Dr. Chris Haase joins as Director of the Critical Materials Institute from GE Ventures, where he was Senior Director, leading new business creation and investment activities in the areas of oil & gas, power and renewables. With background in defense and natural resources, Chris has served as early-stage technology manager and investor in several corporate venture capital organizations, including Shell Technology Ventures Fund 1, BTG Ventures, Shell GameChanger and GE Ventures. In upstream energy, Chris served as the head business advisor to the Chief Technology Officer of Royal Dutch / Shell, managing alignment of R&D funding with the company’s long-term corporate strategy and value chains and also launching Shell’s latest venture fund, Shell Ventures. Additionally, Chris was Shell’s manager for external research, where he helped Shell close many innovative partnership agreements with universities and small enterprises in North America. With a background in numerical modeling, petrophysics and quantitative seismic interpretation, Chris has worked on oil & gas exploration and development projects, new upstream joint ventures and divestments involving assets in the Gulf of Mexico, South Atlantic, North Sea, Middle East and Australia.
A former US Department of Defense Fellow and adjunct professor at the United States Naval Academy, Chris held R&D positions with the Naval Ocean Systems Center (now SPAWAR) and Department of Defense and also served as a 10-year volunteer commercialization advisor for the National Technology Transfer Center and US Missile Defense Agency. An inventor with several patents, Chris received his Ph.D. and MS degrees in mathematics from the University of Chicago, his MBA from Erasmus University in Rotterdam and his Bachelor of Science degree, Summa Cum Laude, from Ohio State University. Chris is married to Ineke and has two sons, Mark and Peter, both studying mechanical engineering in university.
She is an environmental geochemist with research interests focusing on how chemical reactions can increase the efficiency of producing energy while minimizing environmental impacts, and how to monitor the sources of fluids and gases in natural systems. Her specialties include natural gas, carbon capture and storage, and carbon dioxide storage. She earned her bachelor’s in geosciences with a certificate in environmental studies from Princeton University in 2003, and her doctorate in the School of Earth Sciences at Ohio State University in 2008 where she was a U.S. Environmental Protection Agency’s Science to Achieve Results graduate fellow. She started as an Oak Ridge Institute for Science and Education (ORISE) post-doctoral research associate at the National Energy Technology Laboratory (NETL) in 2008 and became a NETL research physical scientist in the Office of Research and Development in 2009. While at NETL, she has led multiple projects related to onshore unconventional shale gas development. She received the 2017 Presidential Early Career Award for Scientists and Engineers and the 2016 Federal Executive Board Women in Science Bronze Award. She’s also contributed her expertise to a variety of publications and manuscripts with numerous upcoming presentations and authorships.
He is responsible for the development of science-based simulations for use in accelerating energy technology development. He was architect of the widely used, open-source multiphase CFD code, known as Multiphase Flow with Interphase eXchanges (MFIX), and led the development of software for linking process- and device-scale simulations and the C3M chemical kinetics software. As a fellow of the American Academy of Chemical Engineers, he specializes in multiphase flow, computational fluid dynamics (CFD), fluidization, and various energy processes. He is a founding technical director of National Energy Technology Laboratory’s Carbon Capture Simulation Initiative (CCSI). He has received numerous awards, such as the Energy Secretary’s Achievement Honor Award and American Institute of Chemical Engineers (AIChE) Fluidization Process Recognition Award. His many publications address topics, such as gasifier advanced simulation models; multiphase hydrodynamics of gas-solids flow; modeling coal gasification processes; hydrodynamics of particle segregation in fluidized beds; and simulation of granular layer inversion in liquid fluidized beds. He has a bachelor’s in chemical engineering from the Indian Institute of Technology (BHU) Varanasi, and a master’s and doctorate from the Illinois Institute of Technology in Chicago.
