. There are presently no chemical looping processes using
carbonaceous fuels in commercial operation. However, with CO2 emission from fossil fuel usage that is now
of great concern, interest is high in chemical looping technology applications for CO2 capture. Chemical
looping technology is a manifestation of the interplay among all the key elements of particle science and
technology including particle synthesis, reactivity and mechanical properties, flow stability and contact
mechanics, gas-solid reaction engineering and fluidization. This presentation will describe the fundamental
and applied aspects of modern chemical looping technology that utilizes fossil and other carbonaceous
feedstock. Specifically, it will discuss the characteristics of fluidized bed and moving bed and their impact on
the metal oxide conversion in the reducer operation the key operation of the chemical looping processes.
The energy conversion efficiency and economics of the Coal-Direct Chemical Looping Process and Syngas
Chemical Looping Process being developed at Ohio State University based on the moving bed configuration
will also be elaborated.
Page 100
Wei Wang
Dr. Wei Wang is Professor of Institute of Process Engineering (IPE), Chinese Academy
of Sciences. has been working on multiscale modeling, computational fluid dynamics
(CFD) for multiphase flow and computerized tomography (CT) techniques for
multiphase flow systems. his method has been applied successfully for
troubleshooting/design in industrial processes of e.g. fluid catalytic cracking, coal
gasification and combustion, polyethylene polymerization, kaolinite clay calcination
and so on.
Speeding Up Reactive Modeling of Fluidized Bed Reactor by
Combining CRE and Multiscale CFD
The methanol to olefins (MTO) process, which is a promising alternative to produce light olefins from
coal resources, has been successfully commercialized in China by DICP. The design of MTO reactor borrows
ideas from the reaction-regeneration configuration of the modern fluid catalytic cracking (FCC) process, but
the fluidized bed for MTO reactions operates in the regime of bubbling or turbulent fluidization. The coke
content of catalyst is found to greatly affect the MTO reaction rate, but its conversion rate is slow and
normally takes hours prior to reaching desired level of content (about 6%~7%). The mean residence time of
solid catalysts is hence in orders of minutes or hours. Time-dependent computational fluid dynamics (CFD)
simulation of such a long process poses a big challenge to reactive multiphase flow modeling. To speed up it,
we try to combine the classic chemical reaction engineering (CRE) model with CFD. For example, the
continuous stirred tank reactor (CSTR) model is used to estimate the steady state distribution of coke
content, which is then set as the initial distribution for CFD simulation to shorten the time to reach steady
state of MTO reactors. Comparison with experimental data shows good agreement and also great speed up
ratio compared to pure CFD simulation.
Mao Ye
Mao Ye is professor of chemical engineering at the Dalian Institute of Chemical
Physics (DICP), CAS. His research interests include methanol to olefins and fluid
catalytic cracking process, fluidized bed reactor, and multiphase flow modeling and
measurement techniques. He was the recipient of the Newton Advanced Fellowship
by Royal Society, UK in 2015.
.
Improve bubble size estimation by pressure fluctuation analysis in gas-fluidized beds
Pressure fluctuation signals captured at a single point in the gas-fluidized bed is composed by global
fast compression waves and local bubble-passage induced slow pressure waves. Based on the Davidson and
Harrison bubble model, the local bubble-passage induced slow wave has the amplitude proportional to the
size of bubbles, and can only be detected when the bubbles move close to the pressure measurement
points. In principle, if the local pressure wave can be separated from the global one, the information of
bubble size can be inferred accordingly. Van der Schaaf et al. proposed an interesting frequency decoupling
method to estimate bubble size in fluidized beds according to the different propagation velocity of the two
types of pressure waves. As the pressure signal in the windbox only contain the global pressure waves while
the in-bed pressure signals are a combination of the global pressure waves and the local bubble induced
ones, a coherence analysis between on the pressure series simultaneously detected in the bed and in the
windbox can be used to measure bubble size. This frequency decoupling method has now been widely used
in bubble size estimation. However, this method seemingly can only give a qualitative prediction of the
bubble size. No studies have been carried out so far to analyze the systematic deviation of bubble size
estimated from pressure fluctuation signals. In this study, we used an ECT system together with the
synchronized pressure sensors to study the inherent reasons for the deviation in bubble size measurement.
Page 101
Ah-Hyung Alissa Park
Wednesday Oct.14, 8:30-9:10 AM M203 Classroom, Yifu Building
Professor Park is Lenfest Junior Professor in Applied Climate Science, the Earth Institute,
Columbia University. She is currently leading a worldwide multidisciplinary NSF Research
Coordination Network devoted to CCUS. Her current research interests are include: Carbon
Capture, Utilization and Storage (CCUS); Novel Nano-scale Hybrid Materials for energy and
environmental technologies; Synthesis of hydrogen and liquid fuels from biomass and
municipal solid wastes; Clean fossil energy conversion systems; Electrostatic charging
phenomena in multiphase flows and electrostatic tomography; Particle technology and
Fluidization.
Enhanced Water-Gas Shift Reaction in the Presence of a Mg(OH)2 Slurry
in a High Pressure Aqueous System
This study investigated the integration of slurry phase Mg(OH)2 carbonation with the water gas shift
reaction (WGSR) at temperatures up to 215 oC with a 0.5 wt% platinum on alumina catalyst. The removal of
CO2 by the carbonation reaction enhanced hydrogen yield of the WGSR as the equilibrium of the gas phase
reaction was shifted towards products. Aqueous Mg(OH)2 carbonation has been shown to occur readily, and
various metastable and stable magnesium carbonates are formed depending on the reaction conditions
(primarily driven by temperature). This study revealed that the H2 yield was enhanced in the presence of
Mg(OH)2 slurry, and more interestingly the unexpected conversion of CO to aqueous formate ion was
observed, which did limit the overall production of H2. The presence of the basic aqueous phase within the
reactor promoted a side reaction between CO and hydroxide ions. The formate can persist in solution or
decompose to yield H2 depending on the solution conditions. The solid and liquid components of the
reacting slurry were carefully analyzed for carbonate and formate in order to investigate the reaction
mechanisms.
Page 102
Tuesday Oct.13 (M203)
Chair : Alissa Park and Qingshan Zhu
Afternoon
Title
Name
13:30-14:10
S10-K1
Chemical Looping Processes: Role of
Fluidization and Particle Science (J0160)
Liang-Shih
Fan
14:10-14:50
S10- K2
Speeding Up Reactive Modeling of
Fluidized Bed Reactor by Combining
CRE and Multiscale CFD (J0083)
14:50-15:20
S10- I1
15:20-15:30
15:30-16:00
16:00-16:30
16:30-17:00
S10-I2
S10-I3
S10-I4
DEM Validation via System-SizeIndependent Measurements (J0323)
Coffee break
Regular Bubble Pattern Formation in
Pulsed Fluidized Beds – From Exciting
Phenomenon to Fingerprint for Simulation
Method Validation (J0194)
A Novel Two-stage Fluidized Reduction
Process for Enhanced Synthesis of Fe
Nanoparticles (J0452)
3D Full-loop Simulation of
Hydrodynamics in a M-type Circulating
Fluidized Bed Boiler (J0082)
Affiliation
The Ohio
State
University
Institute of
Process
Wei Wang
Engineering,
CAS
Christine
University
Hrenya
of Colorado
MarcOlivier
Coppens
University
College
London
Institute of
Process
Jun Li
Engineering,
CAS
Institute of
Process
Nan Zhang
Engineering,
CAS
Wednesday Oct.14 (M203)
Chair : Marc-Olivier Coppens and Fei Wei
Morning
8:30-9:10
S10-K3
Title
Enhanced Water-Gas Shift Reaction in the
Presence of a Mg(OH)2 slurry in a High
Pressure Aqueous System (J0386)
9:10-9:50
S10-K4
Improve bubble size estimation by
pressure fluctuation analysis in gasfluidized beds (J0387)
9:50-10:20
S10-I5
Fluidized bed direct reduction for the
Panzhihua titano magnetite (J0106)
Name
Affiliation
Ah-Hyung
Park
Columbia
University
Mao Ye
Qingshan
Zhu
Dalian
Institute of
Chemical
Physics,
CAS
Institute of
Process
Engineering,
CAS
Page 103
10:20-10:30
10:30-11:00
11:00-11:30
11:30-12:00
Coffee break
S10-I6
Thinking Small with Fluidization Scale
Up (J0291)
Raymond
Cocco
Particulate
Solid
Research,
Inc. (PSRI)
S10-I7
Micro fluidized bed applied in catalytic
tests of selective oxidative
dehydrogenation of isopentene to isoprene
(J0312)
Qi Wang
Tsinghua
University
S10-I8
Multifluid Modeling of Low-rank Coal
Pyrolysis in a Downer Reactor (J0038)
12:00-13:30
Institute of
Process
Zhan Shu
Engineering,
CAS
Chair : Raymond Cocco and Wei Wang
Afternoon
Title
13:30-14:10
S10-K5
14:10-14:40
S10- I9
14:40-15:10
S10- I10
15:10-15:20
Page 104
Affiliation
China
University
Development and Commercialization of a
Mengxi Liu
of
Gas-solid Airlift Loop Reactor
Petroleum
(Beijing)
Institute of
Modeling the Hydrodynamics of
Process
Cocurrent Gas-solid Downward Flow
Xinhua Liu
Based on Energy-minimization MultiEngineering,
scale (EMMS) Theory (J0040)
CAS
Institute of
Dynamic Multi-scale Simulation of GasProcess
solid Flows Using Spatially Coupled Two- Xizhong
fluid Model and Discrete Particle Method
Chen
Engineering,
(J0037)
CAS
Coffee break
Particle Self-assembly for 3D Structured
Coatings (J0189)
Functional Uniform Microparticles
Tailored by a Novel Spray Drying
15:50-16:20 S10-I12
Technology (J0235)
15:20-15:50
Name
S10-I11
James
Gilchrist
Lehigh
University
Duo Wu
Soochow
University
Symposium 11- Petrochemicals and Fine Chemicals (M104)
Symposium 11- Petrochemicals and Fine Chemicals
Chairs: Jinsen Gao, [email protected]; Xiaojun Peng, [email protected]
Bipin Vora, [email protected]; Jim Johnson, [email protected]
Featured Speakers
Yi Xiao
M104, Yifu Building
Prof. Dr. Yi Xiao graduated from Tianjin University Fine Chemical Engineering, and
he received his Ph.D. degree (2003) in Fine Chemicals at Dalian University of
Technology Department of Applied Chemistry, then, he joined the Japan's National
Institute of Industrial Science and Technology as a Postdoctoral(2003-2004). He
currently is a professor in Fine Chemical Engineering at Dalian University of
Technology. His main research interest focuses fluorescent sensors and organic
semiconductor.
Development and applications of long wavelength BODIPY fluorescent dyes
BODIPY is one of the famous families of fluorescent dyes. BODIPY dyes take advantages of high
fluorescence quantum yields and high photostability over many other fluorescent dyes. Hence,
BODIPYs are popular in various fields. Especially, they are important fluorophores to develop molecular
probes or sensors extensively applied in life sciences. Recently years, BODIPYs have also found new
applications such as donor materials in thin-film solar cells. The limitation of most BODIPYs is the
relatively short wavelength excitation/emission, which is likely interfered by biological background
fluorescence and is also not favorable to match the solar light spectrum. Our group have rationally
developed a series of long wavelength (from red to NIR) BODIPY with tunable photophysical properties.
And we apply them in different ways, e.g. laser dyes, fluorescent probes, solar cells etc. In this
presentation, I would like to report these works.
Zhenghong Luo
M104, Yifu Building
Prof. Dr. Zhenghong Luo currently worked in department of Chemical Engineering
at Shanghai Jiao Tong University. His research interests focus on multi-phase flow
reaction engineering, polymerization reaction engineering, functional polymer
chemistry and chemical engineering, chemical process simulation and optimization.
Effect of Copolymer Composition on pH-Responsive Surface Wettability:
Identifying the Best Copolymer for Efficient Water/Oil Separation
Used polymer as case, this study aimed to fabricate reversible pH-responsive polymeric surfaces for
controllable wettability and to identify the best copolymer for water/oil separation from the chemical
product engineering viewpoint. To attain this aim, three block copolymers with different PAA segment
lengths were synthesized for the first time through Cu(0)-mediated reversible-deactivation radical
polymerization and hydrolysis reaction. pH-induced controllable surface wettability was achieved by spincoating the resulting block copolymers onto silicon wafers. Results showed that the pH-responsive wetting
behavior was introduced by incorporating the PAA block, and that the responsiveness of as-fabricated
surfaces was greatly influenced by PAA content. All three evolutions of water contact angle with pH shared
a similar inflection point at pH 5.25. Furthermore, a simple solution-casting technique was developed to
functionalize the stain steel meshes (SSMs) by using the as-prepared block copolymers to separate layered
water/oil mixtures.
Page 105
Page 1
Jennifer Holmgren
M104, Yifu Building
Dr. Jennifer Holmgren is the Chief Executive Officer of LanzaTech. Jennifer has
over 20 years of experience in the energy sector including a proven track record
in the development and commercialization of fuels and chemicals technologies.
Prior to joining LanzaTech, she was Vice President and General Manager of the
Renewable Energy and Chemicals business unit at UOP LLC, a Honeywell
Company. In that role, she led UOP’s renewable business from its inception
through to the achievement of significant revenues from the commercialization
of multiple novel biofuels technologies.
Carbon Recycling to Produce Valuable Commodities
LanzaTech offers an innovative biosynthesis approach and has developed and scaled a complete
process platform to allow the continuous biological production of fuels and an array of chemical
intermediates from gases at scale. Exceptional feedstock flexibility and metabolic diversity make
LanzaTech’s gas fermenting microbe unique. The ability to utilize gases relies on a unique redox chemistry
and energy conservation mechanisms that are not possible in standard hosts as E. coli or yeast. In order to
maximize the value that can be added to the array of gas resources that the LanzaTech process can use as
an input, the company has developed a robust genetic toolbox to allow the carbon and energy consumed by
its proprietary gas fermenting microbe to be channeled into a spectrum of valuable chemicals. This has
allowed LanzaTech to develop chassis strains with optimized production and multiple proprietary strains for
synthesis of non-natural products via novel routes. LanzaTech has demonstrated synthesis of over 25 new
products from gas fermentation, including fuels ethanol or platform chemicals as 2,3-Butanediol (2,3-BDO),
a four-carbon alcohol that can be catalytically converted to bio butadiene.
Zhichang Liu
M104, Yifu Building
Zhichang Liu is a professor in Chemical Engineering of China University of
Petroleum, Beijing. He received PhD degree from Shanxi Institute of Coal
Chemistry, Chinese Academy of Sciences (1999). Winner of the Outstanding
Young Scientists Fund. His main research interests focus on ionic liquid catalyst
and compound ionic liquid.
New alkylation process-Composite Ionic Liquid Alkylation(CILA)
Chloroaluminate ionic liquids (ILs) [1] were discovered as potential alternatives for the traditional isobutane
alkylation catalysts (HF and H2SO4). A composite ionic liquid (CIL) developed by China University of
Petroleum[2] shows good catalytic performance for isobutane alkylation.The first commercial 100 kt/a CILA
plant was succesfully started-up in 2013 in Shandong by Deyan Chemical Co., Ltd.. Thus far, the plant has
been running stably over two years. This plant includes four sections, namely feed treatment, staged
reactors, reactor refrigeration and product treatment. In addition, this plant also has CIL handling facilities to
enable solids removal and CIL regeneration. The typical composition of C4 feed during this time is listed in
Table 1. The result showed that: the olefin conversion was 100%; the alkylate yield was 80% of feed; the
average RON of alkylate was 96.8; the catalyst consumption per ton alkylate was 5 kg; the energy
consumption per ton alkylate was 150 kgEO. Table 2 shows the typical mass balance of the plant. It shows
that the CILA plant has safety and environmental benefits compared with HF and H2SO4 alkylation
processes.
Page 106
Symposium 1Advanced Technology
for Air Separation
Symposium
11- Petrochemicals
and and
FinePurification
Chemicals( C201)
(M104)
Chair : Jinsen Gao, Bipin Vora
Afternoon
S1113:30-14:10
14:10-14:40
14:40-15:10
K1
S11I1
S11I2
Title
Name
Affiliation
Advances in Petrochemical Technology
(K0334)
James
Johnson
UOP LLC
Xiang Ma
ECUST
Liang Zhao
China
University of
Petroleum
(Beijing)
Yi Xiao
Dalian
University of
Technology
Stimuli-Responsive Functional
Supramolecular Polymers in Aqueous
Solution (K0459)
K-edge XANES and DFT studies of
mechanism of reactive adsorption
desulfurization of thiophene on Ni/ZnO
(K0543)
15:10-15:20
15:20-16:00
16:00-16:30
16:30-17:00
Coffee break
S11K2
S11I3
S11I4
Development and applications of long
wavelength BODIPY fluorescent dyes
(K0282)
Development of Biodegradable Anionic
Detergent (K0381)
New Process Technologies for Conversion
of Acetic Acid to Ethanol or Acrylic Acid
(K0382)
Retired
Bipin V. Vora UOP/Honeyw
ell Fellow
Ralph
Gillespie
Celanese
Corporation
Title
Name
Affiliation
Carbon Recycling to Produce Valuable
Commodities (K0449)
Jennifer
Holmgren
LanzaTech Inc.
