Mark D. Losego is a professor in the School of Materials Science and Engineering at Georgia Tech. The Losego research lab focuses on materials processing to develop novel organic-inorganic hybrid materials and interfaces for microelectronics, sustainable energy devices, national security technologies, and advanced textiles. The Losego Lab combines a unique set of solution and vapor phase processing methods to convert organic polymers into organic-inorganic hybrid materials, including developing the science to scale these processes for manufacturing.  Prof. Losego’s work is primarily experimental, and researchers in his lab gain expertise in the vapor phase processing of materials (atomic layer deposition, physical vapor deposition, vapor phase infiltration, etc.), the design and construction of vacuum equipment, interfacial and surface science, and materials and surface characterization. Depending on the project, Losego Lab researchers explore a variety of properties ranging from electrical to electrochemical to optical to thermal to sorptive to catalytic and more.

Bernard Kippelen was born and raised in Alsace, France. He studied at the University Louis Pasteur in Strasbourg where he received a Maitrise in Solid-State Physics in 1985, and a Ph.D. in Nonlinear Optics in 1990. From 1990 to 1997 he was Charge de Recherches at the CNRS, France. In 1994, he joined the faculty of the Optical Sciences Center at the University of Arizona. There, he developed a research and teaching program on polymer optics and plastic electronics. In August 2003, Dr. Kippelen joined the School of Electrical and Computer Engineering at the Georgia Institute of Technology where his research ranges from the investigation of fundamental physical processes (nonlinear optical activity, charge transport, light harvesting and emission), to the design, fabrication and testing of light-weight flexible optoelectronic devices and circuits based on nanostructured organic materials. He currently serves as director of the Center for Organic Photonics and Electronics, and as co-president of the Lafayette Institute, a major optoelectronics commercialization initiative that is based at Georgia Tech-Lorraine in Metz, France. He currently holds 25 patents and has co-authored over 270 refereed publications and 14 book chapters. His publications have received over 20,000 citations and his h-index is 73 (Google Scholar). He served as chair and co-chair of numerous international conferences on organic optoelectronic materials and devices and as deputy editor of Energy Express. He was the founding editor of Energy Express.

Sholl’s research focuses on materials whose macroscopic dynamic and thermodynamic properties are strongly influenced by their atomic-scale structure. Much of this research involves applying computational techniques such as molecular dynamics, Monte Carlo simulations and quantum chemistry methods to materials of interest. Although the group's work is centered on computational methods, it involves extensive collaboration with experimental groups and industrial partners.

Aarn Stebner works at the intersection of manufacturing, machine learning, materials, and mechanics. He joined the Georgia Tech faculty as an associate professor of Mechanical Engineering and Materials Science and Engineering in 2020.

Previously, he was the Rowlinson Associate Professor of Mechanical Engineering and Materials Science at the Colorado School of Mines (2013 – 2020), a postdoctoral scholar at the Graduate Aerospace Laboratories of the California Institute of Technology (2012 – 2013), a Lecturer in the Segal Design Institute at Northwestern University (2009 – 2012), a Research Scientist at Telezygology Inc. establishing manufacturing and “internet of things” technologies for shape memory alloy-secured latching devices (2008-2009), a Research Fellow at the NASA Glenn Research Center developing smart materials technologies for morphing aircraft structures (2006 – 2008), and a Mechanical Engineer at the Electric Device Corporation in Canfield, OH developing manufacturing and automation technologies for the circuit breaker industry (1995 – 2000).

Kalaitzidou joined Georgia Tech as an assistant professor in the G.W. Woodruff School of Mechanical Engineering in November of 2007. She also holds an adjunct appointment in the School of Materials Science and Engineering. She obtained her Ph.D. in manufacturing and characterization of polymer nanocomposites (PNCs) from Michigan State University and worked as a post-doctoral researcher on mechanics of soft materials in the Polymer Science and Engineering Department at University of Massachusetts, Amherst. She was promoted to professor in 2019 and was also named a Rae S. and Frank H. Neely Professor in the same year. In November 2019 Kalaitzidou was named the Associate Chair for Faculty Development.

Ryan Lively was born in 1984. He spent approximately 16 years in Gainesville, FL and attended almost every home football game at The Swamp. He enrolled at Georgia Tech in 2002 as an eager Chemical Engineering student and has been a Yellow Jacket at heart ever since. During his studies at Georgia Tech, Ryan worked on research projects as diverse as ab initio quantum mechanical methods to estimate molecular binding energies, fresh Georgia peach preservation, composite spinneret design, dual-layer hollow fiber membrane spinning, and sorbent-loaded fiber spinning. Ryan introduced a rapid temperature swing adsorption (RTSA) approach for post-combustion CO2 capture, which was successfully demonstrated by adapting knowledge developed in membrane science to design unique nanoscale composite adsorbent/heat exchangers. After his Ph.D. (awarded in 2010), he spent almost 3 years as a post-doctoral research engineer at Algenol Biofuels, where he published 25 papers and filed two U.S. patent applications. His work at Algenol focused on developing energy-efficient liquid and vapor separation systems for downstream biofuel purification. 

He is now the Thomas C. DeLoach Professor in the School of Chemical & Biomolecular Engineering at the Georgia Institute of Technology. His current research seeks to revolutionize fluid separation processes critical to the global energy and carbon infrastructure. He has a specific focus on membrane- and adsorbent-based science and technology to address some of the most difficult chemical separations. His group’s research activities range from fundamental material science and discovery to translational engineering applications focusing on making and testing separation devices. 

Ryan has received a variety of awards for his research efforts including the 2020 Allan P. Colburn Award from AIChE, and the 2022 Curtis W. McGraw Award from ASEE. He is currently an Editor for the Journal of Membrane Science and is the Secretary of the North American Membrane Society. He is the Director of the Center for Understanding & Controlling Accelerated and Gradual Evolution of Materials for Energy (UNCAGE-ME), an Energy Frontier Research Center of the US Department of Energy. He has over 160 publications in the field of separations including articles in Science, Nature and other impactful venues.

Peralta-Yahya has been part of Georgia Tech since 2012. Her diverse research group composed of chemists, biologists, and chemical engineers works in the area of engineering biology, drawing from principles of biochemistry and engineering to build systems for chemical detection and production. Specifically, her group focuses on the development of G protein-coupled receptors for biotechnology and biomedical applications, and the engineering of biological systems for the production of fuels and functionalized plant natural products. Early on, her work was recognized with several awards including a DARPA Young Faculty Award, a DuPont Young Professor Award, a Kavli Fellowship by the US Academy of Science, and an NIH MIRA award. Her group’s key accomplishments are 1) the standardization of GPCR-based sensors in yeast to reduce the cost and accelerate the pace of drug discovery for these receptors, which are the target of over 30% of FDA approved drugs, and 2) the development of advanced biofuels, including pinene, which, when dimerized, has sufficient energy content to power rockets and missiles.  Today, her group is funded to work on these and other cutting edge areas – including how to power a rocket returning from Mars and how to make synthetic cells learn without evolution – by the National Institutes of Health, the National Science Foundation, the Department of Energy, and NASA.