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 the technology manager of National Energy Technology Laboratory’s (NETL) Natural Gas and Oil Research and Development (R&D) program. In this capacity, he manages an R&D portfolio encompassing advanced technology projects ranging from basic energy science (modeling, materials development, sensors, controls) through large-scale field demonstrations and includes natural gas (shale gas), enhanced oil recovery, deepwater oil and gas production, and methane hydrates. He has 17 years of diversified engineering and management experience that spans a broad spectrum of technology areas including electric power generation, advanced greenhouse gas control, process control, coal conversion processes (oxycombustion, gasification and chemical looping), thermoelectric water management, and simulation/systems analysis.
Previously at NETL, he served as director of the Office of Coal and Power R&D Program and technology manager of the Carbon Capture Program and Engineering Systems Analyst. Prior to joining NETL, he worked as a chemical engineer for Science Applications International Corporation (SAIC) and as a research/process engineer for Calgon Carbon Corporation. He has a bachelor’s and master’s in chemical engineering from the University of Pittsburgh.
He is a human factors engineer in the Human Factors, Controls, and Statistics Department with 37 years of experience in various human factors engineering roles in heavy industry, defense, nuclear, and commercial organizations. His primary focus is on making work more effective, efficient, and satisfying through the design of human-centered tools, methods, and work environments. He has worked at Idaho National Laboratory since 2010. His current work includes researching and developing methods and procedures to integrate human factors principles in the systems engineering process for advanced and modernized nuclear power stations with an emphasis on human-system interfaces and control room design and information visualization. He has a master’s degree in human computer interaction from the University of South Africa and associate degrees in human computer interaction and industrial engineering.
Starting at Sandia National Laboratories in August 2001, he is currently a principal member of the technical staff in Sandia’s Geochemistry organization. His primary role is project manager and overall technical lead on the Crude Oil Characterization Research Study, a 3-year, $10-million project investigating how crude oil properties affect potential combustion hazards during transportation and handling. In that role, he has extensive contact with a broad set of internal Sandia personnel and support organizations, as well as extensive external contact with federal sponsoring agencies in the United States and Canada and industry representatives in midstream oil and gas and associated service companies.
Prior to taking project manager responsibility on the crude oil research work in 2016, he served as a technical lead on the Sandia contract for geotechnical support of the U.S. Strategic Petroleum Reserve (SPR) in 2004 and focused on understanding and improving methods for sampling, measuring, and modeling crude oil properties and phase behavior in storage and handling applications. He led the technical scope development and aligned customer needs with Sandia capabilities for the $3-million annual project from 2010-2016. He was also principal investigator on numerous analyses and technical reports within the SPR scope during that period.
His first assignment at Sandia from 2001-2004 was as a principal investigator for developing and qualifying a wellbore stability model, which was a component of a larger performance assessment model of the Waste Isolation Pilot Plant (WIPP).
His research focuses on ferroic functional materials and their applications in clean energy and energy efficiency applications. Current research directions include caloric materials, such as elastocaloric materials for heating, ventilation, and air conditioning, refrigeration; application and magnetocaloric materials for gas liquefaction; advanced soft magnetic materials, such as high silicon electrical steel for inductors, transformers, and motors; permanent magnetic materials, such as Mn-based, rare-earth-free permanent magnetic materials and rare-earth permanent magnets with high toughness; high temperature anti-ferroelectric capacitor materials; and ferroelastic shape memory alloys. The overall materials development strategy is theory guided high throughput experimentation, utilizing DFT-based computation to identify alloy composition space and combinatorial bulk synthesis and scanning materials characterization techniques to discover, and down-select candidate compositions. He holds joint positions with Ames Laboratory and the Materials Science and Engineering Department at Iowa State University.
