Leigh McCook, principal research associate at Georgia Tech, also serves as deputy director for IPaT, director of STEM programs for the Georgia Tech Research Institute (GTRI), and previously served as division chief for fifteen years in GTRI’s socio-technical systems division in the Information and Communications Lab. She has been with Georgia Tech for more than 30 years.

As deputy director in IPaT, McCook works to build new research partnerships across campus as well as develop government, industry, and international programs. While she continues to conduct research, McCook's focus has centered on growing IPaT’s research portfolio of state government and industry projects, particularly in education, humanitarian systems, health and smart cities.

McCook’s GTRI activities include directing research and outreach programs for regional and national centers and managing a variety of research and STEM programs funded by federal, state, and local agencies.

Her career expertise includes technology transfer, research translation, outreach, planning, and program management, specifically in areas related to emergency preparedness and response, homeland security, community resiliency, and education. She has managed researchers working a variety of programs in health, learning technology, planning, technology assessment, and integration, policy analysis and research, technology transfer, education, training, public safety, humanitarian, and emergency response.

McCook served as program manager for the Georgia Emergency Management Agency (GEMA) Homeland Security/Emergency Response programs at the Georgia Tech Research Institute since 2000. Twenty years of program support to GEMA has resulted in over $53M work of funded project work at GTRI.

McCook’s experience also includes having served as associate director for technology transfer and outreach for EPA’s Hazardous Substance Research Centers (South & Southwest). In this capacity she led technology transfer, research translation, and outreach activities for the five-university consortium.

McCook has served as principal investigator (PI) or co-PI on projects for the Centers for Disease Control and Prevention, the Georgia Department and Family and Child Services, the Governor’s Office of Student Achievement, the Atlanta Urban Area Security Initiative, and the Department of Homeland Security (DHS) Southeast Regional Research Initiative.

Dr. Anirban Mazumdar joined Georgia Tech as an Assistant Professor in Mechanical Engineering in 2018. Dr. Mazumdar studies robot mobility with the goal of understanding and achieving agile, versatile, and efficient robot behaviors in unstructured environments. His previous experience includes a postdoctoral research position in the High Consequence Automation and Robotics Group at Sandia National Laboratories in Albuquerque, NM. He has broad experience with novel robotic systems including energy efficient bipedal robots, reconfigurable aerial vehicles, prosthetic devices, and relaxed stability mobile robots.

Dr. Mazumdar started at the Woodruff School of Mechanical Engineering at Georgia Tech in January of 2019 and currently has a courtesy appointment with the Guggenheim School of Aerospace Engineering. She graduated with her Ph.D. from Massachusetts Institute of Technology and completed a postdoctoral appointment at Sandia National Laboratories in the Diagnostic Science and Engineering group. Her research interests include the design of new diagnostic techniques and sensor systems for studying combustion, multiphase flows, hypersonic flows, and energetic materials. Her group utilizes new composite sensing materials, optical diagnostics, magnetostatics, and system identification methods to study these complex physical phenomena.

Dr. Mayor is a distinguished expert in thermal sciences, electro-mechanical machine design, and micro-manufacturing. As the inventor of the DwHX cooling technology for electric machines, he specializes in the research and development of advanced power electronics cooling, electric machine design, micro-power generation, and sustainable energy systems. Alongside his technical pursuits, Dr. Mayor has a rich entrepreneurial backdrop, having navigated product-oriented tech startups and led multiple advanced research and development programs. His expertise is sought in IP litigation, where he serves as a technical authority. 

He has presented keynotes and seminars on diverse topics, from micro-manufacturing and electric machines to energy systems. He teaches courses in mechanical engineering courses at Georgia Tech, including machine design, manufacturing processes, design thinking and internal combustion engines, including H2ICE, and has taught courses as a visiting lecturer in China, France, Saudi Arabia, and South Africa. He has a substantial academic contribution with over 120 publications in leading archival journals and conferences and is a member of ASME and IEEE and SME. 

Dr. Mayor's commitment goes beyond teaching and research as he engages in service as the Secretary of the Faculty. He strives to build on the learnings from the pandemic to expand the resourcefulness, understanding, and trust in shared governance. Moreover, Dr. Mayor serves as the faculty advisor for the Student Competition Center, further highlighting his commitment to student mentoring and leadership development. He looks forward to implementing AI in a robust manner in institute learnings, as a core capability in education.