Chair : Xiaojun Peng, Jim Johnson
Morning
8:30-9:10
9:10-9:40
9:40-10:10
10:10-10:20
S11K3
S11I5
S11I6
Hindered diffusion of sulfur-containing
compounds in residue fractions through
membranes and catalyst (K0572)
Zhentao
Chen
Construction of Functional MoleculesPlasmonic Nanoparticle for Colorimetric
Recognition (H0445)
Jianjun Du
China
University of
Petroleum
(Beijing)
Dalian
University of
Technology
Coffee break
Page 107
10:20-11:00
11:00-11:30
S11-K4
S11-I7
China
New alkylation process-Composite Ionic Zhichang
University of
Liquid Alkylation(CILA) (K0499)
Liu
Petroleum
Design of interconnected ion conductive
Xuemei
channels for fuel cells
Wu
Dalian
University of
Technology
11:30-12:00
S11-I8
12:00-13:30
Separating Olefins from Sulfur in FCC
Gasoline Mid-Cut (K0390)
Zhepeng
Liu
GTC (Beijing)
Technology
Inc.
Name
Affiliation
Chair : Xiaojun Peng, Jim Johnson
Afternoon
Title
Preparations and applications of Ni2P-
13:30-14:10
S11-K5
based catalytic materials for hydrogen
China
Chen
University of
guang Liu
Petroleum
evolution (K0530)
14:10-14:40
S11-I9
14:40-14:50
(East China)
Fluoresecein-based sensors for metal ions Xiaoqiang Nanjing Tech
and biological rargets
Chen
Coffee break
Effect of Copolymer Composition on pH-
14:50-15:30
S11-K6
Responsive Surface Wettability:
Zheng
Identifying the Best Copolymer for
hong Luo
Efficient Water/Oil Separation
15:30-16:00
University
S11-I10
High Throughput Testing of Naphtha
Reforming Catalysts (K0383)
Alfred
Haas
Shanghai Jiao
Tong
University
hte GmbH
China
16:00-16:30
S11-I11
A hybrid absorption-adsorption method
for separating gas mixtures
Pei Liu
University of
Petroleum
(Beijing)
Page 108
Symposium 12- Process Development and Optimization (M103)
Symposium 12- Process Development and Optimization
Chairs: Feng Qian, [email protected]; Guangsheng Luo, [email protected]
Joe Qin, [email protected]; Michael Baldea, [email protected]
Featured Speakers
Frank Zhu
M103, Yifu Building
Dr. Frank Zhu, a leading expert in industrial process design, modeling, and energy optimization, is a Senior
Fellow of UOP. During his tenure at UOP, he has helped several major refinery companies achieve
significant energy savings by applying energy management systems, led designs of several most efficient
refinery plants, implemented energy optimization into UOP engineering process, and led R＆D projects
achieving major breakthroughs. His latest book "Energy and Process Optimization for the Process
Industries" is jointly published by Wiley and AIChE in 2014.
Molecular Modeling Creates News Ways for Process Design and
Operation Optimization
The capability of obtaining molecular information and molecular models provides a new platform
for developing new catalysts and novel process designs as well as optimizing existing assets for refining
and petrochemical processes. The theory of molecular management and applications will be introduced
with practical examples.
Yu Qian
M103, Yifu Building
Dr. Yu Qian is Chair Professor of Chemical Engineering at South China
University of Technology, the Director of the Center for Process Systems
Engineering. His research interests are modeling and Integration of process and
operation, Life cycle analysis and sustainability study of the chemical/energy
processes. Dr. Qian received his BSc, MSc, PhD degrees from Tsinghua
University in Beijing. After his post-doctoral research experience in the
Norwegian Institute of Technology in 1989-1991, he became a Research
Associate Fellow at the University of British Columbia in Vancouver, Canada. In
1994 he was appointed as a full professor at South China University of
Technology, where he served as the Dean of the School of Chemical Engineering
during 2002-2012. Dr. Qian has been the Deputy Director of the Chinese
Institute of Computer Aided Process Engineering since 2005.
Coal based processes development and integration for better resource utilization
and less environmental impacts
In this presentation, Multi-dimensional technical-economical-environmental-social models are built for
quantitative sustainability and life cycle assessment of alternative coal processes from feedstock, to
production, market, and recycling; to rationalize the decision-making on resource allocation and process
design; and finally, to raise efficiency and minimize environmental impacts of existing and potential
alternative coal based processes. A number of coal gasification syngas derived energy and chemical product
chains are taken as benchmark cases in this work. With integration and optimization of the mass and energy
network, coal based processes with higher CO2 capture rate and higher CO2 purity for commercial use could
improve environmental and economic performance a lot.
Page 109
Xigang Yuan
M103, Yifu Building
Xigang Yuan is Professor of Chemical Engineering and Director of Chemical Engineering
Research Center at Tianjin University. He is director of the Distillation Laboratory of the
State Kay Laboratory of Chemical Engineering at Tianjin Universty. He is a member of the
Council of the Chemical Industry and Engineering Society of China, the Fellow of
the IChemE (Institution of Chemical Engineers UK), member of the Fluid Separation
Working Party of the European Federation of Chemical Engineering, member of the
Process Systems Engineering Committee of the Systems Engineering Society of China,
and member of editorial board of Chiness Journal of Chemical Engineering. Professor
Yuan’s research interests are in the areas of mass transfer in chemical processes,
separation engineering, process systems engineering and computational mass transfer
and fluid dynamics for chemical engineering.
Computational mass transfer approach to chemical process simulation
In the present presentation, two kinds of theoretical models, namely: isotropic model and anisotropic
model, for convective mass transfer in multiphase turbulent flow systems are summarized. In the isotropic
model, a two-equation model is proposed based on the Boussinesq hypothesis to calculate the turbulent
diffusivity. While in the anisotropic model, a Reynolds mass flux model is derived, and the assumption of an
isotropic turbulent diffusivity introduced by the Boussinesq postulation can be eliminated. Then,
computational mass transfer approach is developed based on the theoretical models. The proposed
approach is finally validated by simulating chemical processes including distillation and fluidized bed
reaction. The advantages of the proposed method in avoiding empirical parameters utilization, like in some
traditional methods, and some other features are discussed.
Yongrong Yang
M103, Yifu Building
Professor Yang Yongrong was born in 1962 who now works as the research fellow in
UNILAB, Zhejiang University, executive chief editor of Chemical Reaction Engineering
and Technology journal. The main research field concerns multiphase flow reaction
engineering, polymerization engineering and process system engineering. Professor
Yang has completed successfully 863 Programs and projects from National Natural
science foundation. In the recent five years, Professor Yang has published more than
fifty SCI papers and been authorized more than forty patents. The Industrial Application
of Condensation Mode in Gas Phase Polyethylene Process project was awarded second
prize of Nation Award for Science and Technology Progress and Process Package for a
300 Thousand Tons LLDPE per year by Gas Phase Process was awarded the first prize of
Science and Technology Progress Award of SINOPEC
Page 110
Joe Qin
M103, Yifu Building
Dr. S. Joe Qin is Vice President of the Chinese University of Hong Kong, Shenzhen,
and is on leave from the position of Fluor Professor of Process Engineering at the
Viterbi School of Engineering of the University of Southern California.
Dr. Qin is a Fellow of IEEE and Fellow of the International Federation of Automatic
Control (IFAC). He is a recipient of the National Science Foundation CAREER Award,
the 2011 Northrop Grumman Best Teaching award at Viterbi School of Engineering,
the DuPont Young Professor Award, Halliburton/Brown & Root Young Faculty
Excellence Award, NSF-China Outstanding Young Investigator Award, Chang Jiang
Professor of Tsinghua University, Thousand Talent Professor of the Northeastern
University of China, and an IFAC Best Paper Prize for the model predictive control
survey paper published in Control Engineering Practice.
Big Data Process Analytics
In normally-operated engineering systems where processes, units, and equipment are designed with specific
purposes, mechanistic models and first-principles are dependable. However, for the operation of emerging or
abnormal situations that are not anticipated in the design, operation data become indispensable assets for the
decision-making in safe and efficient operations. In this talk we offer a perspective on the essence of process
data analytics, how data have been effectively used in process operations and control, and new perspectives on
how process systems operations might evolve to a paradigm of data-enhanced operations and control. The
discussed perspectives include i) mining of time series data for event discovery, decision-making, and causality
analysis; ii) exploring the power of new machine learning techniques that have enjoyed tremendous
development in nearly two decades; and iii) anticipating a system architecture shift towards a data-friendly
information system.
Xiao Feng
M103, Yifu Building
Xiao Feng is a professor of Chemical Engineering at Xi’an Jiaotong University, China.
Her research interests lie in process integration and include energy, water and
hydrogen system integration, by graphical method and mathematical programming.
Prof. Feng is an author on over 200 archival publications and two books and the
Vice-Chair of the Thermodynamics and Engineering Application Committee, China
Energy Research Society, Standing Director of Chinese Chemical Education Society,
and Director of Process System Engineering Society, Chinese System Engineering
Society.
Optimization of recirculating cooling water systems with
coupling cooler and pump networks
Re-use of cooling water between different coolers has been proved to be an effective way to reduce
flowrate of cooling water. However, the coolers with series configurations require a higher pressure head of the
corresponding branch pipe, which may result in more pump power needed. On the other hand, the pumps for
transporting cooling water from a cooling tower to each cooler traditionally are installed in the header line of
the feed pipe, constituting main pump network. The pressure head of the main pumps must be large enough to
satisfy heat loads and pressure heads of all coolers. The pressure drop of parallel branch pipes must be balanced
by turning down the opening of valves for some coolers, which causes energy penalty of pumps. In order to
minimize power consumption, a novel methodology is proposed to simultaneously consider pump arrangement
in the pump network and cooling water reuse exploration in the cooler network. The total annualized cost of
cooling water systems is taken as the objective function. A superstructure of cooling water systems is developed
to consider the interactions between the performance of pumps and the design of cooler network.
Page 111
Chair : Feng Qian, Joe Qin
Afternoon
Title
Name
13:3014:10
S12-K1
Molecular Modeling Creates News Ways
for Process Design and Operation
Optimization (L0266)
Frank Zhu
14:1014:40
S12-I1
Integrated Control System Harmonic to
Batch Process Natures
Furong
Gao
Affiliation
UOP LLC, A
Honeywell
Company
Hong Kong
University of
Science and
Technology
14:4015:10
Liquid-liquid microflow for fast
chemical reaction processes
(L0515)
Yangcheng
Lu
Tsinghua
University
Yu Qian
South China
University of
Technology
Xi Chen
Zhejiang
University
Zhen Liu
LIST AG
Switzerland
Title
Name
Affiliation
S12-K3
Big Data Process Analytics
Joe Qin
USC
S12-I5
Total site water-using system design for
industrial parks (L0555)
Jian Du
Dalian
University of
An integrated model for industrial
catalytic ethylene polymerization
reactors (L0591)
Zhou Tian
S12-I2
15:1015:20
Coffee break
15:2016:00
S12-K2
16:0016:30
S12-I3
16:3017:00
S12-I4
Coal based process development and
integration for better resource utilization
and less environmental impacts (L0482)
Large Scale Simulation and Optimization
of a Polymerization Process with
Embedded Molecular Weight
Distributions (L0534)
Efficient Processing in the concentrated
Phase (L0088)
Chair : Guangsheng Luo, Michael Baldea
Morning
8:30-9:10
9:10-9:40
9:40-10:10
10:1010:20
Page 112
S12-I6
Coffee break
Technology
ECUST
10:20-11:00
11:00-11:30
11:30-12:00
S12-K4
Computational Mass Transfer Approach
to Chemical Process Simulation (L0521)
S12-I7
Pseudo-transient Methods for EquationOriented Flowsheet Simulation and
Optimization (L0157)
Michael
Baldea
S12-I8
Modeling the oxidation kinetics of
hydrocarbon in liquid phase based on
reaction mechanism (L0462)
Ling
Zhao
ECUST
Title
Name
Affiliation
S12-K5
Progress on olefin polymerization
process technology in China
Yongrong
Yang
Zhejiang
University
S12-K6
Optimization of recirculating cooling
water systems with coupling cooler and
pump networks
Xiao
Feng
Xi'an
Jiaotong
University
S12-I9
Advanced Design Optimization of
Combustion Equipment for BioEnergy
Systems Using Sculptor® with CFD
Tools (L0395)
Joseph
Smith
Missouri
University of
Science and
Technology
S12-I10
Optimization and control technology for
maximizing high added-value product of
ethylene plants
Wenli
Du
ECUST
12:00-13:30
Xigang
Yuan
Tianjin
University
The
University of
Texas at
Austin
Chair : Ling Zhao, Michael Baldea
Afternoon
13:30-14:10
14:10-14:50
Coffee break
14:50-15:00
15:00-15:30
15:30-16:00
Page 113
Symposium 13-Thermodynamics and Transport Phenomena (C209)
Symposium 13-Thermodynamics and Transport Phenomena
Chairmen: Honglai Liu, [email protected]; Xiaohua Lu, [email protected]
Glenn Lipscomb, [email protected]
David Rumschitzki, [email protected]
Randall Snurr
Tuesday Oct.13, 8:30-9:10 AM
C209, Yifu Building
Randy Snurr is the John G. Searle Professor of Chemical and Biological Engineering at
Northwestern University. He holds BSE and PhD degrees in chemical engineering
from the University of Pennsylvania and the University of California, Berkeley,
respectively. From 1994-95, he performed post-doctoral research at the University of
Leipzig in Germany supported by a fellowship from the Alexander von Humboldt
Foundation. Other honors include a CAREER award from the National Science
Foundation, the Leibniz professorship at the University of Leipzig in 2009, and the
2011 Institute Award for Excellence in Industrial Gases Technology from the
American Institute of Chemical Engineers.
Molecular Modeling, Screening, and Design of Metal-organic Frameworks for Gas
Storage and Separation Applications
Metal-organic frameworks (MOFs) are an interesting class of nanoporous materials synthesized in a
“building-block” approach from inorganic nodes and organic linkers. Some of the most intensively studied
applications are related to solving energy and environmental problems, including hydrogen and natural gas
storage for cleaner vehicles, capture of CO2 from power plant exhaust, and energy efficient separations.
Because of the predictability of MOF synthetic routes and the nearly infinite number of possible structures,
molecular modeling is an attractive tool for screening new MOFs before they are synthesized. Modeling can
also provide insight into the molecular-level details that lead to observed macroscopic properties. This talk
will illustrate how molecular modeling and high-throughput computational screening can be used to
discover, develop, and ultimately design new MOFs for desired gas adsorption applications.
Shiang-Tai Lin
C209, Yifu Building
• Lin is a full professor at the Department of Chemical Engineering, National
Shiang-Tai
Taiwan University. Dr. Lin’s research focuses on the determination of thermophysical
properties of materials from the combined use of statistical mechanical theory and
modern computational chemistry. Specific examples include the phase equilibria of
fluids, the equilibrium and kinetic properties of gas hydrates, the efficiency of polymer
photovoltaic. His research works have been published in over 90 peer-reviewed journals.
Dr. Lin’s research team was the recipient of the Best Poster APJ award in the
APCChE2010, and the champion of the 5th Industrial Fluid Property Simulation
Challenge in 2008.
From First Principles to Fluid Phase Equilibria
The knowledge of thermodynamic properties of fluids is critical for the design, development, and
optimization of relevant chemical processes. However, the collection of such data via experimental
approaches can be very time-consuming or even impractical in some areas, such as drug discovery where
properties of thousands to millions of chemicals are investigated. Recent advances in the quantum physical
and quantum chemical theories open up possibilities to obtain these important properties without resorting
to any experimental measurement. However, there are challenges remain such as the need for
overwhelming computational resources for industrial problems and the insufficient chemical accuracy for
phase equilibrium predictions. In this talk, we present approximate methods for fluid property predictions
that utilize results from quantum chemical solvation calculations. The method we have developed is general
and can be used to determine all aspects of properties of a chemical or a mixture of chemicals under almost
any conditions.
