Volume 3, Issue 3 - NASA Postdoctoral Program
Transcription
Volume 3, Issue 3 - NASA Postdoctoral Program
NASA Postdoctoral Program Quarterly Update Volume 3, Issue 3— April 2015 In This Issue: Center Stage: JPL ........................................................................................... 2 Game Changers: SSERVI FINESSE Team ..................................................... 3 Modelling the Atmosphere of Early Earth, Continued.................................. 4 SSERVI FINESSE NPP Alumni, Continued.............................................. 5 & 6 Modeling the Atmosphere of Early Earth: Benjamin Charnay, NAI Fellow Smog, the nuisance that plagues cities and wreaks havoc on human health and the environment today, may have actually been an important component in the survival of life on early Earth. The possible existence of this highly stigmatized substance during Earth’s youthful years, as well as its significance to early climate and life, is what Benjamin Charnay, a NASA Postdoctoral Program Fellow at the University of Washington, Seattle, hopes to better understand. Photochemical smog is the result of a process called photolysis, a chemical reaction between chemical compounds and photons, often from solar energy. This type of reaction is what allows plants and cyanobacteria to produce diatomic oxygen (O2) from sunlight and water, and is also responsible for the formation of the ozone layer in the stratosphere, which protects us from harmful UV radiation. On the other hand, photolysis contributes to the formation of tropospheric ozone, a harmful component of smog. Benjamin Charnay researches the use of Charnay’s research focuses on the formation of organic haze General Circulation Models, or GCMs, to better in the upper-level atmosphere of early-Earth, a result of understand the atmospheric conditions photolysis of the once methane-rich atmosphere to form present on early Earth and the exoplanet hydrocarbons. The resulting haze could have been very similar GJ1214b. (Photo courtesy of Benjamin to that seen on Saturn’s moon Titan today. Charnay) “There is potential geological evidence for the presence of photochemical haze during early Earth,” Charnay said. “The issue is that haze would have cooled the planet, which could have led to full glaciation and been catastrophic for life. But the haze might have also protected primitive life from UV radiation in the absence of an ozone layer at the time, which would have benefitted life.” To understand all of the elements in play during the Earth’s early years, Charnay, who has a doctorate in Planetary Science from the University Pierre and Marie Curie in France, researches ways to model the atmosphere of early Earth using general circulation models, or GCMs. A GCM uses foundational equations from the basic laws of physics and chemistry to compute atmospheric motion and various other physical processes that affect weather and climate—such as the transfer of solar energy or the formation of clouds—to simulate an atmosphere. By entering different equations, and therefore manipulating the conditions of the simulation, researchers can evaluate the impact of shifting conditions, such as climate change, but can also simulate atmospheric conditions from Earth’s past. (Continued page 4) Page 1 NASA Postdoctoral Program Quarterly Update Volume 3, Issue 3— April 2015 Center Stage: Jet Propulsion Laboratory In a dry riverbed wash at the foot of the San Gabriel Mountains—just far enough away from Pasadena’s residential areas for the “Suicide Squad” to test their occasionally explosive fuel mixtures and rocket motor designs—the Jet Propulsion Laboratory (JPL) was born. JPL’s complex history began in the 1930s with the liquid rocket experiments conducted in association with Caltech's Guggenheim Graduate School of Aeronautics. The “Suicide Squad” consisted of graduate students and non-students alike: Theodore von Karman, Frank Malina, John Whiteside Parsons, Edward Forman and others. They established the modest beginnings from which the JPL would eventually take form. Interestingly, despite its name, air breathing jet engines have never been the focus at JPL. According to von Karman, rockets at that time were considered science fiction, so they started referring to their work as "jets”—alluding to the jet-assisted booster rockets designed to assist heavily laden aircraft on short runways. The allusion stuck. In addition to their work on jet-assisted takeoff, the Caltech group also worked with the U.S. Army Air Corps to develop short range ballistic missiles for WWII. This resulted in a series of progressively sophisticated rockets, which the group respectively named Private, Corporal, and Sergeant. In 1957 and 1958, dual Navy and Army-JPL proposals competed to launch a scientific payload. In January 1958, several months after the launch of Sputnik 1 and immediately