Dimitri Mavris is a Regents’ Professor, Boeing Professor of Advanced Aerospace Systems Analysis, and an S.P. Langley Distinguished Professor. He also serves as the director of the Aerospace Systems Design Laboratory (ASDL) and executive director of the Professional Master’s in Applied Systems Engineering (PMASE). Dr. Mavris received his B.S., M.S., and Ph.D. in aerospace engineering from the Georgia Institute of Technology. His primary areas of research interest include: advanced design methods, aircraft conceptual and preliminary design, air-breathing propulsion design, multi-disciplinary analysis, design and optimization, system of systems, and non-deterministic design theory. Dr. Mavris has actively pursued closer ties between the academic and industrial communities in order to foster research opportunities and tailor the aerospace engineering curriculum towards meeting the future needs of the US aerospace industry. He has also co-authored with his students in excess of 1,000 publications. During his tenure at Georgia Tech, Dr. Mavris has chaired and served in several Technical and Program Committees for the American Institute of Aeronautics and Astronautics (AIAA) and served on the AIAA Board of Directors and Institute Development Committee. He is the President of the International Council of the Aeronautical Sciences (ICAS). He is the Georgia Tech technical point of contact for the FAA Center of Excellence for Alternative Jet Fuels & Environment (ASCENT), the Georgia Tech site director for the FAA Partnership to Enhance General Aviation Safety, Accessibility, and Sustainability (PEGASAS), and the principal investigator for the Airbus/Georgia Tech Center for MBSE-enabled Overall Aircraft Design and the Siemens Center of Excellence for Simulation and Digital Twin.

Daniel Matisoff teaches and conducts research in the areas of public policy, energy policy, and corporate sustainability. His research focuses on the effectiveness and efficiency of comparative approaches to addressing environmental problems and the adoption and diffusion of energy technologies and policies. He currently is a fellow with the Brook Byers Institute for Sustainability, and is affiliated with the Strategic Energy Institute and Center for Urban Innovation. He has participated in over $4 million of sponsored research through the National Science Foundation, the European Union Center for Excellence, the German Academic Exchange Service, the Georgia Department of Transportation, and the National Electric Energy Testing Research and Applications Center. His recent research has resulted in publications in the Review of Environmental Economics and Policy, Environmental and Resource Economics, Energy Economics, Environmental Science and Technology, Energy Policy, and Business Strategy and the Environment, among other outlets. His current research interests include: evaluating the effectiveness of voluntary eco-labeling programs; the effectiveness of incentives for solar electricity; the adoption of smart grid technologies and policies; and the impact of large scale solar adoption on consumer rates and bills.

Martin Maldovan is an associate professor in the School of Chemical and Biomolecular Engineering and the School of Physics at the Georgia Institute of Technology. He received his Ph.D. at the Massachusetts Institute of Technology (MIT) in the Department of Materials Science and Engineering. He was also a postdoctoral associate and research scientist at MIT.  Maldovan’s group is developing novel heat and mass transport processes as an enabling technology for energy converter materials and devices, micro and nanoelectronics, chemical and biological separations, and catalysis. His group focuses on designing, predicting, and controlling heat and mass transfer in rationally engineered systems with length scales ranging from macro to nano, to advance new paradigms for energy saving materials and devices.  

Dr. Jian Luo completed his undergraduate and M.S. studies at Tsinghua University, Beijing, where he received a B.Sc.(Eng.) and a M.S. degree in Environmental Engineering in 1998 and 2000, respectively. He completed his Ph.D. in 2006 in Department of Civil and Environmental Engineering at Stanford University, California. The research Dr. Luo is conducting involves field, theoretical, and computational investigations of flow and reactive transport in subsurface; development and application of geostatistical methods for the spatial and temporal analysis of hydrogeologic and biochemistry data; development of computational algorithms and programs to simulate subsurface flow and reactive transport, and to assess the associated uncertainty; inverse modeling to estimate flow and transport parameters under uncertainty; and use of such computational methods and models to assess subsurface contamination, and to aid the optimal design of groundwater remediation operations.