Page 114
Symposium 13-Thermodynamics and Transport Phenomena(C209)
Jianguo Wang
C209, Yifu Building
• Jianguo Wang is the leader of Molecular Catalysis and Computational
Prof.
nanoMaterials Group , Zhejiang University of Technology. He received his B.Sc,
M.Sc and Ph.D degree in Central South University, Nanjing University of Technology
and Tianjin University, respectively. From 2004 to 2008, he worked as postdoctoral
researcher at University of Aarhus, Denmark and Princeton University, USA. In 2008,
Dr. Wang jointed Zhejiang University of Technology as Qianjiang Professor of
Zhejiang Province.
Reaction and Diffusion on Supported Metal Nanocatalysts
Supported noble metal catalysts have played an important role in the conversion of energy and resources.
During the recent years, we have systematically investigated: (1) The diffusion and reaction on hydrophobic
carbon and hydrophilic TiO2 supported noble metal catalysts by means of density functional theory
calculations and molecular dynamics simulations. Size effect has been regularly utilized to tune the catalytic
activity and selectivity of metal nanoparticles(NPs). At present, it is still a computational challenge to directly
simulate the catalytic properties over different sizes of metal nanoparticles. Therefore, a simple method to
describe the relationship between the noble metal particle size and catalytic properties is developed. (2)
The preparation of different size Pd catalysts s on carbon and TiO2 by the controlling the interaction
between metal and support. (3) The application of Pd/C nanocatalysts on halogenated nitrobenzene
selective hydrogenation, CO2 reduction.
Chunshang Li
C209, Yifu Building
Professor of Institute of Process Engineering (IPE), Chinese Academy of Sciences
(CAS).
Structure-Property Relationship in Ionic Liquids
A systematic property database are established by us and near 4000 ILs are contained. The new
thermodynamic models based on the ionic fragment contribution-corresponding states (FCCS) are
developed to predict the physicochemical properties of ILs and phase equilibrium of IL-containing mixtures.
The contribution values of io、nic fragment can be expected to be estimated by quantum chemistry (QC)
method. In structural investigation, the non-covalent interactions are the underlying aspect in determining
the properties of ILs. Based on the QC calculation, it is found that the hydrogen bond is very critical to
pairing, packing and assembly, although the electrostatic force was stronger ions. The properties such as
melting point, viscosity and enthalpy are correlated with the hydrogen bond forces. The force fields of new
ILs were developed and the properties of density, viscosity, conductivity and so on were predicted by
molecular dynamic (MD) simulation. It is found that the nano-clusters in some ILs induce the charge
redistribution and the aggregation of polar-heads. The clusters are changeable dynamically and show rodlike
and vesicle structures with the different concentrations.
Page 115
Doraiswami Ramkrishna
C209, Yifu Building
Doraiswami Ramkrishna, Harry Creighton Peffer Distinguished Professor of
Chemical Engineering at Purde University since 1994, obtained his B (Chem) Eng.
Degree from University of Mumbai in 1960, and his PhD in Chemical Engineering
from the University of Minnesota in 1965. Following his PhD, he was an Assistant
Professor for two years at Minnesota before returning to the India Institue of
Technology Kanpur where he served on the faculty for nearly seven years. He
returned to the United States in 1974 as a Visiting Associate Professor in 1974,
thereafter as a visiting professor at Minnesota in 1975 before joining Purdue
University as a Professor of Chemical Engineering in 1976. Professor Ramkrishna's
research group is motivated by ideas in the application of mathematics to solving
problems in chemical and biochemical reaction engineering, biotechnology and
biomedical engineering.
Population balance modeling: A ubiquitous tool for engineering analysis
Although the earliest use of population balances dates back to the days of Boltzmann, its status as a
ubiquitous modeling tool in engineering has come about only in relatively recent times. In particular, while
its importance began with conventional areas such as in modeling the behavior of commonly occurring
dispersed phase systems, its role in enabling extension to many modern exotic applications has been
spectacular. It is the purpose of this talk to expound the basic tenets of population balances with examples
drawn from traditional and current areas of application towards their further exploration.
Dapeng Cao
C209, Yifu Building
Dapeng Cao is a Professor and Director of the Division of Molecular and Materials
Simulation, State Key Laboratory of Organic-Inorganic Composites at Beijing
University of Chemical Technology (BUCT). He received his Ph D from BUCT in 2002,
and was a research scientist at NanoMaterials Technology Pte Ltd in Singapore
(2002-2003) and a postdoctoral researcher at the University of California at
Riverside (2003-2005). His research interests are focused on the designed synthesis
and applications of functional materials, including porous luminescent polymers and
energy conversion and storage materials related to fuel cells supercapacitors and
solar cells. Currently, he is the Editorial Board Members of 《Scientific Reports》,
《ISRN Chemical Engineering》 and 《American of Macromolecular Science》. He
has published more than two hundred articles in journals such as 《J. Am. Chem.
Soc.》, 《Angew. Chem. Int. Ed.》, 《Adv. Mater.》, 《Energy Environ. Sci.》.
Multiscale Simulation Designed Synthesis of Nanostructured Porous Materials in
It has become increasingly clear that hydrogen as a viable energy carrier may play an important role in
future energy plans. However, development of reasonably safe and reversible hydrogen storage materials
for transportation is still a great challenge. In this work, we present the scheme of designing novel
materials and address the multiscale simulation method, in which the first-principles calculation is
performed to calculate the interaction energy between adsorbate and adsorbent, and then the interaction
is input to grand canonical Monte Carlo (GCMC) simulation for evaluation of hydrogen storage capacities.12 By using the multiscale simulation method proposed, a series of novel materials are designed. These
materials include new carbon allotrope - diamondyne, silicon nanotube (SiNT), silicon Li12Si60H60 fullerene,
Li-doped covalent organic frameworks (COFs), Porous aromatic Frameworks (PAFs). Furthermore,
hydrogen storage capacities of these materials are also investigated. In addition, we also proposed a
targeted synthesis method to fabricate the nitrogen-doped graphene analogue materials for oxygen
reduce reaction (ORR), in which we used the well-defined 2D covalent organic polymers as targeted
template and then carbonized the targeted materials for in situ synthesis of nitrogen-doped porous
carbons. These synthesized porous carbons are excellent metal-free electrocatalysts for ORR.
Page 116
Shuangliang Zhao Wednesday Oct.14, 15:20-16:00 PM
C209, Yifu Building
Shuangliang Zhao received his Ph.D. degree from Ecole Normale Superieure de
Lyon, France in 2007, and after postdoctoral periods in Ecole Normale
Superieure, Paris (2008-2009) and University of California at Riverside (20102011), he joined the Department of Chemical Engineering in East China
University of Science and Technology as an associated professor. His research
area mainly focuses on molecular modeling and equilibrium/non-equilibrium
statistical mechanics theory.
Unified Framework of Multi-scale Density Functional Theories and
Its Recent Applications
Most chemical engineering processes involve complex multi-phase fluid systems, and their evolution
depends on the mechanism by which the inhomogeneous subsystems exchange information at
different length-scales. Whereas numerous theoretical methods with specific description accuracies
have been developed for investigating physicochemical properties of various fluid systems, a unified
theory that enables the investigation of mesoscale problems is still needed. In this talk, we present a
unified framework of multi-scale density functional theories (DFTs). In addition, the combinations of
those DFTs with each other and with other conventional theories and simulation approaches are also
discussed. Finally, general discussions on the up-to-date progress of DFTs and the expectations on their
further extensions are given.
Jian Zhou
C209, Yifu Building
Prof. Dr. Jian ZHOU is the leader of nano-bio interface engineering group at the
department of chemical engineering, South China University of Technology. He
received his Ph.D. degree (1998) of Chemical Engineering at Nanjing University of
Chemical Technology. Then, he had his postdoc research at Beijing University of
Chemical Technology, University of Washington and University of Utah during 19982005. He was appointed as a full professor in Chemical Engineering at South China
University of Technology since 2006. His research interest is multiscale simulation of
complex chemical and biological systems, including protein adsorption, smart
materials, adsorption and diffusion of confined fluids, self-assembling of soft
matters etc.
Multiscale Simulations of Protein Adsorption
Protein adsorption plays an important role not only in a wide range of basic biological processes but also in
many applications such as protein chromatography, drug delivery on solid substrates, biosensors, biofuel
cells and biomaterials. For these processes and applications, one key issue is the orientation of adsorbed
proteins on surfaces. Another key issue that determines the activity of adsorbed proteins is their
conformation (i.e., how the conformation of the adsorbed protein resembles that of its native state). In this
talk, the protein orientation and conformation on charged surfaces are investigated by a hierarchical
approach, i.e., studied by colloidal, coarse-grained and all-atom models. It is found that the electric dipole
and hydrophobic dipole of adsorbed proteins play important roles in determining the protein orientation on
charged and hydrophobic surfaces.
Page 117
Yudan Zhu
C209, Yifu Building
Yudan Zhu was born in China in 1982. She received her Ph.D. degree (2010) in
Chemical Engineering at Nanjing Tech University (Used name: Nanjing University of
Technology), then, she joined the group of professor Xiaohua LU. She currently is an
associate professor in Chemical Engineering at Nanjing Tech University . Her main
research interest focuses on nanoconfined fluid molecule behaviors using molecular
simulation for nanoporous material applications. She is the project leader of two
National Natural Science Foundations of P.R. China (Youth Program and General
Program )
Molecular simulations on nanoconfined fluid molecule behaviors
for nanoporous material applications
Nanoporous materials (e.g. membranes and catalysts) applications have been increasingly applied in energy
and environmental fields. Material performance is largely dependent on structure. Most applications of
nanostructured materials involve fluids. The properties of bulk fluids are independent of their
microstructure; hence, classical phase equilibrium and transfer mechanism based on the continuum model
can be applied. However, a decrease in the molecule number of fluids confined within the nanostructure
enhances the influence of material interfacial properties on fluid molecule behaviors. Thus, the properties
of nanoconfined fluids are different from those of bulk fluids. The behaviors and microstructures of
nanoconfined fluids are closely related, which make the continuum model frequently invalid at the
nanoscale. To establish the structure–property relationship of nanoporous materials, not only the structures
of materials themselves, but also the microstructures of nanoconfined fluids are required to be explored.
Our group carried on a series molecular simulation studies of nanoconfined fluid molecules behavior for
many years to understand what indeed we can learn from molecular simulations of nanoconfined fluid
molecule behaviors and how these understandings could promote the nanoporous material applications.
Theodore Tsotsis
C209, Yifu Building
Theodore Tsotsis is Professor of Chemical Engineeringis and Holder of Robert E. Vivian
Chair in Energy Resources. He is expert in high temperature reactions, with
applications to landfill remediation and other environmental issues.He is also
Consultant to ALCOA, UNOCAL and U.S. Department of Energy and Holds several
patents on reaction engineering methods.
Microporous Inorganic Membranes for Conventional and Reactive Separations
Microporous inorganic membranes are attracting today substantial research interest due to their potential
for finding widespread use in a number of high-temperature conventional and reactive separation
applications of interest in the Energy field. In our group the emphasis has been on carbon molecular sieve
and SiC membranes. The preparation and characterization of these materials presents significant technical
challenges. Issues of membrane preparation, reproducibility, and robustness to the proposed application
environments remain of significant importance. In this talk, we will describe the techniques that we utilize
for the preparation and characterization of such microporous membranes. They involve a variety of surface
analytical techniques, TGA, and various chromatographic and mass spectrometric techniques useful for
characterizing the membrane structure, and its surface and bulk chemical composition. They are coupled to
transport and sorption experimental investigations, and molecular simulations of such processes. Combining
all these techniques helps to provide unique insight into the key factors that determine membrane
properties and performance. The use of these membranes in important reactive separations will be also
discussed.
Page 118
Tuesday Oct.13
Chair : Honglai Liu
Afterno
Title
Name
Affiliation
S13-K1
Molecular Modeling, Screening, and
Design of Metal-organic Frameworks
for Gas Storage and Separation
Applications
Randall
Snurr
Northwester
n University,
USA
S13- I1
Thermodynamic and Transport
Properties of Porous Materials for
Carbon Dioxide Separation
Shuguang
Deng
New Mexico
State
University
S13- I2
High-throughput Screening of Fluid
Adsorption in Metal-organic
Frameworks by Using a Classical
Density Functional Theory
Yu Liu
East China
University of
Science and
Technology
S13-K2
From First Principles to Fluid Phase
Equilibria
Shiang-Tai
Lin
National
Taiwan
University
S13-K3
Reaction and Diffusion on Supported
Metal Nanocatalysts
Jianguo
Wang
Zhejiang
University of
Technology
S13-I3
A Novel Multiscale Strategy for
Prediction of Phase Behaviors through
Distribution of Molecular
Conformations
on
13:3014:10
14:1014:40
14:4015:10
15:10Coffee break
15:20
Chair : Glenn Lipscomb
15:2016:00
16:0016:40
16:40-
17:10
Li
Yang
Wuhan
Institute of
Technology
Page 119
Wednesday Oct.14
Chair : David Rumschitzki
Morning
8:30-9:10
9:10-9:40
9:40-10:10
Title
S13-K4
S13-I4
S13-I5
Structure-property Relationships and
Physicochemistry of Ionic Liquids
Investigation of Lower Critical Solution
Temperature Transition of Poly Nvinylcaprolactam (PVCL)
Monte Carlo Simulations of Phase
Equilibria and Structural Properties of
Thiophene/[Bmim][PF6]/CO2
Name
Affiliation
Chunshang
Li
Institute of
Process
Engineering,
Chinese
Academy
Science
Xianghong University of
Qian
Arkansas
Yongping
Zeng
Yangzhou
University
Doraiswami
Purdue
Ramkrishna
University
10:10Coffee break
10:20
Population Balance Modeling. A
10:2011:00
S13-K5
Ubiquitous Tool for Engineering
Analysis
Anomalous Structures and Vibrational
11:0011:30
S13-I6
Spectra of Ethylammonium Nitrate Ionic
Jiangxi
Zhen Yang
Liquids in 1-nm Hydrophobic
Normal
University
Nanochannel
11:3012:00
S13-I7
DFT Study of Molecules Adsorption and
Reaction on Grapheme
12:0013:30
Page 120
Yingchun
Liu
Zhejiang
University
Chair : Randall Snurr
Afternoo
Title
Name
Affiliation
n
Beijing
Multiscale Simulation Designed
13:3014:10
S13-K6
Synthesis of Nanostructured Porous
University
Dapeng Cao
Materials in Chemical Engineering
of
Chemical
Technology
Equilibrium and Dynamic Properties of
14:1014:40
Thermodynamically Small Clusters:
S13- I8
Views at Both Atomistic and Colloidal
University
of
David Ford Massachuse
tts Amherst
Scales
Blood Pressure-driven Trans-artery Wall
14:4015:10
S13-I9
Water Flow and Early Atherosclerosis:
The Role of A Membrane Protein
David
Rumschitzki
City
College of
New York
15:10Coffee break
15:20
Chair : Jianguo Wang
Unified Framework of Multi-scale
15:2016:00
S13-K7
Density Functional Theories and Its
Recent Applications
East China
Shuangliang University
of Science
Zhao
and
Technology
The Interaction Between Nanoparticles
16:0016:30
S13-I10
Drug Delivery
Review on Modified Poisson-
16:3017:00
and Membranes: From Cytotoxicity to
S13-I11
Boltzmann (MPB) and Its Recent
Applications
Xianren
Zhang
Manman
Ma
Beijing
University
of
Chemical
Technology
Shanghai
Jiaotong
University
Page 121
Thursday Oct.15
Chair : Guangjin Chen
Morning
Title
Thermodynamics of Deformation and
8:30-9:10
S13-K8
Phase Transformations in Nanoporous
Adsorbents
9:10-9:40
S13-I12
Poroviscoelasticity in protein hydrogels
S13-I13
Large-scale molecular dynamics
simulation and online measurement of
thermal conductivity of bulk silicon and
silicon nanowires
9:4010:10
Name
Affiliation
Alexander
Rutgers
Neimark
University
Ruben
Mercade
Prieto
Soochow
University
Chaofeng
Hou
Institute of
Process
Engineering,
CAS
10:10Coffee break
10:20
Chair : Alexander Neimark
10:2011:00
S13-K9
S13-K10
Fluid Molecule Behaviors for
Effective Gas Separation Using
S13-I14
Membranes Based on Metal-organic
Frameworks
12:0013:30
Page 122
South China
University
of Technolog
y
Nanjing
Yudan Zhu
Nanoporous Material Applications
11:3012:00
Jian Zhou
Molecular Simulations on Nanoconfined
11:0011:30
Multiscale Simulations of Protein
Adsorption
Technology
University
Dahuan
Liu
Beijing
University of
Chemical
Technology
Chair : Dapeng Cao
Afternoon
Title
Name
Affiliation
China
13:3014:10
S13-K11
Natural Gas Hydrate and Carbon
Guangjin
Univerisity
Dioxide
Chen
of Petroleum,
Beijing
14:1014:40
S13-I15
CO2 Capture on Amine-Functionalized
Polymer Hollow Fiber Sorbents in Rapid
Temperature Swing Adsorption
Fateme
Rezaei
Modeling and Simulation of CO2
Chunyan
Capture from Biogas using aqueous
Ma
Missouri
University of
Science and
Technology
Nanjing
14:4015:10
S13-I16
Technology
University
15:10Coffee break
15:20
Chair : Shuguang Deng
15:2016:00
S13-K12
16:0016:30
S13-I17
Microporous Inorganic Membranes for
Theodore
Conventional and Reactive Separations
Tsotsis
Dynamics Study of Methane Dissociation
on Ni (111) Surface
Prediction of Liquid-Liquid Equilibrium
16:3017:00
for Ternary Solutions Based on the
S13-I18
COSMO-SAC and the Ising Lattice
Xiangjian
Shen
University of
Southern
California
Institute of
Chemical
Physics of
Dalian
East China
YongUniversity of
Ming WEI Science and
Technology
Model
Page 123
Symposium 14- Separation Technology (M106, No. 16 Building)
Symposium 14- Separation Technology
Chairs: Suojiang Zhang, [email protected]; Hualin Wang, [email protected];
Kamalesh K. Sirkar, [email protected]; Ralph Yang, [email protected].
