Nate Damen is a Research Engineer I with Aerospace, Transportation and Advanced Systems Laboratory of Georgia Tech Research Institute. Damen’s work at ATAS has focused on Mixed Reality applications, robotics, the automation of CAR-T cellular expansions, and bioreactor design. Before joining GTRI, Damen conducted research into the manipulation of textiles with Softwear Automation and the design of deformable parcel manipulation systems with Dorabot. His creative work ATLTVHEAD with the Atlanta Beltline Inc., includes the creation of several wearable electronic systems for remote computing and novel interactions between wearable systems and live user input from those walking the Atlanta Beltline. 

Sabetta Matsumoto received her B.A., M.S. and Ph.D. from the University of Pennsylvania. She was a postdoctoral fellow at the Princeton Center for Theoretical Sciences and in the Applied Mathematics group and Harvard University. She is a professor in the School of Physics at the Georgia Institute of Technology. She uses differential geometry, knot theory, and geometric topology to understand the geometry of materials and their mechanical properties. She is passionate about using textiles, 3D printing, and virtual reality to teach geometry and topology to the public.

The Tong Lab tackles challenges in the interdisciplinary areas of bioresource engineering and sustainable chemistry. We develop innovative technologies for producing chemicals, materials, energy, and fuels from renewable resources.

Current research interests include:

• Functional biomaterials for high-efficiency circular economy
• Platform chemicals and hydrocarbon fuels from renewable resources
• Sustainable process control and modeling
• Nano-biomaterial synthesis and self-assembling
• Polymer degradation and recycling

Disciplines:

• Materials and Nanotechnology

• Energy and Sustainability

Scott Sinquefield completed his Ph.D. in Chemical Engineering in 1998 at Oregon State University. He spent three years working with the Multi-Fuel Combustion Group at the Combustion Research Facility at Sandia National Labs (Livermore); where he performed the experimental portion of his thesis research. He joined the Chemical Recovery group at IPST in 1998 and was lead.engineer in the construction and operation of the Pressurize Entrained Flow Reactor facility. He now leads the research program on black liquor gasification. He has extensive experience in the design and construction of pilot research reactors and control systems. He also has expertise in boiler fire-side fouling and thermodynamic modeling of aqueous electrolyte systems.

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

Carson Meredith is Professor and James Preston Harris Faculty Fellow in the School of Chemical & Biomolecular Engineering at Georgia Tech and serves as Executive Director of the Renewable Bioproducts Institute (RBI). 

His research focuses on sustainable materials and bioproducts, with particular emphasis on biomass-derived polymers such as cellulose and chitin nanomaterials. Representing the contributions of students and collaborators, this work addresses critical challenges in packaging, coatings, and recycling, and has been featured in Newsweek, NBC Nightly News, BBC, and NPR. Meredith’s research also includes innovations in polymer films, foams, composites and particle adhesion.

Meredith has published over 140 peer-reviewed articles and book chapters, with more than 7,600 citations. His recent research includes the development of recyclable nanocellulose coatings and water vapor-resistant films using renewable materials. He has received multiple patents and has led over $30 million in federal and industry funded research. 

Meredith has served in leadership roles across campus and nationally. At Georgia Tech, he has led RBI since 2020, one of eleven interdisciplinary research institutes, where he has built a community of over 70 faculty focused on circular materials, bio industrial manufacturing, and low-impact papermaking. He is also a member of advisory boards for the Bioproducts Institute (University of British Columbia) and the DOE Joint Bioenergy Institute (JBEI) and serves on the editorial board of Green Materials. 

He teaches courses in forest product technology and sustainable materials, and co-founded GT-EQUAL, the first American Chemistry Society Bridge Program in chemical engineering. He also led the development of a graduate certificate in Data Science for the Chemical Industry and created a MOOC on High-Throughput Development of Materials, which has reached over 14,000 learners. 

Meredith earned his Ph.D. in Chemical Engineering from the University of Texas at Austin and his B.Ch.E. from Georgia Tech. 

Research 

Meredith’s research centers on sustainable materials and bioproducts, with a focus on: 

• Cellulose and chitin nanomaterials 

• Renewable packaging and coatings         

• Polymer thin films and foams

• Particle adhesion 

• Energy efficient drying in natural fiber manufacturing

   

His work integrates environmental sustainability into materials design and manufacturing, and he collaborates across disciplines to advance scalable climate solutions. 

Awards and Distinctions 

• AIChE Andrew Chase Award (2024) 

• AIChE David Himmelblau Award (2024) 

• AIChE Fellow (2023) 

• Georgia Tech Outstanding Service Award (2023) 

• Georgia Tech Curriculum Innovation Award (2022) 

Selected Publications 

• Hickmann, T., Tao, L., Stingelin, N., Meredith, J.C. (2024). Low-water-permeability foils based on bio-renewable cellulose-derivatives. RSC Sustainability, 2, 3451–3455. 

• Ji, Y., Shen, D.E., Lu, Y., Schueneman, G.T., Shofner, M.L., Meredith, J.C. (2023). Aqueous-based recycling of cellulose nanocrystal / chitin nanowhisker barrier coatings. ACS Sustainable Chemistry and Engineering, 11, 10874–10883. 

• Shin, D., Choi, W.T., Lin, H., Qu, Z., Breedveld, V., Meredith, J.C. (2019). Humidity-Tolerant Capillary Viscous Adhesion of the Honey Bee Pollen Basket Fluid. Nature Communications, 10, 1379. 

• Satam, C., Irvin, C.W., Lang, A.W., Jallorina, J.C.R., Shofner, M.L., Reynolds, J.R., Meredith, J.C. (2018). Spray-Coated Multilayer Cellulose Nanocrystal—Chitin Nanofiber Films for Barrier Applications. ACS Sustainable Chemistry and Engineering, 6, 10637–10644. 

   

A full list of publications is available on Google Scholar. 

Dennis Hess’s research interests are in thin film science and technology, surface and interface modification and characterization, microelectronics processing and electronic materials. His group focuses on the establishment of fundamental structure-property relationships and their connection to chemical process sequences used in the fabrication of novel films, electronic materials, devices, and nanostructures. Control of the surface properties of materials such as dielectrics, semiconductors, metals, and paper or paper board by film deposition or surface modification allows the design of such surfaces for a variety of applications in microelectronics, packaging, sensors, microfluidics, and separation processes.