following the launch pad explosion of the Navy's Vanguard, JPL quickly assembled and launched Explorer 1, which radioed back information relating to temperature, micrometeorites and radiation environments, which were later to become known as the Van Allen belts. Later in 1958, JPL was transferred from the Army to the newly created National Aeronautics and Space Administration (NASA), and the 1958 success of Explorer 1 became just the first on a list of continued JPL missions in space exploration. JPL currently conducts a range of solar system exploration, Earth science, and space-based astronomy missions, as well The Jet Propulsion Laboratory was officially named in 1944, almost 14 years before NASA was formed. It was first funded by the U.S. Army to develop rocket technology, but was transferred over to NASA in 1958. (Photo courtesy of NASA) as technology research and development. JPL spacecraft have explored all of the solar system’s planets, and the lab is responsible for all of the four successful rovers sent to Mars. Today, JPL is staffed and managed for the U.S. government by the California Institute of Technology (Caltech). This makes JPL employees unique among NASA Centers in that they are not government employees but are instead employed by Caltech. In addition to telescopic facilities at Table Mountain, JPL also manages the Goldstone Communications Complex as part of the NASA Deep Space Network. JPL currently hosts 45 NPP Fellows who conduct research in planetary, earth, astrophysics and technology. Postdoctoral scholars are a critical part of JPL’s research community. They bring fresh ideas and enthusiasm to JPL, and we are grateful for the opportunity to have such talented individuals. We are committed to providing the best possible experience to our postdocs. Rowena Kloepfer JPL NPP Center Representative Page 2 NASA Postdoctoral Program Quarterly Update Volume 3, Issue 3 — April 2015 Game Changers: SSERVI FINESSE Team NPP Alumni The rocks of the Earth, Moon, and asteroids likely seem dramatically different to the casual observer, but to a planetary geologist, the Earth—green, warm and habitable—may just be the next best thing when it comes to studying the bare, cold and lifeless features of the Moon and asteroids. This unusual comparison is what has led scientists of the Field Investigations to Enable Solar System Science and Exploration (FINESSE) team to the barren volcanic fields of Craters of the Moon National Monument in Idaho. “Nearly every type of lunar volcanic feature is represented at Craters of the Moon and immediate surroundings,” said Dr. Jennifer Heldmann, NPP alumnus and PI of the FINESSE team. Like most planetary bodies, including the Earth, the Moon and asteroids have been subject to the dominating forces of volcanism and celestial impacts. Volcanic fields and impact structures here on Earth serve as geologic analogues to the target bodies studied by FINESSE—the Moon, near-Earth asteroids or NEAs, and Phobos and Deimos, the moons of Mars. The FINESSE team is funded through a grant from NASA’s Solar System Exploration Research Virtual Institute (SSERVI), formerly the NASA Lunar Science Institute (NLSI), which is based at Ames Research Center (ARC) in California. Heldmann and the rest of the FINESSE research team were awarded a five-year grant through SSERVI to conduct field-exploration science at Craters of the Moon National Monument and Preserve in Idaho and at the West Clearwater Lake Impact Structure in northern Canada. These sites represent unique opportunities on Earth to gain knowledge on the formation and evolution of volcanic landforms and to view the three-dimensional structure and geology of impact craters. They therefore serve as first-hand equivalents for improved understanding of lunar and asteroid surficial geology, and also allow the evaluation of proposed future human-robotic exploration of these target bodies. These opportunities are the two primary objectives of the FINESSE team. “The goal of FINESSE volcanic studies,” explained Heldmann, “is not just to understand the formation of certain volcanic features on the Moon, but also to Landscapes such as this pahoehoe lava flow at Craters of the Moon National Monument and Preserve in Idaho provide FINESSE team scientists with a unique opportunity to study Earth analogs to the surficial geology of moons and asteroids. (Photo courtesy of NPS) assess how we can best explore these features with robotic and human assets on the surface.” The objective is to document volcanic and impact features within the limitations of current planetary exploration technologies. This will help researchers evaluate current proposals for human-robotic missions to the SSERVI target bodies. “In our field studies at Craters of the Moon,” said FINESSE member Dr. Catherine Neish, also an NPP alumnus, “we are learning the importance of