He received his bachelor’s degree in physics and his master’s and doctorate degrees in electrical engineering from the University of Washington. His main areas of research are distribution system analysis and power system operations. He is currently a principal research engineer at the Pacific Northwest National Laboratory working at the Battelle Seattle Research Center. He is an adjunct faculty member at Washington State University, an affiliate assistant professor at the University of Washington, and a licensed professional engineer in Washington. He is the past chair of the Distribution System Analysis Sub-Committee and the current secretary of the Analytics Methods for Power Systems Committee (AMPS); formerly known as the Power System Analysis, Computing, and Economics (PSACE) Committee.
Vladimir Koritarov is the Manager of the CEESA Power Systems group in Argonne National Laboratory’s Energy Systems division. The group provides analytical services on strategic energy and environmental issues to government agencies, international organizations, and private institutions around the world. He is also a Senior Fellow at the University of Chicago’s Energy Policy Institute at Chicago (EPIC). Koritarov has over 30 years of experience in the analysis and modeling of electric and energy systems in domestic and international applications. Currently, he serves as Argonne’s Program Manager for Water Power Program, which includes hydropower and marine and hydrokinetic technologies.
Most recently, Koritarov has been working on the development of new agent-based modeling approaches for the simulation of energy and electricity markets, and applying advanced simulation methods to study the role and possible evolution of non-conventional energy resources, such as renewable generation and energy storage.
He is a senior environmental engineer at the National Energy Technology Laboratory's Energy Systems Analysis Team. He leads life cycle analysis (LCA) research efforts on methane emissions from the natural gas value chain, alternative transportation fuels, and advanced power generation systems. He is the primary author of multiple natural gas and coal-related life cycle analyses published by U.S. Department of Energy. He also leads research on energy resource availability, integration of biomass and fossil energy resources, and strategic energy concepts for new programs. He has 20 years of experience in the field of energy analysis and is a graduate of Pennsylvania State University.
He is a principal mechanical engineer and manager of Fuels, Engine, and Aftertreatment Research at Argonne National Laboratory’s Center for Transportation Research. In this role, he and his team plan, analyze, and execute powertrain and combustion research projects in light-duty, heavy-duty, and non-road applications, including marine and UAV, and employing a range of fuels, including gasoline, diesel, hydrogen and natural gas, and alcohols. Much of the work involves close collaboration with major manufacturers in these market segments.
He received a doctorate in computer science at the University of Tennessee in 2009, master’s in computer systems and software design, and his bachelor’s with a double major in computer science and mathematics with physics from Jacksonville State University. His research spans government-scale database and management systems, graphical user interface design, medical software used for surgery, gesture recognition, graph-theoretic analysis, optimization, automation, systems genetic research, magnetic resonance imaging, image processing, artificial intelligence, supercomputing, and energy-efficient buildings. He currently serves at Oak Ridge National Laboratory’s Building Technologies Research & Integration Center (BTRIC) as a subprogram manager for software tools and models with oversight of projects, involving websites, web services, databases, simulation engine development, visual analytics, supercomputing, and artificial intelligence. He has lead creation of the world’s most accurate method for calibrating a simulation model to measured data, fastest building model creator, fastest buildings simulator, and largest archive of simulated building data. He is a joint faculty member at the University of Tennessee’s Electrical Engineering and Computer Science Department, and an active member of American Society of Heating, Refrigerating and Air-Conditioning Engineers and Institute of Electrical and Electronics Engineers.
His research focuses on experimental and analytical studies to improve the energy performance of building envelopes, equipment, and systems. Some of his recent work at Oak Ridge National Laboratory includes energy efficiency enhancement of Army huts, thermal performance evaluation of various radiant barrier systems, lifetime energy and environmental impact of building insulation materials, identify and evaluate performance of lower-global warming potential alternative refrigerants for various applications and operating conditions, study suitability of procedures for evaluating performance of appliances and heating, ventilation, and air conditioning systems, and performance evaluation of thermochromic and electrochromic paints for buildings applications. He is also developing web-based energy-savings calculation to estimate energy and cost savings potential from improving building envelope airtightness. He earned a master’s and doctorate in mechanical engineering from Iowa State University. He is an American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE) certified Building Energy Modeling Professional (BEMP) and member of ASHRAE, American Society of Mechanical Engineers (ASME), and Tau Beta Pi.
He is a staff research scientist working in the Nuclear System Design and Analysis Division at Idaho National Laboratory (INL). He has expertise in heat transfer, fluid mechanics, thermal design, thermodynamics and nuclear safety analyses. Over the last few years, he has been researching high temperature heat exchanger design and optimization, system integration and power conversion systems, and safety and reliability for Advanced Reactor Concepts, and also has extensive experience in the design and construction of large-scale experimental systems for nuclear and thermal-hydraulic research. He has more than 12 years of research and development experience in nuclear/thermal engineering and has been involved in several academic, industrial, and cross-discipline national laboratory research projects. He is currently working to develop a new multi-loop, multi-fluid advanced test facility designed to examine thermal hydraulic and materials issues associated with advanced nuclear reactor technologies. He has authored two books; contributed chapters to technical books on advanced reactors, thermal systems and process heat transfer; published over 100 peer-reviewed publications; and served as the INL lead for numerous partnerships. He holds an adjunct faculty appointment in the Department of Mechanical, Aerospace, and Nuclear Engineering at Rensselaer Polytechnic Institute. He obtained his bachelor’s in mechanical engineering with concentration in robotics and controls from Wilkes University in Pennsylvania, a master’s degree in nuclear engineering with a minor in mechanical engineering from Oregon State University, a master’s degree in engineering management from University of Idaho, and doctorate in nuclear engineering from University of Idaho.
Her expertise includes photovoltaic (PV) system performance evaluation and module reliability analysis risk analysis, photovoltaic performance and degradation, energy efficiency, technical supervision of the installation of utility-scale PV research plants, and supervision of the activities for a new PV module testing laboratory. She has developed a probabilistic risk analysis study to assess technical, occupational, and environmental risks for the manufacturing process of crystalline silicon PV cells. Her current research focuses on understanding the mechanisms of failures of PV modules with the support of the X-ray material analysis capabilities offered by the National Synchrotron Light Source. Her expertise in PV started in 2003 working with the Joint Research Centre of the European Commission in close contact with technical analysis and the normative context of PV module qualification. She has a master’s degree in electric engineering from the Polytechnic University of Milan, Italy, and doctorate in energy risk and safety from Delft University of Technology in the Netherlands.
With 23 years of experience in engineering design, safety, and analysis of nuclear and energy systems, he has served as a principal member of the technical staff at Sandia National Laboratories since 1995, as well as a research associate professor at the University of New Mexico since 2012. His key areas of expertise include computational fluid dynamics, turbulence, dimpling, swirl, advanced manufacturing, and heat transfer. He is experienced with gas, water, molten salt, and heavy-water cooled reactors, including large, small, and miniature reactors. His primary technical achievements include right-sized dimpling, the LIKE algorithm, design of advanced fire sprinklers, isotropic turbulence decay model, development of five new vortices, a vortex unification theory, dynamic swirl modeling, and central recirculation zone modulation. He earned a doctorate in nuclear engineering from the University of New Mexico, as well as a doctorate in philosophy and apologetics from Trinity Seminary and College. He earned two master’s degrees in applied mathematics from the University of New Mexico and mechanical engineering from the University of Idaho, and a bachelor’s in nuclear engineering from the University of California - Santa Barbara. He is currently writing an engineering book for the Springer Publishing Company entitled, “Applied Computational Fluid Dynamics and Turbulence Modeling.”
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