He is a laboratory fellow and director of the Fuel Cycle Science and Technology Division at Idaho National Laboratory (INL). His primary focus is directing research and development of advanced technologies for spent nuclear fuel recycling and other chemical separation applications. He also serves as the national technical director for the U.S. Department of Energy (DOE) Nuclear Technology Research and Development Material Recovery and Waste Form Development Program and is also the director of the Glenn T. Seaborg Institute at INL. He has 35 years of experience in chemical separation technologies involving spent nuclear fuel and radioactive waste. He holds bachelor’s and master’s degrees in chemical engineering from Montana State University and a doctorate degree in chemical engineering from Khlopin Radium Institute in St. Petersburg, Russia. He has published over 200 journal articles, reports and conference proceedings, and awarded 23 U.S. patents and six Russian patents, as well as received numerous awards, including an R&D 100 Award. He serves on the editorial board for the journal, Solvent Extraction and Ion Exchange. He is a fellow of the American Institute of Chemical Engineers and the American Nuclear Society and the founder of an endowed chemical engineering scholarship at the University of Idaho. He has served on numerous international conference scientific advisory boards and technical program committees.
He is a research and development scientist at Idaho National Laboratory (INL) leading the Engineering Scale Nuclear Fuel Simulation team. His work focuses mainly on the development of INL’s nuclear fuel performance code, BISON, and on advanced modeling of fission gas behavior in nuclear fuel. He earned his master’s and doctorate degrees in nuclear engineering from Politecnico di Milano, Italy. He has 10 years of experience in nuclear fuel modeling and simulation. Prior to INL, he worked at the European Commission in Karlsruhe, Germany, and the Halden Reactor Project in Norway. His research encompasses various areas of nuclear fuel modeling, including fission gas release and swelling in oxide fuels, fuel rod performance during design-basis reactor accidents, and modeling of accident-tolerant fuel concepts, including uranium silicide fuel and iron-chromium-aluminum steel claddings.
He is a staff scientist at Idaho National Laboratory (INL) and a recognized expert in materials characterization and instrumentation. He has a doctorate in materials science and condenser matter physics from the University of California, Davis. His work has spanned global and nationwide collaborations. He has worked at premier nanocharacterization facilities at national laboratories and universities and has expert knowledge of scanning transmission electron microscopy, atom probe tomography and electron loss spectroscopy. His primary research interests lie in the investigation of materials and the origins of their physical properties. He has heavily leveraged the use of multidimensional microscopy, diffraction and artificial intelligence to address delays in data access and extraction, which has led to a new frontier in advanced microscopy. At INL, he continues to focus on the development and application of machine and deep learning in order to decipher and decimate information from images, spectra, and diffraction patterns to maximize the effectiveness, efficiency and utility of advanced microscopy. He is an invited academic faculty member and manager for a diverse group of postdoctoral research scientists, graduate students, and technicians across several national laboratories and universities. He is an author of 45 peer-reviewed publications, a recognized reviewer, and a technical contributing member to energy materials research. He was awarded two patents and has three patents pending, including an innovative approach to computational microscopy using machine learning.
After graduating from the University of Florida in 2004 with a Bachelor’s degree in chemistry, Dr. Aaron L. Washington, II completed his PhD in Inorganic Chemistry with specialization in material science. As of April 2009, Dr. Washington joined the Advanced Characterization and Processing (ACP) group at SRNL and is currently a principal scientist and former manager in the same group. He is currently involved with material development for multiple applications including radiological sensors, nuclear waste storage, additive manufacturing for nuclear material disposal, nuclear Deactivation & Decommissioning (D&D), organic based nuclear sensors, and nuclear waste treatment strategies. Additionally, he recently led a group with 3 post-doctoral researchers (3 former postdocs are now full time), 7 peer PhD scientists, a bachelor’s scientist, 3 managers, and 2-4 interns in interdisciplinary research and program development. Dr. Washington has more than 20+ peer reviewed manuscripts, 30+ technical reports, and more than 15 presentations at national conferences and meetings. Dr. Washington also has 4 patents issued and 7 additional patents currently in process. Dr. Washington was a 2014 recipient of the Laboratory Director’s Award for Early Career Exceptional Achievement and the 2016 Laboratory Director’s Award for Exceptional Achievement. Dr. Washington has also recently received his Project Management Professional (PMP) certification as of July 2017.
Dr. Washington currently serves on multiple committees both at SRNL and in the Aiken community. These include the Conduct of R&D safety council, Diversity Board of Directors for SRNS, and the former Board of Directors Chairman and current member for Habitat for Humanity. He is an also an Adjunct Professor at USC Aiken in the chemistry department.
He is a distinguished scientist for the Aqueous Separations and Radiochemistry Department at Idaho National Laboratory. He has expertise in nuclear fuel separations (aqueous and pyrochemical), high-level waste treatment, decontamination, nuclear processing off-gas treatment, and low-level waste treatment. His areas of decontamination expertise include chemical, strippable coatings and laser decontamination methods. In 1991, he began the study of decontamination of stainless steel nuclear fuel reprocessing equipment and waste minimization. In 2004, he began developing decontamination technologies to remediate radioactive contamination from a dirty bomb for the Defense Advanced Research Projects Agency. His expertise in decontamination and decommissioning (D&D) was recognized by the International Atomic Energy Agency (IAEA) with a consultancy on decommissioning spent fuel pools and as a teacher for the IAEA D&D courses. He holds seven patents and won an R&D 100 Award in 2011. He is a founding member of the National Analytical Management Program (NAMP) and continues to serve as the High Dose/Hot Cell Subcommittee chairman. He serves as a member of the Waste Management Symposia Program Advisory Committee for the last 12 years and annually as the session chairman for Novel Decontamination Techniques. He is also a member of the ASTM Subcommittee E10.03, Radiological Protection for Decontamination and Decommissioning of Nuclear Facilities and Components.
He has more than 10 years of experience in various capacities spanning nuclear and chemical engineering. His research expertise is in the design, modeling, simulation, and analysis of experiments in the Advanced Test Reactor (ATR) at Idaho National Laboratory; chemical processes including the manufacturing of high purity polysilicon and oil separation from brine water; and both test and space nuclear reactors. He is an adjunct professor at the University of Utah, where he collaborates on nano- to micron-thick film coating projects, which are done with a fluidized bed chemical vapor deposition (FB-CVD) reactor. He has also been a senior reactor operator of the TRIGA reactor at the University of Utah. His recent work includes the modeling and simulation of corrosion on the surfaces of various cladding materials to be tested at ATR, which is a coupling of nuclear activation, radiolysis of water, chemical systems simulation with the chemical kinetics, and thermodynamics from a selected set of corrosion, acid/base and electrochemical reactions.
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