Featured Speakers
William Koros
M106, No. 16 Building
William J. Koros is the GRA Eminent Scholar in Membranes and the
Roberto C. Goizueta Chair for Excellence in Chemical Engineering at
Georgia Institute of Technology. Professor Koros received his Bachelor's
degree in Chemical Engineering from The University of Texas in 1969 and
worked in the Engineering Department of the E. I. DuPont Company for
the next four years. He entered graduate school in 1973 and upon
completion of his studies in 1977 joined the faculty of the Chemical
Engineering Department at the North Carolina State University as an
Assistant Professor.
Diffusion Entropic Activation Factors: Maxwell’s Demons at Work
Chemical Engineering separation research has a long history with connections to the thermodynamic
and transport phenomena pioneers in our discipline. Advanced materials have become increasingly
important as vehicles explore separation options, with increasing attention being paid to energy
efficiency and process carbon footprints. Gas separations are highly energy-intensive processes when
based upon a traditional phase-change paradigm such as distillation or sorption processes. Membranes
avoid this paradigm by integrating molecularly selective partitioning and diffusive discrimination
between components into a single device. This integrative ability can change the separations landscape
by offering a full order of magnitude lower energy-intensity compared to phase-change separation
approaches. The selective partitioning feature is understandable in terms of well-known
thermodynamic factors. On the other hand, engineering diffusion selectivity usually relies upon tuning
relative diffusion activation energies of permeating species within the membrane. Unfortunately,
higher relative diffusion activation energies between similar penetrants are correlated with higher
absolute diffusion activation energies for both components. This correlation creates a natural tradeoff
in which dramatically lower permeabilities are typically seen for highly selective membranes. A new
approach, tuning the diffusion activation entropy associated with size-similar penetrants can avoid
major productivity losses if done properly.
Page 124
Jerry Lin
Dr. Jerry Y.S. Lin is a Regents‘ Professor at the Arizona State University in
Tempe. He also serves as editor of Journal of Membrane Science. Dr. Lin
was a professor of chemical engineering and co-director of the NSF Center
for Membrane Applied Science and Technology at University of Cincinnati
prior to joining ASU in January, 2005. Dr. Lin received B.S. (1982) from
Zhejiang University in China, and M.S. (1985) and Ph.D (1988) from
Worcester Polytechnic Institute in the U.S., all in chemical engineering. In
research, Dr. Lin has made significant contributions to the advancement of
inorganic membrane science and high temperature gas separation
technologies. As of
January, 2015 he has published over 255
refereed papers in chemical engineering and materials science SCI journals,
10 book chapters and 50 conference proceedings papers; he also holds
8 patents; his papers have received over 8400 SCI citations (with H-index
over 51) .
Carbon Dioxide Permeation Properties of Samarium-Doped-Ceria
Carbonatedual-phase membranes
High temperature CO2 perm-selective membranes can be used in a number of important separation
and reaction processes for hydrogen production or carbon capture. Oxygen ionic conducting metal
oxide and molten carbonate dual-phase membranes are the only membranes perm-selective to CO2 at
high temperatures with selectivity as high as 3000. This talk will discuss high temperature CO2
permeation properties of samarium doped ceria (SDC)-carbonate dual-phase membranes. Hermetic
SDC-carbonate membranes were prepared by infiltrating porous SDC ceramic support with Li/K/Na
molten carbonate. CO2 permeation/separation data for the SDC-carbonate membranes were then
obtained with either atmospheric or high pressure feed of CO2:N2 mixture or simulated syngas with
composition of 50% CO, 35% CO2, 10% H2, and 5% N2. The SDC-carbonate membranes exhibit CO2
permeation flux in the range of 0.2-0.8 mL(STP).cm-2.min-1 in 700-950oC with measured CO2 to N2
separation factor above 1000. CO2 permeation data through the SDC-carbonate membranes at
different upstream and downstream CO2 partial pressures were obtained.
Page 126
Xiangchen Fang
Dr. Xiangchen Fang received his phD degree on Chemical Engineering from East China
University of Science and Technology in 2005. He is now work as the director in Fushun
petroleum research institute, SINOPEC and part-time professor of school of chemical
engineering in ECUST. His research interest focus on the catalysis process and system
fabrication on petroleum refinery, especially the hydrogenation reforming,
hydrogenation treatment and hydrogenation pyrolysis. He was listed as the co-author
of over 30 research paper and inventor of over 120 invention patent. He was also the
owner of various academic and industrial honor, including He Leung He Lee Foundation
Award, National Technical Invention Award, CAS Outstanding contribution award,
Sinopec Outstanding contribution award, Science Talent in Liaoning Province etc.
Several points on gas-liquid-solid separation for ebullated bed resid hydrocracking
Resid hydrocracking has been attract more and more attention by the refining industry for this decades, and one of
the best approach is the ebullated bed resid hydrocracking (EBRH). STRONG ebullated bed resid hydrocracking uses a
new type of ebullated bed reactor, and a 50,000Tons/Year demonstration unit has been putting on operation now.
The crucial technology of STRONG is the gas-liquid-solid separation efficiently in the reactor. Several points on gasliquid-solid separation for the resid hydrocracking reactor has to be specially mentioned: 1. the mass transfer in the
system is very important, especially the gas-liquid mass transfer and liquid diffusion in catalyst particle pores. In
order to overcome the mass transfer difficulties, increase the gas hold-up ratio, decrease the gas bubble size and
catalyst particle size are preferred, but the problem of gas-liquid-solid separation will be enlarged quickly. 2.
controlling the system flow pattern is another important point, how to meet the needs for fully back mixing flow
while does not causing large size vortex flow, how to avoid the gas bubble quickly coalescence to become large
bubbles, how to maintain the three phase distributed in the reactor an even as possible, and so on. 3. the resid
hydrocracking is a sensitive process for the reactor system coking block up, especially in the phase separation system.
The three phase separator of STONG ebullated bed resid hydrocracking has solved the above problem satisfactorily,
and will described in this paper in detail.
Weiqiao Deng
Wednesday Oct.14, 10:20-11:00AM
M106, No16. Building
Dr. Weiqiao Deng is the group leader of 1109 at Dalian Institute of Chemical Physics.
He has published more than 80 publications including Nature Comm. J. Am. Chem.
Soc., Angew. Chemie. Int. Ed., Energy Env. Sci., Nano Lett., Phys. Rev. Lett. etc with
citations more than 2000 times. Deng’s research is about materials simulation and
design, which includes the multi-scaled computational simulation to screen and
design novel materials with desired properties and synthesis of the designed
materials accordingly.
Conjugated microporous polymer for water purification
Resid Oils, organic solvents, dyes, and heavy metal ions are primary pollutants in water resources. Currently, no
sorbent material can effectively remove these types of pollutants simultaneously. Here we report a perfluorous
conjugated microporous polymer with superhydrophobicity and a large surface area, which exhibits outstanding
adsorption capacities, kinetics, and recyclability for a wide range of organic solvents, oils, dyes, and heavy metal ions.
The adsorption capacities of this polymer, 1376.7 mg g-1 for Congo red, 808.2 mg g-1 for Pb(II) and 303.2 mg g-1 for
As(V), are higher than the adsorption capacities of any previously described porous materials. Our theoretical
calculation reveals that the superior properties of this polymer are due to fluorination and triple bonds within the
polymer. A benchmark experiment indicates that this polymer can efficiently remove these pollutants simultaneously.
Application of this polymer may lead to the development of next-generation reusable and portable water purification
appliances.
)
Xuefeng Zhu
Dr. Xuefeng Zhu got his Bachelor degree from the chemistry college of the
Beijing Normal University in 2001 and PhD from the Dalian Institute of Chemical
Physics (DICP), Chinese Academy of Sciences in 2007. He went to the Jerry Lin
group in Arizona State University and carried out a project from DOE on zeolite
membrane for hydrogen separation (2008). After that he came back to DICP
and then was appointed as an associate professor (2009) and full professor
(2014) of the State Key Laboratory of Catalysis (SKLC). He has published more
than 50 scientific papers, contributed to 2 book chapters and holds more than
10 patents.
Mixed oxygen ionic-electronic conducting perovkite membrane
reactors for H2 separation
Mixed oxygen ionic-electronic conducting membrane was used as catalytic membrane reactor for
hydrogen separation to acquire high-purity hydrogen from steam and low-purity hydrogen. One side of
the membrane is exposed to steam atmosphere where water splits into hydrogen and oxygen ions at
high temperature, and the other side of the membrane is swept by low-purity hydrogen to react with
the oxygen ions permeated from the opposite side. Theoretically, hydrogen of 100 % purity can be
obtained from steam side after cooling and drying. With 80% H2/He balance as feeding gas, the
hydrogen separation rate of a 0.5-mm-thick BaCe0.05Fe0.95O3-δ membrane increased from 2.0 to 9.6 mL
cm-2 min-1 as the operation temperature was raised from 700 to 900 °C, which were two orders
higher than those of the mixed protonic-electronic conducting membranes at the same conditions.
Winston Ho
Winston Ho is Distinguished Professor of Eng, Chemical & Biomolecular Eng in
the Ohio State University. He was elected member of Academia Sinica, the
highest form of academic recognition in the Republic of China in Taiwan, 2015.
New Scale-up Membranes for CO2 Capture and Separation
This presentation covers new scale-up carbon dioxide-selective membranes for (1) hydrogen
purification for fuel cells and (2) carbon capture from flue gas. We have synthesized carbon dioxideselective membranes by incorporating amino groups into polymer networks. The membranes have
shown high carbon dioxide permeability and selectivity vs. hydrogen, carbon monoxide and nitrogen.
The membranes were scaled up to fabricate 14-inch wide membranes by using a continuous roll-to-roll
machine equipped with a thin-film-coating assembly. Aided by a material balance equation, three
variables, including the coating knife gap setting, substrate rolling speed, and coating solution
concentration, were identified as the critical factors to control the membrane selective layer thickness.
For the CO2 separation from a synthesis gas stream containing CO2 and H2S, i.e., pre-combustion CO2
capture in IGCC (integrated gasification combined cycle) technology or hydrogen purification for fuel
cells, the thicker amine-containing membranes with around 15 ± 2 microns of selective layer
thicknesses were fabricated by using a gap setting of 17 mils, a rolling speed of 0.5 ft/min (set by the
drying capacity of the drier, i.e., its length), and an amine coating solution of 18 wt% solid
concentration. For the post-combustion CO2 capture from flue gas, the same thin-film-coating
assembly machine was used to fabricate thinner amine containing membranes with < 250 ± 20 nm of
selective layer thicknesses by using various rolling speeds and amine-containing solution concentrations
at a fixed gap setting of 0.45 mils.
Page 127
)
Wednesday Oct.14 , 10:20-11:00 AM
Junhua Li
Dr. Junhua Li received his Ph.D. degree major in Nuclear Fuel Cycle and Material
from China Institute of Atomic Energy in July 2001. After a post-doctral period in
School of Environment, Tsinghua University from 2002-2003, he was selected as the
Associate professor of School of Environment in Tsinghua University. He was
prompted to full professor from 2007 and become an excellent talent on
Environmental Science of NSF China in 2013. He has once been a visiting professor
at University of Michigan and University of Sydney, respectively. His research
interests including Environmental Catalysis and Adsorbent Materials and Air
Pollution Chemistry and Control Technology. He was listed as the co-author of over
50 peered reviewed research paper, most of which were published on high-ranking
reseach journals, including Environ. Sci. Technol., Appl. Catal. B: Environ. and J. Phy.
Chem. etc.
Progress on removal NOx and VOCs by environmental catalysis
In this work, a series of MnO2 with various structures were prepared, and their catalytic activities were
evaluated for reduction of NOx and oxidation of VOCs. The preparation method affects the structure of
Mn-based catalyst, and the dispersion of active sites depends on concentration of the precursor
solution, and the final procedure of drying. Tunneled alpha-MnO2 had much higher catalytic activity
than other MnO2 under the same reaction conditions. Experiment results revealed that the surface
area was not the main factor to affect the NH3-SCR activities over the MnO2 nanorods and that the
activities were structure sensitive. The crystal structure and surface properties of alpha-MnO2 are more
suitable to the adsorption of NH3 and activation of NH3 and NOx, which accounts for the higher
catalytic activity of the alpha-MnO2 nanorods. 1D-MnO2, 2D-MnO2 and 3D-MnO2 with different
structures were successfully synthesized. The decrease order of the activity of ethanol oxidation on
different MnO2 catalysts is 3D-MnO2 > 2D-MnO2 > 1D-MnO2, which is consistent with the sequences of
some factors such as surface areas, Mn4+ cations species, surface active oxygen species and reducibility.
3D-MnO2 has the best catalytic property of ethanol oxidation due to the special 3D pore channel
structure, larger specific surface area, better low-temperature reducibility, more abundant active
surface oxygen species and sufficient active Mn4+ cationic species.
Daming Wang
Daming Wang is the Professor and Chairman of Department of Chemical Engineering
in National Taiwan University. He obtained his B.S. in Chemical Engineering from
National Taiwan University and Ph.D. in Chemical Engineering from Pennsylvania
State University.Prof. Wang has been working in membrane separation technology,
molecular simulation and tissue engineering. In 2005, he was bestowed Outstanding
Teaching Award of the NTU. He is editorial board of Journal of Applied Membrane
Science and Technology, Chinese Institute of Chemical Engineers and Journal of
Chemical Engineering of Japan, Scientific Committee Member of Aseanian
Membrane Society, Scientific Committee Member of Aseanian Membrane Society.
Formation of pores in polymeric membranes --a thermodynamically or kinetically controlled process
It is well known that the thermodynamic stability of casting solution plays an important role in phase
separation and the formation of membrane pores. However, phase separation may need time to occur,
which makes kinetics also important. For example, phase separation via the mechanism of nucleation
and growth may not occur if there is not enough time for the nuclei to form; similarly, a polymer
solution with a composition in the crystallization region (can crystallize thermodynamically) may not
crystallize if not enough time is given for the crystalline nuclei to occur. Therefore, kinetic factors
influencing the time given for the nuclei to occur and the rate of nuclei forming can also play important
roles in the formation of membrane pores. We will show how the mass transport during membrane
formation and the entanglement of polymer chains are important kinetic factors in controlling
membrane morphology. Insight into these kinetic factors is important in understanding the formation
of membrane pores.
