Dr. Karyn Rogers joined the faculty at Rensselaer Polytechnic Institute in 2013 after serving as a Research Scientist at the Carnegie Institution of Washington, Assistant Professor at the University of Missouri, and a Deep Ocean Exploration Institute Postdoctoral Scholar at Woods Hole Oceanographic Institution. Dr. Rogers completed her PhD in Earth and Planetary Sciences at Washington University in St. Louis, with previous degrees awarded from Stanford University (M.S. 2001) and Harvard University (A.B. 1996). Dr. Rogers is a member of the New York Center for Astrobiology (NYCA) and the Institute for Data Exploration and Applications (IDEA).
Dr. Rogers’ research focuses on the relationships between microbial communities and environmental conditions in extreme ecosystems, and is broadly applied to understanding the nature of the origin of life on Earth, the potential for life throughout the solar system, and the extent of life in modern extreme environments. To advance our understanding of environmental microbiomes in these systems, Dr. Rogers research program includes field research in early Earth and Mars analog environments as well as laboratory experimental studies of microbial behavior under extreme conditions. Additionally, the group is exploring the viability of abiotic synthesis of biomolecules over a range of early Earth conditions. The driving question in this research is how realistic environmental conditions combine to form habitable niches that can both support the early emergence of life as well as the long-term survival of life in these environments. Dr. Rogers’ fieldwork includes several terrestrial hydrothermal systems including Cerro Negro Volcano, Nicaragua, the Vulcano shallow marine hydrothermal system in Italy, and several modern deep-sea mid-ocean ridge environments. These field endeavors are combined with extensive laboratory analytical and experimental techniques to develop a holistic picture of functional microbial ecosystems. More specifically, laboratory techniques include cultivation of extremophiles under high pressure, high temperature, acidic, and anaerobic conditions; a next-generation genomics approach to determine the functional environmental microbiome in extreme systems; geochemical analyses and modeling of environmental and bioenergetics parameters; and the synthesis of these datasets using novel data analytics.
Dr. Rogers’ research program currently includes two postdoctoral associates, four graduate students (in both Earth & Environmental Sciences and the Department of Biological Sciences), and several undergraduate researchers. The laboratory is housed in Jonsson-Rowland Science Center and includes a state of the art high-pressure microbial cultivation facility. Additionally, Dr. Rogers is the US Lead for the Deep Carbon Observatory’s (Sloan Foundation) High Pressure Sampling, Transport, and Cultivation User Facility and the co-chair of the UNOLS Deep Submergence Science Committee New User Program. Dr. Rogers teaches courses in Geobiology, Aqueous Geochemistry, the Origin of Life, Advanced Geomicrobiology, and Planetary Habitability.
Ph.D. in Earth and Planetary Sciences, Washington University, 2006
A.M. in Earth and Planetary Sciences, Washington University, 2001
M.S. in Geological & Environmental Sciences, Stanford University, 2001
A.B in Environmental Science & Public Policy and Earth & Planetary Sciences, Harvard University, 1996
- Lever, MA, KL Rogers, KG Lloyd, J Overmann, B Schink, RK Thauer, TM Hoehler, BB Jørgensen. 2015. Life under Extreme Energy Limitation: A Synthesis of Laboratory- and Field-Based Investigations. FEMS Microbiology Reviews, 39(5), 668-728.
- McCollom, TM , BM Hynek, K Rogers, B Moskowitz, TS Berquó. 2013. Chemical and mineralogical trends during acid-sulfate alteration of pyroclastic basalt at Cerro Negro Volcano and implications for early Mars. Journal of Geophysical Research-Planets, Special Issue: Early Mars III, 118(9), 1719-1751.
- Hynek, BM, TM McCollom, EC Marcucci, K Brugman, KL Rogers. 2013. Assessment of environmental controls on acid-sulfate alteration at active volcanoes in Nicaragua: Applications to relic hydrothermal systems on Mars. Journal of Geophysical Research-Planets, Special Issue: Early Mars III, 118(10), 2083-2104.
- Marcucci, EC, BM Hynek, KS Kierein-Young, KL Rogers. 2013. Visible-near infrared reflectance spectroscopy of acid-sulfate alteration in Nicaragua: Analogs for early Mars. Journal of Geophysical Research-Planets, Special Issue: Early Mars III, 118(10), 2213-2233.
- Kish, AL, PL Griffin, ML Fogel, RJ Hemley, KL Rogers, A Steele. 2012. High-Pressure Tolerance in Halobacterium salinarum NRC-1 and Other Non-Piezophilic Prokaryotes. Extemophiles, doi 10.1007/s00792-011-0418-8, 16(2), 355-361.
- Holden, JF, JA Breier, KL Rogers, MD Schulte, BM Toner. 2012. Towards an integrated view of biogeochemical processes at hydrothermal vents: advances in bioenergetic modeling, microbe-mineral interactions, and carbon flux estimates. Oceanography, 25(1), 196-208.
- Rogers, KL and MD Schulte. 2012. Organic sulfur metabolisms in hydrothermal environments, Geobiology, 10(4), 320-332.
- Hynek, BM, TM McCollom, KL Rogers. 2011. Cerro Negro Volcano, Nicaragua: An Assessment of Geological and Potential Biological Systems on Early Mars, In GSA Special Publication #483: Planetary Analog Environments (WB Garry and JE Bleacher, eds), Boulder, CO, pp. 279-285.
- Rogers, KL, JP Amend, S Gurrieri. 2007. Temporal variations in fluid chemistry and energy profiles in the Vulcano hydrothermal system. Astrobiology, 7, 905-932.
- Skoog, A, P Vlahos, KL Rogers, JP Amend. 2007. Concentrations, distributions, and energy yields of dissolved neutral aldoses in a shallow hydrothermal vent system of Vulcano, Italy. Organic Geochemistry. 38, 1416-1430.