Xing Xie is the Carlton S. Wilder Assistant Professor in the School of Civil and Environmental Engineering at Georgia Institute of Technology. Prior to joining Georgia Tech, he was a post-doctoral scholar at California Institute of Technology. He received his B.S. (2006) and M.S. (2008) degrees in Environmental Science & Engineering from Tsinghua University, and a second M.S. degree (2012) in Materials Science & Engineering and a Ph.D. degree (2014) in Civil & Environmental Engineering from Stanford University. His research focuses on the applications of innovative materials for sustainable and reliable water and energy. He has worked on many projects related to water treatment and reuse, microbial detection and quantification, energy and resource recovery, energy storage, etc. He has published more than 60 peer-reviewed articles with more than 6,000 citations

Russell Gentry is professor of architecture and civil engineering (by courtesy) and a licensed structural engineer. He teaches graduate courses in building structures, computationally-driven fabrication and construction, and building integration. He is affiliated with the design computing faculty in the School of Architecture and the structural engineering and mechanics of materials faculty in the School of Civil Engineering. 

Gentry is the chair of ASTM D30.10, Composites for Civil Structures and an expert on the development of test methods for composite materials. He is a fellow of the International Institute for Fiber Composites (IIFC). He is the Georgia Tech principal investigator on the NSF-sponsored international initiative to develop alternative uses for decommissioned composite wind turbine blades. 

Gentry is the acting director of the Digital Building Laboratory (DBL), an applied research lab in the College of Design, focusing on computational design, building information modeling, and information technology in the AEC industry. He serves as the associate dean for faculty in the College of Design.

Ajeet Rohatgi received the B.S. (E.E.) degree from Indian Institute of Technology in 1971, the M.S. (Materials Engineering) from Virginia Polytechnic Institute and State University in 1973, and the Ph.D. in Metallurgy and Materials Science from Lehigh University in 1977. He joined the Westinghouse Research and Development Center in Pittsburgh, Pennsylvania in 1977 and became a Westinghouse Fellow while working on the science and technology of photovoltaic and microelectronic devices. Rohatgi joined the ECE faculty at Georgia Tech in 1985 and started a program on photovoltaics, which has become one of the best in the country. He has become an internationally recognized leader in photovoltaics. He is the founding director of the first university-based DOE Center of Excellence in Photovoltaic Research and Education. He is the author of more than 300 publications and holds 10 U.S. patents. Rohatgi has received numerous awards and distinctions from professional societies and Georgia Tech. He is the founder and CTO for Suniva.

Professor Doolittle is a native of Jonesboro, Georgia. He graduated from Georgia Tech with a bachelor's degree in electrical engineering with highest honors in 1989. He later received his Ph.D. in electrical engineering in 1996 from Georgia Tech. 

His thesis work revolved around identifying the device limiting defects in photovoltaic silicon materials using several custom designed and patented tools. He later worked as a Research Engineer II in the area of compound semiconductor growth with emphasis on wide bandgap semiconductors. He joined the Georgia Tech faculty in 2001. 

During his time at Georgia Tech he has helped develop academic programs in the areas of microelectronic fabrication, materials growth, characterization, and measurement system design. Professor Doolittle consults with industry in the areas of law, materials testing, MBE growth, and test equipment development. 
His hobbies include bible studies, classic cars, playing the guitar, and reading. Most of his free time is spent with his two teenage children.

W. Jud Ready is the executive director of the Space Research Institute. Prior to this role, he served as associate director of external engagement for the Georgia Tech Institute for Matter and Systems and director of the Georgia Tech Center for Space Technology and Research. He has also been an adjunct professor in the School of Materials Science and Engineering at Georgia Tech and a principal research engineer on the research faculty of Georgia Tech Research Institute (GTRI) for over a dozen years. Prior to joining the Georgia Tech faculty, he worked for a major military contractor (General Dynamics) as well as in small business (MicroCoating Technologies). He has served as PI or co-PI for grants totaling ~$17M awarded by the Army, Navy, Air Force, DARPA, NASA, NSF, NIST, industry, charitable foundations and the States of Georgia and Florida. His current research focuses primarily on energy, aerospace, nanomaterial applications, and electronics reliability.

Dr. Akanksha Menon is an Assistant Professor in the Woodruff School of Mechanical Engineering at Georgia Tech. Prior to this, she was a Rosenfeld Postdoctoral Fellow at Lawrence Berkeley National Laboratory, where she performed research on hybrid membrane-thermal desalination processes using solar energy, and she also contributed to the development of thermal energy storage materials. Dr. Menon completed her Ph.D. at Georgia Tech, where she focused on developing semiconducting polymers and new device architectures for thermoelectric energy harvesting. She holds a bachelor's degree from Texas A&M University at Qatar, as well as a master’s degree in Mechanical Engineering from Georgia Tech.

Her research group at Georgia Tech is working on technologies for the water-energy nexus.

Prior to joining MSE in July 2003 Professor Singh was a faculty member in Corrosion and Materials Engineering Group at The Institute of Paper Science and Technology (IPST) since 1996.  While in IPST Singh worked on fundamental as well as applied research projects related to the corrosion problems in the pulp and paper industry. From 1990 to 1996, he was a Senior Research Associate at Case Western Reserve University, Cleveland, Ohio, working on various materials and corrosion related research projects, including damage accumulation in metal matrix composites (MMCs), Environmental sensitive fracture of Al-alloys MMCs, and High temperature oxidation of Nb/Nb5Si3 composites. He received the Alcan International's Fellowship in 1988-90 to work on "Effects of Low Melting Point Impurities on Slow Crack Growth in Al Alloys,"  He has published over 50 papers in reputed scientific journals and conference proceedings. He is active member of NACE, TMS, TAPPI and has co-organized a number of international symposiums.

Reliable performance of the materials is very important for any industrial process and especially for the chemical process industry for the manufacture of a high quality product. Material selection is generally based on the required material properties, low initial capital investment, and minimum maintenance. Changes in the process parameters to improve products can often lead to higher corrosion susceptibilities of the plant materials. Moreover, with increase in capital cost, there is pressure to extend the life of existing plant equipment beyond its original design life. Corrosion and Materials Engineers are also playing a key role in selecting, maintaining, and modifying materials for changing needs for every industry. Corrosion Science and Engineering research includes understanding the basic mechanisms involved in material degradation in given environments and using that knowledge to develop a mitigation strategy against environment-induced failures

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.