understanding surface roughness before sending rovers or humans out to explore new terrains.” (Continued on pages 5 & 6) Page 3 NASA Postdoctoral Program Quarterly Update Volume 3, Issue 3— April 2015 Modeling the Atmosphere of Early Earth: Benjamin Charnay, NAI (Cont.) (Continued from page 1) “A GCM is really a planet simulator,” Charnay explained. “Our goal is to develop a universal model able to simulate any kind of atmosphere around any planet. So, we need a very robust and flexible model that will work for conditions that can be very different from those on present-day Earth.” Charnay and his colleagues hope that their 3D GCM will unravel the mystery of early Earth’s atmosphere by simulating the formation of organic haze and its climatic impact. “We don’t know if the cooling of the planet by haze would really be important or not because of all the different climate couplings and feedbacks,” Charnay explained. “Only a 3D GCM can give a clear answer to this question.” In addition to modeling the atmosphere of early Earth, Charnay’s research also focuses on the clouds and haze that are estimated to be quite common in exoplanetary atmospheres. His primary object of research is the exoplanet GJ1214b, a super-Earth, or planet with a mass greater than that of the Earth, but significantly less than that of the gaseous planets Uranus or Neptune. The atmosphere of early Earth may have had a composition and chemistry quite similar to that of Saturn’s moon Titan, which consists largely of nitrogen, methane and a thick outer layer of photochemical haze, or smog. (Photo courtesy of National Geographic News) efforts to detect evidence of life. “Clouds and haze are very common in exoplanetary atmospheres, and they impact our ability to detect a biosignature,” Charnay said. “It is therefore necessary to characterize them and understand how they impact An exoplanet is a planet that orbits a star other than observational spectra. This may allow us to determine the sun. Over 1800 exoplanets have been discovered, the best wavelength for seeing through the clouds.” and a majority of these have been identified within our Charnay hopes that he can continue work with own Milky Way Galaxy. Exoplanets have become increasingly important to planetary scientists because exoplanets long after his NASA postdoctoral research. many of them are known to exist in the “habitable zone,” or “Goldilocks zone,” which is at just the right distance from a star to not be too hot or cold, and to have the right amount of atmospheric pressure to support liquid water. In other words, exoplanets represent a great possibility to discover life on another planet. “The number of discovered exoplanets grows exponentially,” Charnay said. “We have already identified more than one thousand, and with the GAIA mission—launched in 2013—we will discover thousands more in the next four years!” “It is really crazy how fast the field of exoplanet research has evolved, both in terms of discoveries and in understanding,” Charnay said. “In 10 years, amazing new space technologies will have been launched to observe exoplanets, such as TESS and PLATO. I would love to still work as a researcher or professor in this area during this time of many discoveries.” Charnay’s advisor is Dr. Victoria Meadows of the NAI Virtual Planetary Laboratory (NAI-VPL) at the University of Washington. His co-advisor is Dr. David Catling. The NAI-VPL is funded by a five-year CAN-6 Cooperative Agreement through the NAI, which currently funds 12 Charnay hopes that a 3D GCM will help him and his colleagues to better characterize the atmospheres of teams at universities and NASA centers across the GJ1214b and other exoplanets, and therefore improve country. Page 4 NASA Postdoctoral Program Quarterly Update Volume 3, Issue 3— April 2015 Game Changers: SSERVI FINESSE Team NPP Alumni, Cont. (Continued from page 3) In addition to its primary objectives, the FINESSE team also provides opportunities for education and outreach through NASA’s Spaceward Bound Program, which is supported by the Idaho Space Grant Consortium at Craters of the Moon, and through undergraduate and graduate research programs, including the NASA Postdoctoral Program (NPP) administered by ORAU. The Spaceward Bound program is designed to train students and teachers in exploration and settlement of the often harsh environments of space using similar landscapes here on Earth. “The teachers are useful contributors to the scientific program,” said Heldmann, “and they also help researchers to remember why this research is so important to students and the next generation of explorers.” Brent Garry (FINESSE team geologist) explains to Jeff Karlin (Spaceward Bound participant teacher) how to use LIDAR at the Highway Flow of Craters of the Moon National Monument and Preserve. (Photo courtesy of Scott Hughes) In January 2015, the FINESSE team