Page 128
Tuesday Oct.13 (M106, No. 16 Building)
Chair : Suojiang ZHANG
Afternoon
Title
Name
Affiliation
13:30-
S14-K1
Diffusion Entropic Activation Factors:
Maxwell’s Demons at Work
William
Koros
Georgia
Institute of
Technology
S14- I1
Ionic Liquid Solvent Design for
Extraction Processes Based on
Molecular Group Descriptor and Multiscale Simulations
Zhiwen Qi
East China
University of
Science and
Technology
S14- I2
Lattice Boltzmann simulation of mixing
process inside micro-droplet
Yi Cheng
14:10
14:1014:40
14:4015:10
15:10-
Tsinghua
University
Coffee break
15:20
15:2016:00
S14-K2
Several points on gas-liquid-solid
separation for ebullated bed resid
hydrocracking
S14-I3
Mixed-linker zeolitic imidazolate
framework (ZIF) materials and scalable
membrane processing on polymeric
hollow fibers
S14-I4
Responsive Hydrophobic Interaction
Membrane Chromatography
16:0016:30
16:3017:00
Xiang
chen
Fang
Fushun
Research
Institute of
Petroleum and
Petrochemical
s, SINOPEC
Nair
Georgia
Institute of
Technology
Xiang
hong Qian
University of
Arkansas
Sankar
Wednesday Oct.14 (M106, No. 16 Building)
Chair :Ralph T. YANG
Morning
Title
Name
Affiliation
8:30-9:10
S14-K3
Carbon dioxide permeation properties of
samarium-doped-ceria carbonate dualphase membranes
Jerry Lin
Arizona
State
University
S14-I5
Density Functional Theory Study on the
Electrophoresis Separation of Charged
Particles
Yangxin
Yu
Tsing Hua
University
9:10-9:40
Page 129
Symposium 14- Separation Technology (M203)
9:40-10:10
Xiaohua
Ma
King
Abdullah
University of
Science and
Technology
S14-K4
Conjugated microporous polymer for
water purification
Weiqiao
Deng
Dalian
Institute of
Chemical
Physics
S14-I7
Optimization of staged configurations
for membrane-based CO2 capture
Glenn
Lipscomb
University of
Research and Applications of Baosteel's
BSSF Process for Molten Steelmaking
Slag Treatment
Yongli
Xiao
Baosteel
Research
Institute
S14-I6
Novel Microporous Polyimide
Membrane Derived from a
Spirobifluorene-Based Dianhydride for
Gas Separation Applications
10:10Coffee break
10:20
10:20-
11:00
11:0011:30
11:30-
S14-I8
12:00
12:00-
Toledo
13:30
Chair : Hualin WANG
Afternoon
Title
Name
Affiliation
13:30S14-K5
Ionic liquid-based materials as
electrolytes
Shimo
Chen
Institute of
Process
Engineering
S14- I9
Treating Poultry Processing Wastewaters
by Ultrafiltration
Sumith
Wickrama
singhe
University of
Arkansas
S14-I10
Preparation of PVA composite catalytic
membrane and the intensification of
esterification reaction
Weidong
Zhang
Beijing
University of
Chemical
Technology
14:10
14:1014:40
14:4015:10
15:10-
Coffee break
15:20
15:2016:00
16:0016:30
16:3017:00
Page 130
S14-K6
Mixed oxygen ionic-electronic
conducting perovkite membrane reactors
for H2 separation
S14-I11
A Rotating Carbon Nanotube Membrane
Filter for Water Desalination
S14-I12
Continuous Production of Polymer
Coated Drug Crystals, Particles and
Nanoparticles by Cooling and Antisolvent Crystallization
Dalian
Xuefeng
Institute of
Zhu
Chemical
Physics
University of
Shaofan Li CaliforniaBerkeley
Kamalesh
Sirkar
New Jersey
Institute of
Technology
Thursday Oct.15 (M106, No. 16 Building)
Chair : Kamalesh K. SIRKAR
Morning
8:30-9:10
9:10-9:40
9:40-10:10
Title
Name
S14-K7
Progress on removal NOx and VOCs by
environmental catalysis
Junhua Li
S14-I13
High-performance multilayer composite
membranes with polydopamine as a
versatile molecular bridge for CO2
separation
Zhi Wang
S14-I14
Novel Liquid-like Nanoparticle Organic
Hybrid Materials (NOHMs) for Carbon
Capture and Conversion
Ah-Hyung
(Alissa)
Park
10:10-
11:00
11:0011:30
11:3012:00
Tsing Hua
University
Tianjin
University
Columbia
University
Coffee break
10:20
10:20-
Affiliation
New Scale-up Membranes for CO2
Winston
Capture and Separation
Ho
S14-I15
Nanoengineered Coalescence Separation
of Water-in-oil and Oil-in-water
Emulsions
Chuan
fang Yang
S14-I16
The micromixing performance of a
micro-impinging stream mixer and its
extraction applications
S14-K8
12:00-
Lixiong
Wen
The Ohio
State
University
Institute of
Process
Engineering
Beijing
University of
Chemical
Technology
13:30
Chair :Suojiang ZHANG
Afternoon
13:30-
Title
S14-K9
14:10
14:1014:40
14:4015:10
S14-I17
S14-I18
Formation of pores in polymeric
membranes --a thermodynamically or kinetically
controlled process
Elevated pervaporation performance of
polysiloxane membrane using metal
organic framework CuBTC
Numerical simulation of mechanical
property of plant cell during ultrahigh
pressure extraction process
Name
Affiliation
Daming
Wang
National
Taiwan
University
Zhongyi
Jiang
Jun Xi
Tianjin
University
Sichuan
University
Page 131
15:10-
Coffee break
15:20
15:20-
S14-I19
Dynamic interactions of small molecules
with KCNQ2 channels
Huaiyu
Yang
S14-I20
Simulation research on the thermally
coupled reactive distillation in the
biodiesel production
Lanyi Sun
15:50
15:5016:20
Page 132
Shanghai
Institue of
Materia
Medica
China
University of
Petroleum
Symposium 15- Forum of Chemical Engineering Department Deans and Chairs (M103)
Symposium 15- Forum of Chemical Engineering Department Deans and Chairs
Chairs: Shan-Tung Tu, [email protected]; Bogeng Li, [email protected]
Linda Broadbelt, [email protected];
William Koros, [email protected]
Featured Speakers
Mark Barteau
M103, Yifu Building
Mark Barteau is the Director of Energy Institute; DTE Energy Professor of
Advanced Energy Research; and the Professor of Chemical Engineering.
His researches are mainly about Design of catalysts and nanomaterials
to improve efficiency and sustainability of chemicals and fuels
production and strategies for utilization of renewable resources.
Lessons from a (half) career in academic leadership
It is almost a truism that junior faculty are often thrown into the classroom with little formal preparation in
teaching. It is also the case that those taking on positions of academic leadership at the department chair
and similar levels receive little preparation for their new responsibilities. The author has served in a variety
of academic leadership positions, from center and institute director, to department chair, to university
central administration, and will share experiences and thoughts about the lessons learned along the way.
Wenjun Wang
M103, Yifu Building
Wenjun Wang is the Professor of Department of Chemical and
biochemical Engineering in Zhejiang University, 2010.12-present. And
a Visiting Professor of Department of Chemical Engineering in
McMaster University, 2010.11-present. His research areas includes
functional fine polymer product engineering, olefin polymerization
and functionalization and polymeric materials and interface
engineering.
Globalization Initiatives in Chemical Engineering Education at Zhejiang University
Adapting to the rapid globalization of post-secondary education is a great challenge for engineering
programs in China, but the removal of boundaries separating educational institutions also provides
significant opportunities. Increasing international collaborations and the global flow of research talent
allows institutions to enhance their exposure and influence, and recalibrate both their undergraduate and
graduate engineering education. Zhejiang University (ZJU) is strongly committed to maintaining its
reputation as a top tier chemical engineering program both nationally and internationally. To achieve this
objective, ZJU has enacted several outreach approaches to facilitate interactions with some of the best
engineering institutions, educators, and researchers in the world. In this presentation, an update on these
efforts is provided. This will include a review of our most promising initiatives such as (1) design of
programs facilitating formation of long-term collaborations with internationally recognized institutions; (2)
participation in major international meetings and conferences through presentations and the hosting of
receptions; (3) arrangement of lectures, special courses, and long-term visits from international scholars;
and (4) development of summer research exchange programs, which facilitates the placements of ZJU
students at various universities around the world and supports the visit of international students.
Page 133
Symposium 15- Forum of Chemical Engineering Department Deans and Chairs (M103)
Thursday Oct.15 (M103)
Chair : Shan-Tung Tu, Bogeng Li, Linda Broadbelt, William Koros
Morning
Title
Name
Affiliation
S15-K1
Lessons from a (half) career in academic
leadership
Mark
Barteau
University of
Michigan
Energy
Institute
9:10-9:40
S15- I1
Reform and Practice of Chinese Higher
Education in Chemical Engineering
(O0394)
Xuhong
Guo
ECUST
9:40-10:10
S15- I2
The evolving role of assessment in
chemical engineering education (O0313)
Glenn
Lipscomb
University of
Toledo
Wen-Jun
Wang
Zhejiang
University
MarcOlivier
Coppens
University
College
London
Department
of Chemical
Engineering
8:30-9:10
10:10Coffee break
10:20
10:2011:00
11:0011:30
S15-K2
S15-I3
Globalization Initiatives in Chemical
Engineering Education at Zhejiang
University (O0470)
A World of Opportunities for Chemical
Engineering (O0193)
12:0013:30
Page 134
Posters
The size for the poster should not be bigger than 900 mm (W) x1200 mm (L).
Poster boards will be numbered. Presenters should attach their posters to the
board number corresponding to the number assigned to their posters in the
final program.
The Best Student Poster Awards will be given to the winners at the 8th Sino-US
ChE conference.
Poster Presentation, Wednesday Oct.14, 2015
S1--Air
S2--Bio
P001
P006
Electrochemical NO2 Sensor based on Gd1xCaxAlO3-δ using NiO sensing electrode (A0256)
Synergistic Effect of Epigallocatechin-3-Gallate
and Polymeric Nanoparticle in Inhibition and
Detoxification of Amyloid β-Protein Fibrillation
(B0043)
Dongmei Wang, Yuanyuan Ding, Chufan Zhang, Xu
Zhang, Fulan Zhong, Yihong Xiao (Fuzhou University)
Hongchen Liu, Xiaoyan Dong, Yan Sun (Tianjin
University)
P002
P007
Study on the Oxidation of Formaldehyde over
various dimensional Co-based Catalysts (A0465)
Enhanced Inhibition Effect of Acidulated Serum
Albumin on Zn2+-Mediated Amyloid β-Protein
Fibrillogenesis and Cytotoxicity (B0051)
Bingyang Bai, Zichen Li (Chinese Research Academy of
Environmental Sciences)
Baolong Xie, Xiaoyan Dong, Yongjian Wang, Yan Sun
(Tianjin University)
P003
P008
Experimental study on Combination of Wood
fiber with Catalyst for Improving Capacity of
Nonthermal Plasma Treating Automobile
Exhaust (A0578)
Tailored Cell Morphology of Polylactide Foams
by Controlling Its Crystallization during Foaming
(B0070)
Wenli Zhu (Hubei University of Arts and Science)
Xiurong Guo, Yinghui Wang, Danfeng Du (Northeast
Forestry University )
S2--Bio
P004
P009
Fast aggregation kinetics of amyloid β-protein in
the presence of zinc ions (B0041)
High-yield Synthesis of Stain Precursor with a
New Aldehyde-Tolerant Aldolase (B0091)
Jingjing Guo, Linling Yu, Yan Sun, Xiaoyan Dong
Xuecheng Jiao, Huilei Yu, Jianhe Xu (East China
University of Science and Technology)
P005
P010
Hematoxylin Inhibits Amyloid β-Protein
Aggregation and Cytotoxicity (B0042)
Switching a thermostable lactonase into an
efficient phosphotriesterase by simple double
mutations (B0107)
Yilong Tu, Fufeng Liu, Yan Sun, Xiaoyan Dong
(Tianjin University )
Xiao-Jing Luo, Jiahai Zhou, Jian Zhao, Xu-Dong Kong,
Qi Chen, Jian-He Xu (East China University of Science
and Technology)
Page 135
S2--Bio
S2--Bio
P011
P016
(B0117)
Modeling isotopic fractions of intercellular
metabolic pools in isotope experiments with
isotopomer decomposition units (B0208)
Weilu Lin, Mingzhi Huang, Yingping Zhuang, Siliang
Zhang (East China University of Science Technology)
P012
P017
Highly efficient and enantioselective
biosynthesis of (R)-2-chloro-1-(2,4dichlorophenyl)ethanol with a reductase SsCR
from Scheffersomyces stipites CBS 6045 (B0123)
Modular optimization of multi-gene pathways
for fumarate production (B0209)
Xiulai Chen, Liming Liu (Jiangnan University)
Yuepeng Shang, Huilei Yu, Jianhe Xu (East China
P013
P018
Cold Plasma at Atmospheric Pressure as A Novel
Approach to Regulate Cell Membrane
Permeability for Formation of ATP and NADH in
Saccharomyces cerevisiae (B0168)
Non-sterilized production of ethanol or L-Lactic
Acid from waste substrate by Metabolic
Directing of Thermoanaerobacterium (B0219)
Xiaoyu Dong (Dalian University)
Shuang Li , Muzi Zhu , Xiaofeng Yang (South China
University of Technology)
P014
P019
pH optimization of oil recovery bacteria strain
(B0169)
DNA assembler method for construction of
omega-6 arachidonic acid producing strain of
Yarrowia lipolytica (B0259)
Chunyan Chen , Sihua Long (Southwest Petroleum
University)
Huhu Liu, Catherine Madzak, Xiao-Jun Ji, He Huang
(Nanjing Tech University)
P015
P020
Semi-rational design the enantioselectivity of
lipase aided by molecular docking (B0196)
Comparison of the Behavior of High-silica
Zeolite and ZIF-8 for 1-Butanol Adsorption and
Separations from ABE Model Solution (B0262)
Hongjiang Wang, Bin Yang, Xiulai Chen, Liming Liu
(Jiangnan University)
Page 136
Chunping Gao, Qi Shi, Jinxiang Dong (Taiyuan
S2--Bio
S2--Bio
P021
P026
A de novo NADPH generation pathway for
improving xylitol production in Escherichia coli
(B0283)
On structural identifiability analysis of the
cascaded linear dynamic systems in transient
isotope experiments (B0443)
Buli Su, Mianbin Wu, Jianping Lin (Zhejiang University)
Weilu Lin, Mingzhi Huang, Yingping Zhuang, Siliang
Zhang (East China University of Science Technology)
P022
P027
Foaming simulation in ethanol fermentation of
high solids lignocellulose feedstock (B0308)
Performance of different strains of Clostridium
thermocellum and Clostridium
thermosaccharolyticum in production of
Hydrogen and VFA (B0460)
Weiliang Hou, Jian Zhang, Jie Bao (East China
Md. Saiful Islam, Chen Zhang, Chunzhao Liu (Institute
of Process Engineering, Chinese Academy of Sciences)
P023
P028
Biocompatible hydrogels support in vitro cell
survival (B0335)
Vanillic acid treatment enhances Trametes
versicolor laccase production (B0480)
Jing Yang, Yingnan Zhu, Lei Zhang (Tianjin University)
Kefeng Wang, Chunzhao Liu (Institute of Process
Engineering, Chinese Academy of Sciences)
P024
P029
Inhibitory effects of ammonia on methanogen
mcrA transcripts in anaerobic digester sludge
(B0423)
Performance of different strains of Clostridium
thermocellum and Clostridium
thermosaccharolyticum in production of
Hydrogen and VFA (B0500)
Chen Zhang, Quan Yuan, Yahai Lu (China Agricultural
University)
Chunzhao Liu (Institute of Process Engineering,
Chinese Academy of Sciences)
P025
P030
Effect of two different vectors on expression
and purification of CotA laccase (B0440)
Cellulosic ethanol production using
Trichoderma reesei mutant with enhanced
cellulase activity and integrated cellulase
production, saccharification and ethanol
fermentation (B0560)
Nadia A. Samak, Chunzhao Liu (Institute of Process
Yonghao Li, Cheng Cheng, Liang Xiong, Xinqing Zhao,
Fengwu Bai (Dalian University of Technology)
Page 137
S2--Bio
S3--Cat
P031
P036
Enhanced stress tolerance of Saccharomyces
cerevisiae by overexpression of genes involved
in amino acid metabolism (B0561)
Water vs. Ethanol: Effects of impregnation
solvent on Ni/SBA-15 catalyst for CO
methanation reaction (C0026)
Mingming Zhang, Keyu Zhang, Qingqing Wan, Xinqing
Zhao, Fengwu Bai (Dalian University of Technology)
Miao Tao, Zhong Xin (East China University of Science
and Technology)
P032
P037
Separated hydrolysis and ethanol production
from Jerusalem artichoke stalk (JAS) with high
solid loading (B0581)
Kinetic study on hydrogen evolution from
decalin over Pt catalysts supported on carbon
nanofibers with different microstructures
(C0029)
Liang Xiong, Ruiqi Tang, Yonghao Li, Xinqing Zhao,
Fengwu (Dalian University of Technology)
