Fedorov's background is in thermal/fluid sciences, chemical reaction engineering as well as in applied mathematics. His laboratory works at the intersection between mechanical and chemical engineering and solid state physics and analytical chemistry with the focus on portable/ distributed power generation with synergetic CO₂ capture; thermal management of high power dissipation devices and electronics cooling; special surfaces and nanostructured interfaces for catalysis, heat and moisture management; and development of novel bioanalytical instrumentation and chemical sensors. Fedorov joined Georgia Tech in 2000 as an assistant professor after finishing his postdoctoral work at Purdue University.

Dr. Medford is interested in leveraging materials informatics, statistics, and machine learning to maximize the practical impact of fundamental atomic-scale simulations in the field of surface science and catalysis. His research areas include heterogeneous catalysis, oxide surface chemistry, density functional theory, kinetic models, uncertainty quantification, and Bayesian optimization and inference.

Valerie Thomas is the Anderson-Interface Chair of Natural Systems and Professor in the H. Milton School of Industrial and Systems Engineering, with a joint appointment in the School of Public Policy. 

Dr. Thomas's research interests are energy and materials efficiency, sustainability, industrial ecology, technology assessment, international security, and science and technology policy. Current research projects include low carbon transportation fuels, carbon capture, building construction, and electricity system development. Dr. Thomas is a Fellow of the American Association for the Advancement of Science, and of the American Physical Society. She has been an American Physical Society Congressional Science Fellow, a Member of the U.S. EPA Science Advisory Board, and a Member of the USDA/DOE Biomass Research and Development Technical Advisory Committee. 

She has worked at Princeton University in the Princeton Environmental Institute and in the Center for Energy and Environmental Studies, and at Carnegie Mellon University in the Department of Engineering and Public Policy.

Dr. Thomas received a B. A. in physics from Swarthmore College and a Ph.D. in theoretical physics from Cornell University.

Tim Lieuwen is the executive vice president for research (EVPR) at the Georgia Institute of Technology. In this role, he oversees the Institute’s $1.4+ billion portfolio of research, economic development, and sponsored activities. This includes leadership of the Georgia Tech Research Institute (GTRI), the Enterprise Innovation Institute, 11 interdisciplinary research institutes (IRIs), and related research administrative support units.

In his 25-plus years at Georgia Tech, Lieuwen earned his master's and Ph.D. degrees in mechanical engineering (1996 and 1999, respectively) and has held multiple leadership positions. He has been the executive director of the Strategic Energy Institute (SEI) and served as the interim chair of the Daniel Guggenheim School of Aerospace Engineering in 2023.

Lieuwen has received numerous honors and recognition for his work in clean energy systems and policy, national security, and regional economic development. Additionally, he has been awarded the titles of Regents’ Professor and the David S. Lewis, Jr. Chair in AE. He is also a member of the National Academy of Engineering and is a fellow of the American Society of Mechanical Engineers and the American Institute of Aeronautics and Astronautics.

Tom Fuller is Professor of Chemical Engineering at the Georgia Tech. Dr. Fuller received a BS from the University of Utah in Chemical Engineering in 1982. Dr. Fuller then served for five years in the U.S. Navy working as a Nuclear Engineer. In 1992 he obtained a Ph.D. from UC, Berkeley also in Chemical Engineering. 

Subsequently, Dr. Fuller developed advanced lithium batteries while working as a postdoctoral fellow at Lawrence Berkeley National Laboratory. He then moved to United Technologies. He was responsible for technology development, design, assembly, and test of cell stacks for UTC Fuel Cells. 

His research group at Georgia Tech is focused on durability challenges for electrochemical systems. For the last eight years Dr. Fuller has been a Technical Editor for the Journal of the Electrochemical Society. In 2009 Dr. Fuller was named a Fellow of the Electrochemical Society.

The Strategic Energy Institute is excited to welcome Scott McWhorter as a 2023 Distinguished External Fellow. Scott will co-lead the concept development, visioning, partnership, and preliminary capture activities for Georgia Tech on the Department of Commerce Tech Hubs (“Hubs”) and expand Georgia Tech’s hydrogen activities and stature.

Scott is not new to the Georgia Tech campus and has previously worked with Dan Campbell of the Georgia Tech Research Institute (GTRI) on developing trace organic optical sensors based on evanescent waveguides. More recently, Scott worked with David Sholl (professor in the School of Chemical and Biomolecular Engineering at Georgia Tech through 2021), to develop the RAPID (Rapid Advancement in Process Intensification Deployment) Institute and then through his work with Southeast Hydrogen Energy Alliance (SHEA), started working with Comas Haynes of GTRI on hydrogen, where they brought together the ecosystem that was responsible for at least three hydrogen hub efforts in the South East.

Scott's work related to energy in his own words: 
My career has always related to energy even when I didn’t notice it. I started out in DNA microchips where we tried to understand the various aspects of fluidics (mass transport, thermal, and surface science) that influenced efficient separations. Using the tools from those efforts I transitioned into optical sensor development to monitor trace gases from the gas-solid catalyst interface in a fuel cell electrode to an unknown-unknown contaminant that might cause a failure mode in a weapons system. Over the past decade, my work in energy has focused namely on building partnerships in industrial manufacturing consortia (ManufacturingUSA Institutes) where I helped form both CESMII and RAPID and then focusing on developing technologies to solve the hydrogen storage and delivery challenges through either more efficient, energy dense solid-state storage or using electro magnetics to efficiently provide heat to catalysts to decompose a hydrogen carrier or plastic.