advertised a NPP research opportunity to assist the SSERVI funded team with research at Craters of the Moon. The next NPP application deadline is July 1st. Currently, these four NPP alumni serve on the FINESSE team: Dr. Jennifer Heldmann (Ames NPP Fellow 2003–2006), FINESSE team PI, currently serves as a Research Scientist for the Division of Space Science and Astrobiology at NASA Ames Research Center. Much of her research uses Mars and moon-analog environments on Earth to better understand the geomorphology and habitability of planetary bodies. She recently served as Observation Campaign Coordinator for NASA’s Lunar Crater Observation and Sensing Satellite (LCROSS) mission, which confirmed the presence of water ice and other important volatiles in the Cabeus craters at the Moon’s South Pole. She is also largely involved in the optimization of human-robotic exploration strategies. Recent projects include the ISRU Regolith and Environment Science and Oxygen Lunar Volatiles Extraction (RESOLVE) field test (2012) and the Mojave Volatiles Prospector (MVP) field program (2013–2014). Heldmann currently serves as an advisor in the NPP at Ames. By the Numbers Fellows in Residence as of today, April 30, 2015 209 “The NPP provides a fantastic opportunity for researchers to not only conduct research and publish papers, but also to provide the foundation for their future career. My postdoc position was integral to helping me establish my career as a planetary science researcher.” - Dr. Jennifer Heldman (Photo courtesy of Jennifer Heldmann) Page 5 NASA Postdoctoral Program Quarterly Update Volume 3, Issue 3— April 2015 Game Changers: SSERVI FINESSE Team NPP Alumni, Cont. Dr. Darlene Lim (Ames NPP Fellow 2004–2007), FINESSE team Deputy PI, is a Research Scientist and Principal Investigator with the Bay Area Environmental Research Institute (BAERI) based at the NASA Ames Research Center. Lim is also the PI for the Pavilion Lake Research Project (PLRP), which she founded in 2004. Lim’s research focuses on the development of ConOps for human exploration of the solar system. Lim is currently MEPAG Goal IV (Prepare for Human Exploration) Co-Chair and founder of the Haven House Family Shelter Explorers Speakers Series, which allows scientists to teach STEM subjects to homeless children in the San Francisco Bay Area. Lim was selected to Wired Magazine’s Smart List in December 2013, and was awarded a NASA Ames Honor Award for Contractor achievement in 2012. She was recently awarded the 2014 NASA Honor Award for Group Achievement for the PLRP and in November 2014 was named to NOAA’s Ocean Exploration Advisory Board. Dr. Catherine Neish (Goddard NPP Fellow 2012– 2013), FINESSE member, is currently an assistant professor of Physics and Space Sciences at the Florida Institute of Technology but has plans to move to the University of Western Ontario in Summer 2015. Neish was granted the Ron Greeley Early Career Award in Planetary Science from the AGU in 2014 and is currently funded by a grant from NASA’s Outer Planets Research Program. “The great value of the NPP program is the flexibility it offers, and the opportunity to work alongside experts in your field, learning from them and forming lifelong collaborations.” - Dr. Catherine Neish Dr. Noah Petro (Goddard NPP Fellow 2007– 2009), FINESSE member, currently serves as a Research Scientist at the NASA Goddard Space Flight Center, a position he accepted after his NPP research there in 2009. Petro currently serves as Deputy Project Scientist for the Lunar Reconnaissance Orbiter (LRO) mission and was awarded the NASA Early Career Achievement Award in 2012. He currently serves as an advisor in the NPP at Goddard. “The NPP gave me an opportunity to work at a NASA Center and get exposed to what is done here. During my NPP I was able to build collaborations with other scientists here and develop as a scientist.” - Dr. Noah Petro “I wanted to have a career that blended science and exploration, and my NPP position at NASA Ames was really the launch pad for the research experiences that I’ve been so fortunate to garner over the past decade.” - Dr. Darlene Lim (Photo courtesy Henry Bortman) Purpose of the Program The NASA Postdoctoral Program (NPP) supports NASA’s goals to expand scientific understanding of the Earth and the universe in which we live. Selected by a competitive peer-review process, NPP Fellows complete one-tothree-year Fellowship appointments that advance NASA’s missions in earth science, heliophysics, aeronautics and engineering, human exploration and space operations, and astrobiology. As a result, NPP Fellows contribute to national priorities for scientific exploration; confirm NASA’s leadership in fundamental research; and complement the efforts of NASA’s partners in the national science community. For more information, visit our website or find us on Facebook or Twitter. Page 6