Yongxiao Tuo, Xing Li, Hao Jiang, Xuezhi Duan, Xinhai
Yu, Ping Li (East China University of Science and
Technology)
P033
P038
Moderate high fermentation temperature
improves xylose consumption of recombinant
Saccharomyces cerevisiae (B0584)
Simultaneous catalytic conversion of H2S and
CO2 into valuable products (C0030)
Liang Xiong, Xinshui Yu, Cheng Cheng, Xinqing Zhao,
Fengwu Bai (Dalian University of Technology)
Hui Su , Yuyang Li, Ping Li, Xuezhi Duan, Zhizhi Zhang,
Xiangchen Fang (East China University of Science and
Technology)
P034
P039
Construction of efficient recombinant
Saccharomyces cerevisiae strain for
simultaneous saccharification and cellulosic
ethanol production from Jerusalem artichoke
stalk (B0585)
Platform of on-site oxidants generation (C0047)
Zijun Xia, Yida Xu, Xing Zhang, Lei Cao (GE Global
Research)
Cheng Cheng, Liang Xiong, Xinqing Zhao, Fengwu
Bai(Dalian University of Technology)
P035
S3--Cat
Effect of MoO3 on catalytic performance and
stability of the SBA-16 supported Ni-catalyst for
CO methanation (C0025)
Zhicheng Bian, Zhong Xin (East China University of
Science and Technology)
Page 138
P040
Reasearch on Reactive Distillation of Aldol
Comdensation of Acetaldehyade (C0068)
Yanhui Wu, Xiangbin Kong, Zelei Liang, Gaosheng Wu
(Tongji University)
S3--Cat
S3--Cat
P041
P046
Steam reforming of dimethyl ether over a novel
anodized γ-Al2O3/Al monolith supported Cubased bi-functional catalyst (C0077)
Rational design the enantioselectivity of lipase
aided by molecular docking and Molecular
Dynamics (C0196)
Feiyue Fan, Qi Zhang, Xing Wang, Zibin Zhu (East China
Hongjiang Wang (Jiangnan University)
P042
P047
Bimodal Comb Block Polyolefins by Serial
Reactors (C0102)
Controllable Synthesis of Silica Hollow
Microspheres with Size-tunable Penetrating
Macroporous Shells and their Application in
NBR Hydrogenation (C0206)
Andy Tsou (ExxonMobil Chemical Company)
Pei Yuan, Jian Wang (China University of
Petroleum(Beijing))
P043
P048
Selective Hydrogenation of Succinic Acid by
Regenerable Atomically Dispersed Pd on
zirconia (C0127)
New insights into the function of potassium
carbonate species and the superiority of base
metals to noble metals in the polytitanate
nanobelt supported LNT catalysts (C0234)
Chi Zhang, Lifang Chen, Zhiwen Qi (East China
University of Science Technology)
Yuxia Zhang, Ming Meng (Tianjin University)
P044
P049
Direct production of high octane gasoline by
LCO Hydrocracking (C0156)
Catalytic Cracking Performance of Daliya VGO
and Penglai VGO (C0239)
Chong Peng, Xiangchen Fang, Ronghui Zeng, Zhenmin
Cheng (East China University of Science and
Technology)
Xin Zhao, Qingxiang You, Haiyan Liu, Rui Zhang,
Xianghai Meng
(China University of Petroleum (Beijing))
P045
P050
Identifying active sites of CoNC/CNT from
pyrolysis of molecularly defined complexes for
oxidative esterification and hydrogenation
reactions (C0186)
Co-Mo sulfur resistant shift catalyst supported
on Mg-Al mixed oxide derived from layered
double hydroxides (C0243)
Tianyuan Cheng, Hao Yu, Feng Peng, Hongjuan Wang,
Bingsen Zhang, Dangsheng Su (South China University
of Technology)
Jinxing Mi, Yanning Cao, Dalin Li, Lilong Jiang (Fuzhou
University)
Page 139
S3--Cat
S3--Cat
P051
P056
Cobalt-aluminum mixed oxides prepared from
layered double hydroxides for benzene total
oxidation (C0244)
Acid modification of natural bauxite mineral
and its application in slurry-bed hydrocracking
process (C0264)
Yuanyuan Ding, Dongmei Wang, Dalin Li, Yihong Xiao
(Fuzhou University)
Pengli Niu, Yuanyuan Yue, Lilong Jiang, Xiaojun Bao
(Fuzhou University)
P052
P057
Layered double hydroxides as precursors of Cu
catalysts for water-gas shift reaction (C0245)
Discovery, engineering and application of acid
phosphatases for ascorbic acid-2-phosphate
preparation (C0267)
Yunbing Cai, Dalin Li, Chongqi Chen, Lilong Jiang
(Fuzhou University)
Wei Song, Hui Liu, Ruidong Chen, Xiulai Chen, Jia Liu,
Liming Liu (Jiangnan University)
P053
P058
Synthesis of sheet-like γ-FeOOH and Its Removal
of Carbonyl Sulfide Property at Low
Temperature (C0247)
Cyclohexene as hydrogen carrier to promote the
biomimetic catalytic oxidation of aliphatic C-H
bond in the presence of molecular oxygen
(C0269)
Zhongjie Du, Xuebin Lin, Yan Lin, Ronghai Huang,
Yanning Cao, Lilong Jiang (Fuzhou University)
Jun Jiang , Xiantai Zhou , hongbing Ji (Sun Yat-sen
University)
P054
P059
Optimization of Modified Hollow Titanium
Silicalite HTS in Cyclohexane Selective Oxidation
(C0257)
Mesoporous Silica Supported Ionic Liquids
Catalyst for the Alkylation between Benzene
with 1-Dodecene (C0270)
Houjie Song, Meiqin Zheng, Shujuan Guo, Qingming
Huang, Min Lin, Xiaohui Chen (Fuzhou University)
Yibo He, Qinghua Zhang, Xiaoli Zhan, Dang-Guo
Cheng, Fengqiu Chen (Zhejiang University)
P055
P060
Pervaporation Enhanced Esterification of
Propionic Acid and its kinetics (C0258)
Highly Efficient Aerobic Oxidation of Tetralin to
α-Tetralone over Cr2O3-CeO2/Al2O3 Catalysts
(C0281)
Shasha Na, Wenying Zhang, Weixing Li , Weihong Xing
(Nanjing Tech University)
Page 140
Lixin Xu, Guangyuan Chen, Jian Zhang, Bing Hong,
Chao Wan (Anhui University of Technology)
S3--Cat
S3--Cat
P061
P066
A study of H2 release from dodecahydro-Nethylcarbazole over a supported Pd catalyst
(C0287)
Isobornyl Acetate Synthesis Kinetics (C0314)
Yingshu Wang, Chao Li, Naru Huang, Suying Zhao
(Fuzhou University)
Chao Wan , Yue An , Dang-guo Cheng , Fengqiu Chen ,
Lixin Xu (Anhui University of Technology)
P062
P067
Bimetallic PtSb Nanocatalyst for Selective
Oxidation of Glycerol with Oxygen in a Basefree Aqueous Solution (C0298)
Synthesis of SAPO-11 and application in the
isomerization of n-heptane (C0341)
Hua Dong, Jiaqi Lei, Xuezhi Duan, Gang Qian, Xinggui
Zhou (East China University of Science and
Technology)
Dongliang Jin, Kake Zhu (East China University of
P063
P068
Kinetics of the Catalytic Polymerization of
Cottonseed Oil Acid (C0301)
The Creation of Sulfur Vacancies for the
Hydrodesulfurization over 2H-MoS2 M-edge and
S-edge: A DFT Study (C0343)
Suying Zhao, Fuqiang Li, Yanyi Shen , Dan Wu (Fuzhou
University)
Peng Zheng , Liang Zhao , Kebin Chi , Aijun Duan ,
Zhen Zhao (China University of Petroleum(Beijing))
P064
P069
Identification of the kinetic parameters and
autocatalytic behavior in esterification via
isoperibolic reaction calorimetry (C0304)
Oxidative dehydrogenation of light alkanes over
mesoporous Cr-Ce-Al composite oxide using
N2O as an oxidant (C0345)
Zichao Guo, Lin Hao, Hongyuan Wei (Tianjin
University )
Suresh Kumar Megarajan, Jingting Lu, Wenyuan Liang,
Yan Zhang, Heqing Jiang (Qingdao Institute of
Bioenergy and Bioprocess Technology, Chinese
Academy of Sciences)
P065
P070
Photocatalytic activity of Methyl orange and
Congo red using Ba0.2Sr0.8Co0.5Fe0.5O3-δ (C0311)
Study on the microscopic mechanism of
microwave and effects on the dissolution of
Potassium Feldspar at low temperature (C0346)
Hongyan Meng , Jun Qiao , Zhengquan Shi, Xianghong
Huang (Zhejiang Shuren University)
Jingxing Zhao, Jianhai Zhao, Jiao Meng, Huanhuan Shi
(Tianjin Chengjian University)
Page 141
S3--Cat
S3--Cat
P071
P076
Hydrogenation of coal tar model compounds
catalyzed by Ni2P/SBA-15 and MoNiWP/Al2O3
(C0355)
Immobilization of laccase on amine-functioned
Fe3O4 nanoparticles via metal affinity
adsorption or covalent binding (C0436)
Shuai Ma, Mengxiang Fang, Zhenzhen Liu, Qinhui
Wang, Zhongyang Luo (Zhejiang University)
Tingting Xia, Chen Guo, Jianhua Hu, Chunzhao Liu
(Institute of Process Engineering, Chinese Academy of
Sciences)
P072
P077
Biomass derived p-xylene by selective
aromatization (C0388)
Selective oxidation of furfural in a bi-phasic
system with homogeneous acid catalyst (C0448)
Gangli Zhu, Huanling Song, Feng Zhao, Chungu Xia
(Lanzhou Institute of Chemical Physics(LICP), Chinese
Xiaodan Li, Tiefeng Wang (Tsinghua University)
P073
P078
Study on preparation of Ru-based catalysts with
bioreduction method and their application in
liquid phase hydrogenation (C0389)
Characterization and catalytic performances of
Pd-CeO2/C catalysts for caprolactam
hydrogenation purification (C0451)
Yangqiang Huang, Youwei, Cheng Lijun Wang, Xi Li
(Zhejiang University)
Chunyan Tu, Li Xie, Shibiao Cheng (Research Institute
of Petroleum Processing, SINOPEC)
P074
P079
Facile fabrication of porous magnetic polymer
microspheres via inverse replication for efficient
enzyme immobilization (C0422)
Effect of HZSM-5 crystal size and mesoporosity
on catalytic conversion of methanol and
ethanol into propylene (C0456)
Pingping Han , Zhongyi Jiang , Jiafu Shi , Hong Wu
Ali A. Rownaghi, Xin Li, Amit Kant, Yingxin He, Harshul
V. Thakkar (Missouri University of Science and
Technology)
P075
P080
Understanding NH3-SCR kinetics over Cu-SSZ-13
catalysts prepared by different methods (C0434)
Reaction mechanism of cyclodehydration of
sugar alcohols over a layered niobium
molybdate solid acid (C0477)
Tao Zhang, Feng Qiu, Wenkang Su, Junhua Li
(Tsinghua University)
Page 142
Atsushi Takagaki, S. Ted Oyama (The University of
Tokyo)
S3--Cat
S3--Cat
P081
P086
Molecular modeling of water adsorption in MFI
zeolites (C0485)
Hierarchical Zeolite Y: Influence of the acid wash
on the structural and acidic characteristics of
the hierarchical zeolites (C0539)
Xiongfei Zhang (Tianjin University)
Wenlin Li, Zhijian Da, Yibin Luo, Jinyu Zheng(Research
Institute of Petroleum Processing, SINOPEC)
P082
P087
Hydrogen peroxide decomposition in aqueous
suspensions of nano-magnetite (C0507)
Ketonization of acetic acid over Ce-Ti mixed
oxide catalysts: Effect of redox and basicity
properties (C0554)
Na Wang, Xin Cai, Xiaodong Chen, ShengPeng Sun
(Soochow University)
Feipeng Lu, BinBo Jiang , Zuwei Liao, Jingdai Wang,
Yongrong Yang (Zhejiang University)
P083
P088
Novel Core-Sheath Copper Catalysts with tunble
Surface Cu(0)/Cu(I) active species and
Confinement Effect for CO2 Hydrogenation
(C0509)
Pelletization process of spherical Pb-Mn
composite oxide supports (C0557)
Jie Zhou, Yue Hu, Xiaojun Yang (Wuhan Institute of
Technology)
Jing Li, Bohan Jin, Kui Ma, Siyang Tang, Changjun Liu,
Hairong Yue, Bin Liang (Sichuan University)
P084
P089
Synthesis of ethyl acetate in a reactive-distillation
unit (C0514)
Synthesis of 7-hydroxy-4-methylcoumarin via
the Pechmann reaction with PVP-supported
phosphotungstic acid catalyst (C0568)
Bencheng Wu, Jianhua Zhu, Jiayue Wang (China
University of Petroleum(Beijing))
Sifang Li, Xiaoxia Qi, Binbin Huang (Xiamen University)
P085
P090
Quantitative Kinetics and the Structural
Mechanism for Ni-Co Dry Reforming Catalysts
(C0527)
Modeling and kinetics study of bisphenol A
(BPA) degradation over a FeOCl/SiO2 Fentonlike catalyst (C0577)
Haiyan Zhao, Mohsen Shakouri, Karena Chapman,
Peter Chupas, Hui Wang(University of Idaho)
XueJing Yang, Ximeng Xu, Xinchao Xu, Jing Xu, Hualin
Wang, Raphael Semiat, Yi-Fan Han (East China
Page 143
S3--Cat
S4--Ene
P091
P096
Heteropolytungstate-ionic liquid supported on
the surface of silica coated magnetite
nanoparticles: An efficient and reusable catalyst
for esterification (C0582)
Coal Polygeneration Systems for Efficiency and
Environment Benefits (D0057)
Junli Xue (GE Global Research Center , Shanghai)
Honglei Lian, Jingyi Yang, Jian Gao, Mingzhu Ding
(Zhengzhou University)
P092
P097
Intensification the C4 alkylation process by Ionic
Liquids (C0586)
Meso-scale computational fluid dynamics
in energy and process industry (D0086)
Tao Zhang, Fei Zhou, Yuan Zhang, Shengwei Tang
(Sichuan University)
Ning Yang, Jinghai Li (Institute of Process Engineering,
P093
P098
Oxidative desulfurization of dibenzothiophene
using H3PMo12O40 immobilized onto ionic liquidmodified SiO2 (C0588)
Retrofitting Industrial Heat Exchanger Network
Based on Simple Pinch Analysis (D0087)
Bao-Hong Li (Dalian Nationalities University)
Jian Zhang , Yanjuan Wang , Haiyan Wang , Huipeng
Li , Hao Ling , Hongla Liu , Bing Wang (Liaoning Shihua
University)
P094
P099
Effect of the acidity of metal modified Y zeolites
on adsorptive desulfurization (C0596)
Kinetic study of catalytic pyrolysis of nheptane (D0204)
Yanfei Lu (Tianjin University)
Guili Liu, Shaopeng Guo, Rui Zhang, Haiyan Liu,
Zhichang Liu, Xianghai Meng (China University of
Petroleum(Beijing)
P095
P100
Electrocatalytic Dehydrogenation of 2-propanol
in EHP reactor (C0613)
Copper–free ZnGaO complex oxide catalysts
with low CO selectivity and high catalytic
stability for dimethyl ether steam reforming to
produce H2 (D0233)
Shiqi Huang , Xuemei Wu , Lin Ma , Shishui Liu ,
Gaohong He (Dalian University of Technology)
Zhou Shuang, MengMing (Tianjin University)
Page 144
S4--Ene
S4--Ene
P101
P106
Efficiency, Integration and Molecular
Management – The Role of Innovation
(D0249)
Controlled synthesis of hierarchical
nanostructured electrode materials for energy
storage applications (D0526)
Dave Martindale, Xin Zhu (UOP LLC, A Honeywell
Company)
Hao Jiang , Chunzhong Li (East China University of
P102
P107
Crystallization kinetics of ice slurry formation
(D0359)
Reactivity of 1-hexene over the sulfided CoMo
catalyst for hydrodesulfurization (D0532)
Xi Liu, Xuelai Li, Ping Yao, Zhiqiang Wu(Fuzhou
University)
Chunyan Tu, Mingfeng Li, Yang Chu, Huifeng Li, Feng
Liu, Hong Nie, Dadong Li (Research Institute of
Petroleum Processing, SINOPEC)
P103
P108
Bioconversion of syngas to ethanol: cultivation
system and impact factors (D0402)
Characterization of basic heteroatom
compounds in coal liquefaction residue (D0536)
Huijuan Xu, Cuiyi Liang, Jingliang Xu, Qiang Hua,
Zhenhong Yuan, Ying Guo, Yu Zhang (Guangzhou
Institute of Energy Conversion, Chinese Academy of
Sciences)
Li Peng, Fangui Xia, Zhouguo Li (Zhengzhou University)
P104
P109
Effects of sodium nitrite on structure and thermal
properties of LiNO3-NaNO3-KNO3 molten salt
(D0475)
Esterification of methanol with oleic acid using
double SO3H-functionalized ionic liquid as
recoverable catalyst (D0556)
Xinmei Yang, Ze Sun, Xingfu Song, Jianguo Yu (East
China University of Science and Technology)
Jian Gao , Honglei Lian, Yadong Zhao , Wenqi Liu , Bo
Meng , Jie Zhang (Zhengzhou University)
P105
P110
Density Functional Theory Study on the
Thermodynamics and Mechanism of Carbon
Dioxide Capture by CaO and CaO Regeneration
(D0476)
Soil- based Microbial Fuel Cell for Electricity
generation using Shewanella and Geobacter
bacteria present in soil (D0580)
Haiou Ni, Wei Du, Ze Sun, Guimin Lu, Jianguo Yu (East
China University of Science and Technology)
Mukund Mishra (Indore Institute of Science &
Technology)
Page 145
S4--Ene
S5--Foo
P111
P116
Adsorption of Heterocyclic Sulfur and Nitrogen
Compounds in Liquid Hydrocarbons on
Activated Carbons Modified by Oxidation:
Capacity, Selectivity and Mechanism (D0595)
Synthesis and characteristics of Acid-Alkali
modified Al2O3/PVDF hybrid membrane
(E0542)
Na Li , Xiaoliang Ma , Xiao Feng , Xiao Dong Chen
Qi He, Kaijun Xiao (South China University of
Technology)
P112
P117
RD&D Activities of SNG Production from
Syngas Methanation at DICP (D0599)
The study on L-lactic acid production by
Rhizopus oryzae from lignocellulosic waste
(E0547)
Zhongshan Yuan , Sheng Wang , Defu Li , Tianjun Sun ,
Hongjiu Su , Deyi Li , Shudong Wang (Dalian Institute
of Chemical Physics, Chinese Academy of Sciences)
Li Zhang, Jian Gao (Yancheng Institute of
Technology)
P113
Nanofibre - based imidazolium-functionalized
polysulfone composite anion exchange
membrane for fuel cell (D0612)
Xue Gong (Dalian University of Technology)
S6--Gre
P114
P119
Novel route for preparation of imidazoliumfunctionalized polysulfone anion exchange
membranes for direct methanol alkaline fuel
cells (D0614)
Heterogeneous catalysis process for precious
metal recovery and premier organosilicon
product manufacturing (F0045)
He Bai (Momentive Performance Materials Inc.)