He is the associate director for Materials Engineering and Manufacturing for the National Energy Technology’s (NETL) Research and Innovation Center (R&IC). He is responsible for NETL’s applied materials science capability, which is engaged in developing functional and structural materials to enable efficient and effective fossil based advanced power generation and resource recovery. He has a bachelor’s from Drexel University and doctorate from Rensselaer Polytechnic Institute, both in materials engineering. His research has encompassed the abrasive wear of sintered titanium matrix–ceramic particle reinforced composites; the effect of manganese additions on the reactive evaporation of chromium in nickel–chromium alloys; and the electrochemical corrosion measurements of carbon steel in supercritical carbon dioxide. He is co-inventor of nine U.S. patents, published over 50 peer-reviewed scholarly articles, and a recipient of two prestigious R&D 100 Awards for technology commercialization. In 2009, his technical contributions were recognized by ASM-International, as he was awarded a society fellowship for the development of novel materials and surface structures for power generation and high temperature applications.
She focuses her research on areas of computer-based procedures and automated work packages, control room modernization, and human-automation collaboration, and also leads research on digital architectures and data analytics at Idaho National Laboratory (INL). This research helps leverage advanced technologies, increase overall efficiency, and improve human performance by informing the design of the interaction between the worker and the system. In 2016, she led the industry-wide Nuclear Electronic Work Packages – Enterprise Requirements (NEWPER) initiative where domestic and international nuclear utilities, research organizations, and vendors came together to define functional requirements for anything from smart PDFs to computer-based procedures. Before joining INL, she worked at Ringhals Nuclear Power Plant in Sweden leading the Human Factors Engineering research and development and human reliability analysis activities. She has 10 years of research and practical experience with human reliability analysis.
He has served science and society as a prominent researcher, professor, senior manager in the US Federal and CA State governments, CEO of a systems engineering and naval architecture firm, and currently a member of the Lawrence Livermore National Laboratory. Steve is the E-Program Manager in the Global Security Directorate. E-Program’s mission is to develop advanced energy technologies and manufacturing techniques and to advance the resilience of the nation’s energy system to physical and cyber attack.
A graduate of the Dartmouth College, he earned a Ph.D. in geochemistry from The University of Michigan in 1979. Following a postdoctoral fellowship at UCLA, he became a tenured professor at Stony Brook University. From1995 through 2000, he was Associate Chief Geologist for Science at the US Geological Survey. He was responsible for the scientific priorities and funding of the broad portfolio of USGS research, including the National Earthquake Hazards Reduction, Climate Change, Global Energy, and Minerals Resource programs. As President and CEO of Joint Oceanographic Institutions from 2000-2008, he led the global effort in scientific ocean drilling and the Integrated Ocean Drilling Program and the systems engineering and deployment of the US National Science Foundation’s Ocean Observatories. In May 2014, he was appointed by Governor Brown to lead the CA Division of Oil, Gas and Geothermal Resources. He rebuilt the Division and developed and implemented the nation’s most comprehensive and environmentally focused regulations on well stimulation and hydraulic fracturing.
With a deep understanding of how the Earth works, he writes and speaks about future challenges and risk assessment of energy, climate, water, and food on a small planet. His 25 years of research on the evolution and stabilization of continental crust is widely cited, and he is among a select group in ISI’s Web of Science of Highly Cited Researchers in the field of Geoscience (atmosphere, ocean, and solid Earth).
He has more than 10 years of industrial and research experience in automation, instrumentation, and control. He holds a doctorate in nuclear engineering from Texas A&M University, a master’s degree in information technology and automation systems from Esslingen University of Applied Science in Germany, and a bachelor’s degree in mechanical engineering from Jordan University of Science and Technology in Jordan. In 2015, he joined Idaho National Laboratory as a research and development scientist with special focus on nuclear automation, instrumentation, and control. Before earning his doctorate, he worked at Asea Brown Boveri for 6 years and was a lead distributed control systems engineer by 2010. While pursuing his degree, he researched various nuclear engineering topics at Texas A&M University and worked for a year at the International Atomic Energy Agency (IAEA). He also worked for Daimler Chrysler-Mercedes Group and Fraunhofer Institute for Production and Automation in Germany. He is a senior Institute of Electrical and Electronics Engineers (IEEE) member and author of several publications and technical reports. He is also a reviewer of nuclear energy and IEEE journals and U.S. Department of Energy grants.
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