Tiantian Li (Dalian University of Technology)
S5--Foo
P115
P120
Critical dissolution and gelation conditions from
whey protein aggregates in alkali (E0263)
Noval acrylamide-free flocculant and its
application for sludge dewatering (F0059)
Lei Zhao, Xiao Dong Chen, Ruben Mercadé-Prieto
Lianghua Lu, Zhida Pan, Nan Hao and Wenqing Peng
(Global Research Center of General Electric)
Page 146
S6--Gre
S6--Gre
P121
P126
Study of asymmetric splitting of AlCl3 in amideAlCl3 based ionic liquid analogues (F0177)
CO2 Capture from Flue Gas by PSA: Bench Scale
Demonstration of a Novel Structured Adsorbent
(F0430)
Pengcheng Hu, Xianghai Meng, Rui Zhang, Haiyan Liu,
Zhichang Liu (China University of Petroleum(Beijing))
Armin D. Ebner, MD Atikur Rahman, Nima
Mohammadi, Marjorie A. Nicholson, Charles E.
(University of South Carolina)
P122
P127
Production of hydrogen peroxide on mixedmetal oxide/carbon nitride composite catalyst
driven by solar Light (F0192)
Design and Control of Supercritical CO2 Blown
Polymer Foaming Process (F0446)
Kecheng Pan, Ruirui Wang, Xu Xiang (Beijing
University of Chemical Technology)
Ling Zhao, Tao Liu (East China University of Science
and Technology)
P123
P128
Graphene oxide composite membranes for
pervaporation (F0340)
Fractional pyrolysis of pretreated algae from
water blooms (F0501)
Wei-Song Hung, Chien-Chieh Hu, Juin-Yih Lai (Chung
Yuan University)
Linling Li, Rui Zhang, Xiaoyan Lv, Dongmei Tong,
Changwei Hu (Sichuan University)
P124
P129
Green production of cumene from liquid-phase
isopropylation of benzene over nano-beta
zeolite in a submerged membrane
reactor(F0392)
Microwave-enhanced Pyrolysis of Natural Algae
from Water Blooms (F0502)
Yang Zou , Hong Jiang , Weihong Xing , Huanxin Gao ,
Rizhi Chen (Nanjing Tech University)
Rui Zhang, Linling Li, Dongmei Tong, Changwei Hu
P125
P130
Solar photocatalytic degradation of Acidic Black
10B over (Sr0.5Ca0.5)Fe2O4-ZnO composites (F0428)
Fractional Pyrolysis of Pubescens at Low
Temperature Stage (F0503)
Jun Qiao, Hongyan Meng, Xianghong Huang (Zhejiang
Shuren University)
Xiaoyan Lv, Linling Li, Dongmei Tong, Changwei Hu
Page 147
S6--Gre
S8--Mat
P131
P136
Monophenols production in H2Otetrahydronfuran directly from corncob residue
catalyzed by alkali (F0504)
NiPdPt nanoclusters decorated on graphene as
a catalyst for ethanol electrooxidation (H0188)
Jingwen Ma, Yang Li (Tianjin University)
Zhicheng Jiang, Jianmei Li, Ting He, Jian Yi, Changwei
Hu (Sichuan University)
P132
P137
Study on Kinetics of Poly(3hydroxybutyrate)(PHB) Hydrolysis Using Acidic
Functionalized Ionic Liquid as Catalyst (F0513)
A solvent evaporation route towards fabrication
of nanosized SAPO-34 molecular sieve (H0319)
Xiuyan Song, Fusheng Liu, Shitao Yu (Qingdao
Jingwei Zheng, Kake Zhu, Xinggui Zhou and Weikang
Yuan (East China University of Science and
Technology)
P133
P138
Quantitative analysis of OH radicals formed on
the surface of TiO2 photocatalysts in aqueous
solution by fluorescence probe method (F0559)
Synthesis and characterization of Beta-FDU-12
and Its applications in the catalysts for FCC
gasoline hydrodesulfurization (H0347)
Jie Zhang, Nosaka Yoshio (Zhengzhou University)
Jiayue Wang , Peng Du , Peng Zheng , Kebin Chi , Aijun
Duan , Zhen Zhao (China University of
Petroleum(Beijing))
S7—R&D
P134
P139
Innovation and culture in the engineering firm
(G0600)
Covalent organic polymers (COPs) for energy
conversion (H0398)
Will Groten (CB&I)
Zhonghua Xiang (Beijing University of Chemical
Technology)
S8—Mat
P135
P140
Carbide bonded graphene network and
applications (H0167)
Nanoplatform for low toxicity and high efficacy:
integration of hidden targeting ligand, tumor
responsiveness, and synergistic therapy (H0405)
L. James Lee, Wenyi Huang, Jianfeng Yu, Paul Garman
(The Ohio State University )
Page 148
Faquan Yu, Yanan Xue, Bo Yu, Ning Cai, Sihui Long,
Xiaogang Luo (Wuhan Institute of Technology)
S8--Mat
S8--Mat
P141
P146
Fabrication of novel hybrid membranes based
on acid-base pairs for enhanced proton
conductivity (H0421)
Fabrication of Gold Nanoparticles with
Functional Molecules for Colorimetric
Recognition (H0445)
Yongheng Yin , Tao Xu , Zhongyi Jiang , Hong Wu
Jianjun Du, Jiangli Fan, Xiaojun Peng (Dalian
P142
P147
In situ fabrication of Ag3PO4/TiO2 nanotube
heterojunctions with enhanced visible-light
photocatalytic activity (H0424)
Crystallization Behaviors of Polypropylene
under the Action of a Novel Aromatic Amide
Nucleating Agent (H0454)
Zhenwei Tong , Dong Yang , Yuanyuan Sun , Zhongyi
Jiang (Tianjin University)
Yue-Fei Zhang, Huichen, Lihua Guo, Xin Yang, Bao Liu
(Changsha University of Science and Technology)
P143
P148
Fabrication of Three-dimensional Porous SrTiO3
Microspheres with Improved Visible-Light
Photocatalytic Performance for Cr (VI) (H0425)
Controlled additive-free hydrothermal synthesis
and characterization of uniform and
monodisperse hydroxyapatite nanobelts (H0493)
Dong Yang , Yuanyuan Sun , Zhenwei Tong , Zhongyi
Jiang (Tianjin University)
Liang An, Wang Li, Yong Xu, Yang Cheng, Guanghui
Wang (Wuhan University of Science and Technology)
P144
P149
Graphitic carbon nitride nanosheets/poly(ether
ether ketone) nanocomposite membrane for
fuel cells application (H0427)
Corrosion resistant properties of
polybenzoxazine/TiO2 Hybrid films (H0516)
Mingyue Gang , Guangwei He , Zhen Li , Hong Wu ,
Zhongyi Jiang (Tianjin University)
Yan Liu, Xin Lu, Changlu Zhou, Zhong Xin (East China
S9--Wat
P145
P150
Assembly and Processing of Functional Porous
Microspheres via Micro-Fluidic Jet Spray Drying
(H0441)
Highly hydrophilic fouling resistant PVDF
ultrafiltration membranes with TiO2
nanoparticles both on membrane surface and in
membrane matrix (I0067)
Zhangxiong Wu , Winston Duo Wu , Cordelia
Selomulya , Dongyuan Zhao , Xiaodong Chen
Hassan Younas, Jiahui Shao,Qiaochu Han, Yuhan Ling,
Yiliang He (Shanghai Jiao Tong University)
Page 149
S9--Wat
S9--Wat
P151
P156
Produced water treatment by Direct Contact
Membrane Distillation (DCMD) (I0071)
Fabrication and characterization of forward
ossimos (FO) composite membranes of cellulose
triacetate (CTA)-magnetic nanoparticles (MNPs)
(I0133)
Hui Lei, Xianguo Yu, Hai Yang, Su lv, Andrew Shapiro
(GE Global Research, Shanghai)
Ping-Yun Zhang, Zhenliang Xu, Xiangyu Chi, Xuejiao
Guo, Tao Wang (East China University of Science and
Technology)
P152
P157
Fouling Analysis of RO membrane (I0074)
Superhydrophobic modification of PVDF-SiO2
electrospun nanofiber membranes for vacuum
membrane distillation (I0134)
Yun Peng, Hua Li, Bo Yan, Su Lv (Global Research
Center of General Electric, Shanghai)
Zheqin Dong, Xiaohua Ma, Zhenliang Xu (East China
P153
P158
Preparation of ordered porous microfiltration
membranes on ice substrates by breath figure
method (I0118)
Coalescence separation of oil/water emulsions
with roughened non-woven filter mat (I0136)
Hailin Cong, Bing Yu, Jilei Wang, Zejing Li (Qingdao
University)
Hu Dan, Li Xiaoyu, Li Lei, Yang Chuanfang (Institute of
Process Engineering, Chinese Academy of Sciences)
P154
P159
Preparation and modification of porous
stainless steel hollow fibers by adding nanoparticles (I0131)
Preparation and characterization of selfassembled nanostructure on the PVC
ultrafiltration membrane (I0151)
Ming Wang, Qifeng Zhong, Xiaohua Ma, Zhenliang Xu
(East China University of Science and Technology)
Liang Cheng, Zhenliang Xu, Hanyang Zan, Jiazhou Zhu
P155
P160
A chlorine-tolerant nanofiltration membrane
prepared by the mixed diamine monomers of
PIP and BHTTM (I0132)
The effect of the manifold on the energy
consumption and flow distribution of the
hollow fiber membrane module-A CFD study
(I0226)
Yongjian Tang, Zhenliang Xu, Shuangmei Xue,
Yongmin Wei, Hu Yang (East China University of
Page 150
Liwei Zhuang, Hanfei Guo, Gance Dai (East China
S9--Wat
S9--Wat
P161
P166
Development of nanofiltration hollow fiber
membranes for industrial water treatment
(I0288)
Porous PES nanofibers loading PFSA catalyst
and its application in esterification (I0444)
Shipeng Sun, Taishung Chung (Nanjing Tech
University)
Xiaohua Ma, Siwen Gu, Zhenliang Xu (East China
P162
P167
Water flow through the graphene nanochannels:
A viewpoint from non-equilibrium molecular
dynamics simulations (I0305)
Atomic layer deposition enabled advanced
membranes (I0489)
Yong Wang (Nanjing Tech University)
Mingjie Wei, Yong Wang (Nanjing Tech University)
P163
P168
Surface engineering of electrospun polymeric
nanofibers for membrane distillation (I0362)
Ultrathin graphene oxide nanosheet
membranes assembled using the pressureassisted filtration method for removing natural
organic matter (I0548)
Haoyuan Zhou, Xiaochan An, Zhongyun Liu, Yunxia Hu
(Yantai Institute of Coastal Zone Research, Chinese
Shengji Xia, Muzi Ni, Nana Li, Yu Zhao ( Tongji
University)
P164
P169
Manipulating the multifunctionalities of
polydopamine to prepare high-flux antibiofouling composite nanofiltration membranes
(I0426)
Conjugated microporous polymers for metal
ions removal (I0579)
Ruixia Yang (Dalian Institute of Chemical Physics)
Runnan Zhang, Zhongyi Jiang, Yanlei Su (Tianjin
University)
P165
P170
Composite CNTs-Polyaniline electro-conductive
membranes (I0438)
Highly stable graphene oxide membranes
prepared on polydopamine functionalized
supports for seawater desalination (I0592)
Wenyan Duan, Avner Ronen, Sharon Walker, David
Jassby (University of California)
Kai Xu, Bo Feng, Aisheng Huang (Ningbo Institute of
Material Technology and Engineering )
Page 151
S9--Wat
S10--Par
P171
P176
Influence of low molecular weight alcohol with
single hydroxyl on performance of PVDF
ultrafiltration membrane (I0609)
Speeding Up Reactive Modeling of Fluidized Bed
Reactor by Combining CRE and Multiscale CFD
(J0083)
Feng Bai , Yan Dai, Gaohong He (Dalian University of
Technology)
Wei Wang, Bona Lu, Hao Luo, Hua Li, Mao Ye,
Zhongmin Liu, Jinghai Li (Institute of Process
P172
P177
Improved antifouling properties of poly(ether
sulfone) membrane: effect of the sequence
structures of amphiphilic modifiers (I0610)
Comparison of Bubbles Hydrodynamics in GasSolid Bubbling Bed Obtained from TFM and
DEM Simulation (J0121)
Guangfa Zhang, Qinghua Zhang, Xiaoli Zhan, Fengqiu
Chen (Zhejiang University)
Xingying Lan, Yingya Wu, Jinsen Gao (China University
of Petroleum(Beijing))
S10--Par
P173
P178
An Experimental Analysis of Pressure Drop
Fluctuations of Cyclone Separator in the FCCU
(J0173)
Xiaoman Li, Zhigang Wei, Guogang Sun , Chaoyu Yan,
Yaodong Wei (China University of Petroleum(Beijing))
P179
Functional Uniform Microparticles Tailored by a
Novel Spray Drying Technology (J0235)
Winston Duo Wu, Zhangxiong Wu, Jie Xiao, Nan Fu,
Xiao Dong Chen (Soochow University)
P180
Direct Liapunov Method for Predicting Maldistribution of Gas-solid Flow through Parallel
Lines (J0273)
Chenxi Zhang, Fei Wei , Weizhong Qian, Zhao Jia , Qi
Wang (Tsinghua University)
Page 152
S10--Par
S10--Par
P181
P186
Pyrolysis of long flame coal under steam
atmosphere in a fluidized-bed reactor (J0280)
Enhancing CO2 absorption into MEA solution by
nanoparticles (J0332)
Airong Li, Daohong Wu (Southwest Petroleum
University)
Wei Yu, Tao Wang, Hui He, Mengxiang Fang (Zhejiang
University)
P182
P187
Study on Discharging Characteristics of the
Cyclone Dipleg-Trickle Valve System in the FCC
Unit (J0284)
Hydromechanical simulation of bubbling
fluidized bed based on modified EMMS model
(J0417)
Zhigang Wei, Xiaoman Li, Xiaoyang Cao, Chaoyu Yan,
Yaodong Wei (China University of Petroleum(Beijing))
Bolun Yang (Xi'an Jiaotong University)
P183
P188
Gas-solids contacting efficiency in the high
density circulating fluidized bed reactors (J0290)
Oxygen Carrier Particle Design and
Development for Chemical Looping Processes
(J0491)
Chengxiu Wang, Jinsen Gao, Jesse Zhu (China
University of Petroleum(Beijing))
Liang Zeng, Jinlong Gong (Tianjin University)
P184
P189
Origin, propagation and attenuation of pressure
waves in a circulating fluidized bed standpipe
(J0299)
Numerical simulations of porous particles
settling using lattice Boltzmann method (J0496)
Jun Xu, Siqing Zhong, Zhinan Yu (Shanghai Research
Institute of Petrochemical Technology)
Cheng-Gong Li, Mao Ye, Jibin Zhou, Zhongmin Liu
(Dalian Institute of Chemical Physics)
P190
Spray-drying route to uniform and large
mesoporous titania microspheres for heavy
metal ions removal (J0497)
Xingmin Gao, Zhangxiong Wu, Xiaodong Chen,
Winston Duo Wu (Soochow University)
Page 153
S10--Par
S11--Pet
P191
P196
Hydromechanical simulation of bubbling
fluidized bed based on modified EMMS model
(J0511)
Effect of Copolymer Composition on pHResponsive Surface Wettability: Identifying the
Best Copolymer for Efficient Water/Oil
Separation (K0601)
Jiageng Li , Bolun Yang (Xi’an Jiaotong University)
S11--Pet
Yin-Ning Zhou, Jin-Jin Li, Zheng-Hong Luo (Shanghai
Jiao Tong University)
P192
P197
Catalytic Cracking of Vacuum Gas Oil and
Vacuum Residue Deasphalted Oil from Huizhou
Refinery (K0302)
Improving Fluorescence Bio-imaging with
Cyanine and Fluorescein Dyes (K0605)
Mengyao Wang, Tianhua Ren, Jiawen Zhou, Rui Zhang,
Haiyan Liu, Xianghai Meng(China University of
Petroleum(Beijing))
(Dalian University of Technology)
P193
P198
Reaction behavior of inferior residue in a
carbon-rejection process(K0351)
Development of cyclic pressure swing operating
process for hydrogen production by sorptionenhanced ethanol steam reforming (L0046)
Nan Jin , Gang Wang , Hongliang Wang , Jinsen Gao ,
Chunming Xu (China University of Petroleum(Beijing))
Fengling Song , Xiaoqing Xiong, Xiaojun Peng
Yi-Jiang Wu, Ping Li, Jian-Guo Yu , Alírio E. Rodrigues
S12--Pro
P194
P199
Fluorescent Probes for Cancer Cells (K0429)
Optimal thermodynamic feed conditions for
sharp separation distillation column with
double feeds (L0060)
Xiaojun Peng (Dalian University of Technology)
Xuegang Liu, Bingjian Zhang, Changchun He, Qinglin
Chen(Sun Yat-Sen University)
P195
P200
Low temperature catalytic naphthalene
hydrogenation to naphthalene over highlyloaded NiMo, NiW and NiMoW catalysts
(K0598)
Simulation and optimization of salt-production
from desalination brine (L0063)
Chenguang Liu, Huan Liu, Changlong Yin(China
University of Petroleum(East China))
Page 154
Lian-Ying Wu , Teng Sun(Ocean University of China)
S12--Pro
S12--Pro
P201
P206
Extractive distillation of hydrocarbons with
sulfolane and n-formylmorpholine mixture
based on modeling and simulation (L0064)
Dr.(L0411)
You Li, Xingang Li, Hong Li, Yonghong Li, Wentao Zhou
Qin Wang, Bingjian Zhang, Changchun He, Qinglin
Chen (Sun Yat-sen University)
P202
P207
Analysis of capacity expansion and retrofit for
crude distillation unit based on statistical model
(L0069)
Solid state fermentation of untreated and
steam-explode corn stalk for laccase production
from Trametes versicolor (L0458)
Kan Wang, Bingjian Zhang, Qinglin Chen(Sun Yat-sen
University)
Abiodun E. Adekunle , Chen Zhang , Chun-Zhao
Liu(Institute of Process Engineering, Chinese
P203
P208
A model for mixed heavy crude refinery and
multi-plant planning (L0076)
Modeling multistage crystallization fouling of
heat exchangers: How do crystal structures
affect heat transfer (L0478)
Xiaoqiao Huang, Yangdong Hu, Lijuan Song, Yuzhen
Zhang, Yongsheng Duan (China University of
Petroleum)
Jie Xiao, Jian Han, Xiao Dong Chen Rodrigues
P204
P209
Process simulations of CO2 desorption in the
novel direct steam stripping process with
different solvents(L0350)
Optimum target for double feeds preheating of
the stabilizer in absorption-stabilization units
(L0479)
He Hui, Fang Mengxiang, Wang Tao, Yu Wei
Xuegang Liu , Junjie Chen , Bingjian Zhang , Qinglin
Chen (Sun Yat-Sen University)
P205
P210
Progress on olefin polymerization process
technology in China (L0408)
CO2 mineralization using natural K-feldspar and
industrial waste: the role of mechanical
activation on the process intensification (L0519)
Yongrong Yang, Jingdai Wang, Musango Lungu, Can
Zi, Haotong Wang (Zhejiang University)
Wenjie Shangguan, Hairong Yue, Jimin Song, Longpo
Ye, Zhixi Gan, Siyang Tang, Chanjun Liu, Chun Li, Bin
Liang, Heping Xie(Sichuan University)
Page 155
S12--Pro
S13--The
P211
P216
Microwave-assisted preparation of the crystal
seeds for producing easily phase-transformed
anatase to Rutile (L0541)
Molecular dynamics simulation of nanoparticles modified viscoelastic fracturing fluids
(M0278)
Yaowen Zhang, Siyang Tang, Shaoyun Yuan, Hairong
Yue, Changjun Liu, Chun Li, Bin Liang(Sichuan
University)
Yaqian Ning, Tao Wang, Fei Xue, Zhongyang Luo
P212
CO2 Mineralization, Soluble potash salts
extraction, And sulfur recovery via Coupling
Carbothermal Reduction of Phosphogypsum
with Thermal Activation of Potash Feldspar
(L0562)
Zhixi Gan, Hairong Yue, Longpo Ye, Wenjie Shanguan ,
Siyang Tang, Changjun Liu, Chun Li, Bin Liang, Heping
Xie(Sichuan University)
P217
Quantum chemistry calculations for the
quaternary-ammonium-based CO2 sorbent
(M0320)
Kun Ge, Kexian Chen, Tao Wang, Mengxiang Fang
S13--The
P213
P218
Large-scale molecular dynamics simulation and
online measurement of thermal conductivity of
bulk silicon and silicon nanowires (M0061)
Separation of Li+ and Mg2+ in nanopores: a
molecular dynamics study (M0484)
Chaofeng Hou, Guoxian Gao, Ji Xu, Wei Ge, Jinghai Li
(Institute of Process Engineering, Chinese Academy of
Sciences)
Yang Ruan, Yudan Zhu, Xiaohua Lu, Yumeng Zhang,
Linghong Lu (Nanjing Tech University)
P214
P219
Metastable zone determination and crystal
growth of K2SO4 in the concentrated alkali
solution (M0072)
Fast phase diagram predictions of ternary
aqueous saline solutions: a density functional
approach (M0533)
Mengjie Luo, Chenglin Liu, Jin Xue, Ping Li, Jianguo Yu
Jie Zhang, Chongzhi Qiao, Shuangliang Zhao, Xingfu
Song (East China University of Science and
Technology)
P215
P220
Thermophysical and Electrochemical Properties
of Ionic Liquids with Azolide Anions (M0180)
The molecular dynamics simulations of friction
of confined liquid (M0563)
Joan Brennecke (University of Notre Dame)
Wei Chen (Computer Network Information Center,
Page 156
S13--The
S14--Sep
P221
P226
Numerical study on heat transfer of shear
thinning flow in twisted noncircular ducts
(M0570)
Selective extraction of lithium from brine with
ionic liquid systems (N0120)
Jingjing Chen, Ruiping Han, Shaopeng Zhang,
Changsong Wang, Xiaohua Lu (Nanjing Tech
University)
Chenglong Shi, Jinhe Sun, Yan Jing, Yongzhong Jia
(Qinghai Institute of Salt Lakes, Chinese Academy of
Sciences)
S14--Sep
P222
P227
Selective adsorption of thiophenic compounds
from fuel over TiO2/SiO2 under UV-irradiation
(N0050)
Experiment on the continuous separation of gas
mixtures via hydrate formation and dissolution
in the presence of hydrate promoter (N0154)
Guang Miao, Feiyan Ye, Luoming Wu, Zhong Li, Jing
Xiao (South China University of Technology)
Yang Luo, Aixian Liu, Xuqiang Guo, Qiang Sun, Lanying
Yang (China University of Petroleum(Beijing))
P223
P228
Preparation of Hybrid adsorbents with SelfImmobilizing Mycelia and Magnetic
Nanoparticles (N0052)
Recent advances in pressure swing adsorption
technology (N0159)
Qilei Zhang, Dongqiang Lin, Shanjing Yao (Zhejiang
University)
James A. Ritter, A. D. Ebner (University of South
Carolina)
P224
P229
Membrane Chemical Exchange (MCEx) for
lithium isotope separation (N0054)
Control of extractive distillation with heat
integration for separating benzene/cyclohexane
mixtures (N0172)
Jianfeng Song, Dingfeng Kong, Ran Zhang, Lixin Xing,
Baolong Zhao, Zhouwei Wang, Xuemei Li, Tao He
(Shanghai Advanced Research Institute, Chinese
Lumin Li, Yanan Tian, Lanyi Sun, Jian Zhai, Yuliang Liu
(China University of Petroleum(East China))
P225
P230
Studies on preparation and
absorption/desorption behaviors of Fe-doped
Li4SiO4 sorbent for CO2 capture at medium
temperatures (N0075)
The hydrodynamics and mass transfer during
centrifugal molecular distillation: simulations
and experiments (N0183)
Jiang Yu, Xigang Yuan, Aiwu Zeng (Tianjin University)
Sai Zhang, Qi Zhang, Chen Shen, Dong Peng, Zibin Zhu
Page 157
S14--Sep
S14--Sep
P231
P236
Phase equilibria and phase diagrams for the
aqueous ternary system (NaCl+Na2SO4+H2O) at
different temperatures (N0187)
Design, optimization and control of energysaving dividing-wall column for separating
azeotropes (N0277)
Haijiao Lu, Jingkang Wang, Hongxun Hao, Ying Bao
Ming Xia, Litao Jia, Bo Hou, Debao Li (Institute of Coal
Chemistry, Chinese Academy of Sciences)
P232
P237
Relating performance of thin-film composite gas
separation membranes to support layer
formation and structure (N0197)
Thin-film composite organic solvent
nanofiltration membranes: from flat-sheet to
hollow fibers (N0289)
Mengqi Shi, Zhi Wang, Jixiao Wang, Shichang Wang
Shi-Peng Sun, Tai-Shung Chung (Nanjing Tech
University)
P233
P238
Practical gas separation polymer membranes in
the organic fluorine industry (N0200)
Experimental study on mass transfer of CO2 in
mixed solvents using a wetted-wall column
(N0303)
Xuehua Ruan, Yan Dai, Gaohong He, Xiaoming Yan,
Baojun Li (Dalian University of Technology)
Fei Liu, Xuping Zhou, Tao Wang, Mengxiang Fang
P234
P239
Membrane properity analysis and optimize for
hydrogen purification (N0202)
Novel bio-crosslinking Schiff base adsorbent for
silver ions rapid removal: synthesis,
characterization, and adsorption property and
mechanism (N0307)
Jiayou Xu, Zhi Wang, Chenxin Zhang, Song Zhao,
Zhihua Qiao, Panyuan Li, Jixiao Wang, Shichang Wang
(Tianjin University )
Qiangfeng Yin (East China University of Science and
Technology)
P235
P240
[Bmim][FeCl4] for the extractive separation of
aromatic and aliphatic hydrocarbons (N0224)
Separation of low boiling gas mixture by a
hybrid absorption-adsorption method (N0310)
Hao Tong , Linyang Qiu , Rui Zhang , Haiyan Liu ,
Xianghai Meng
(China University of Petroleum(Beijing))
Bei Liu, Huang Liu, Yong Pan, Changyu Sun, Guangjin
Chen (China University of Petroleum(Beijing))
Page 158
S14--Sep
S14--Sep
P241
P246
Synthesis of energy efficient separation
processes using distillation (N0330)
Investigation of fine particle packing structure
by introducing a wide-ranged and adjustable
interparticle force (N0370)
Gautham Madenoor Ramapriya, Zheyu Jian, Rakesh
Agrawal, Mohit Tawarmalani (Purdue University)
Fushen Yang, Ning Li, Le Du, Weidong Zhang (Beijing
University of Chemical Technology)
P242
P247
Structure-controllable adsorbents for CO2 air
capture in moisture swing process (N0352)
The application of PTFE hollow fiber membrane
in alcohol amine absorber desorption process
(N0371)
Jun Liu, Tao Wang, Chenglong Hou, Mengxiang Fang,
Zhongyang Luo (Zhejiang University)
Tianran Yu, Xianhang Jin, Ye Yang, Xinyang Du, Le Du,
Yuhai Guo, Weidong Zhang (Beijing University of
Chemical Technology)
P243
P248
Dispersion of adsorption active sites by using
confined space (N0363)
Preparation and modification of PPhTMS
ethanol-permselective pervaporation
separation membrane (N0372)
Lin-Bing Sun, Xiao-Qin Liu (Nanjing Tech University)
Junna Zhang, Wei Jia, Zhongqi Cao, Le Du, Weidong
Zhang (Beijing University of Chemical Technology)
P244
P249
Preparation of a high-flux pervaporation
PDMDES membrane to separate dilute
alcohol/water (N0368)
Efficient carbon capture by constructing CO2philic surface on integrally skinned asymmetric
membranes via surface segregation (N0415)
Wei Jia, Chunjie Xia, Yanping Yu, Zhongqi Cao, Le Du,
Weidong Zhang (Beijing University of Chemical
Technology)
Shaofei Wang, Zhizhang Tian, Hong Wu, Zhongyi Jiang
P245
P250
Development of MEA-based solvents for CO2
capture (N0369)
Synthesis of NaY zeolite membrane for
pervaporation separation of alcohol/water
mixtures (N0416)
Xianhang Jin, Le Du, Weiwei Tu, Jinming Xing, Ye Yang,
Weidong Zhang (Beijing University of Chemical
Technology)
Fei Zhang, Longnv Xu, Xiangshu Chen (Jiangxi Normal
University)
Page 159
S14--Sep
S14--Sep
P251
P256
NaKA zeolite adsorbents with high CO2-N2
selectivity for CO2 capture (N0437)
Continuous de-emulsification of
Kerosene/Water Emulsions with a Threedimensional Spiral Asymmetric Plate-type
Microchannel (N0587)
Bo Yang , Yan Liu , Ming Li (Tongji University)
Zhi-Kun Yao, Da Ruan, Xiao Chen, Zhi-Gang Zhao
(Southwest University for Nationalities)
P252
P257
Research and application of steel slag
separation technology (N0487)
Imidazole functionalized graphene oxide /
PEBAX mixed matrix membrane for CO2 capture
(N0608)
Yongli Xiao, Yongqian Li, Yin Liu, Youping Zhang
(Baosteel Research Institute)
Yan Dai, Zhijun Yan, Miao Yu, Feng Bai, Hao Li,
Gaohong Heg (Dalian University of Technology)
P253
P258
Modeling and simulation of CO2 capture from
biogas using aqueous (N0531)
Sodium 1,2,4-1H-Triazole incorporated mixed
matrix membrane for CO2 separation (N0611)
Chunyan Ma (Nanjing Tech University)
Miao Yu, Yan Dai, Kai Yang, Hao Li, Gaohong He
(Dalian University of Technology)
P254
Novel extraction methods: High intensity pulsed
electric field extraction and ultrahigh pressure
extraction (N0571)
Lang He, Liang-gong Yan, Jun Xi (Sichuan University)
P255
Numerical simulation of mechanical property of
plant cell during ultrahigh pressure extraction
process (N0576)
Lianggong Yan, Lang He, Jun Xi (Sichuan University)
Page 160
Poster Presentation
Sup
P259
Design of hierarchical zeolite Y catalysts by
sequential dealumination- desilication (K0540)
Da Zhijian , Li Wenlin , Luo Yibin , Zheng Jinyu
(Research Institute of Petroleum Processing, SINOPEC)
P260
Study on the crystallite orientation of clustered
AlOOH nano-sheets(H0044)
Yuming Sun, Ping Li(East China University of Science
and Technology)
P261
Exploring the mechanisms underlying the
formation of core-shell particles by spray drying
of homogenous droplets (E0212)
Nan Fu(Soochow University)
P262
Effect of microstructure on the swelling and
dissolution of protein hydrogels(M0260)
Ruben Mercade Prieto, Hui Li , XiaoDong Chen
P263
Introduction of a second promoter to NiMobased catalysts: Preparation, characterization,
and hydrodesulfurization activity(K0529)
Chenguang Liu, Changlong Yin , Huan Liu (China
University ofPetroleum (East China))
P264
Synthesis of cobalt nitrides and their catalytic
performance for NO dissociation(H0574)
Meng Bo , Gao Jian (Zhengzhou University)
Organizer
Sponsors
Special Sponsors
The 8th Sino-US Joint Conference of Chemical Engineering
October 12-16 • 2015 • SHANGHAI • CHINA

SUChE 2015--program book-22 - The 8th Sino

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