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Dr. Sujit Bidhar graduated with his PhD in mechanical engineering from the University of Tokyo in 2012 specializing in fatigue, fracture mechanics, and finite element modelling in aluminium die cast. He is currently working at Fermilab where he is involved in new target material research and development, developing material models for future high energy beam target materials subjected to thermal shock, and nuclear irradiation damage to predict target lifetime. Dr. Bidhar has set up a lab-scale electrospinning unit and successfully fabricated different ceramic, metallic, and polymeric nanofibers; he is currently designing micromechanical experiments to evaluate single nanofiber mechanical properties using SEM, FIB, and AFM techniques. In the past, he has worked at the University of Tokyo as a researcher in the field of impact analysis on jet engine turbine blade made up of FRP composites, large scale finite element simulation on super computers using LS-DYNA. He has research interest and experience in computational mechanics, solid mechanics, structural analysis, fatigue and fracture, stress analysis, very large scale finite element simulations, image Based Finite Element Method using ANSYS,VOXELCON,LS-DYNA,ABAQUS, FrontISTR,HYPERMESH, MATLAB, Fatigue testing, X-ray CT. He also has experience in conducting experiments at high temperature and pressure environment, various metallurgical laboratory works, SEM micrographs, EDX, RAMAN spectroscopy, Slow strain rate tests.
Energy research represents a major focus for BNL over the next decade. We are using a multifaceted approach driven by the unique state-of-the art laboratory facilities and the inter-disciplinary expertise of our scientific staff to solve fundamental questions regarding U.S. energy independence and to translate discoveries into deployable technologies. The laboratory has identified several energy focus areas – including biofuels, complex materials, catalysis, and solar energy.
BNL's one-of-kind user facilities include the National Synchrotron Light Source II NSLS-II, which produces extremely bright beams of x-ray, ultraviolet, and infrared light for scientists exploring materials—including superconductors, catalysts, geological samples, and proteins—to accelerate advances in energy, environmental science, and medicine. Scientists at our Center for Functional Nanomaterials create materials and explore their unique structure and properties at the nanoscale, with a focus on more efficient solar and energy storage materials. And at BNL's Northeast Solar Energy Research Center, where researchers from labs, academia, and industry study test new solar technologies, working to make solar "power plants" more efficient and economical
In addition to fundamental research, the laboratory actively collaborates with industry and other academic institutions to bring the benefits of scientific discoveries to the marketplace. Brookhaven's Office of Strategic Partnerships integrates Brookhaven Lab's industry engagement, technology licensing, and economic development functions to expand the impact of collaborative research and technology commercialization. Strategic Partnerships supports the Laboratory's science mission through identifying, pursuing and managing partnerships with a broad set of private-sector companies, federal agencies, and non-federal entities. For information on licensing and industry.
- Basic science: seeks to understand how nature works. This research includes experimental and theoretical work in materials science, physics, chemistry, biology, high-energy physics, and mathematics and computer science, including high performance computing.
- Applied science and engineering helps to find practical solutions to society’s problems. These programs focus primarily on energy resources, environmental management and national security.
CMI Researcher Thomas Lograsso began serving as CMI interim director in November 2019. He had led the CMI Focus Area 2, Developing Substitutes since 2014. Previously he led Focus Area 4, Crosscutting Research while serving as the interim director of The Ames Laboratory. Also at Ames Lab, Tom leads a BES Synthesis & Processing effort on Novel Materials Preparation and Processing Methodology, whose goal is to develop synthesis protocols for new materials including quasicrystals, ferromagnetic shape memory alloys, and those that may contain volatile reactive or toxic components especially in single crystalline form. Often his pioneering synthesis efforts result in the first single crystals of these novel materials to be grown and studied for intrinsic behavior.
Tom is co-inventor of a rare-earth free substitute for the magnetostrictive alloy Terfenol-D (contains the critical elements Tb and Dy) used in high precision machining operations for small engine components and as a ultrasonic driver in petroleum exploration. This iron-based substitute is currently being evaluated for commercialization in energy harvesting applications.
Dr. Lograsso received his education in metallurgical engineering at Michigan Technological University, earning his Ph.D. in 1986. He did postdoctoral training working on the Rensselaer team, developing the Isothermal Dendritic Growth Experiment (IDGE) that flew on the Space Shuttle in the late 1990s. The IDGE tested the fundamental solidification physics of the pattern formation and kinetics of crystal growth in isothermal undercooled melts in growth regimes where gravity driven convection overwhelmed the growth in terrestrial conditions.
Matthew Kramer has been Division Director for Materials Sciences and Engineering (DMSE) since 2014. He is also an adjunct professor of Materials Science and Engineering at Iowa State University. As DMSE director, Kramer oversees budgets, proposal preparation, Materials Preparation Center administration, and Sensitive Instrument Facility oversight. DMSE includes 13 FWPs (BES funded), EFRC CATS, approximately 13 additional DOE funded projects, and a small number of Strategic Partnership Projects. Kramer joined Ames Laboratory in 1988, specializing in the areas Structure and properties of glass forming metallic alloys, aperiodic intermetallic alloys, permanent magnets and high temperature alloys, development of in situ time resolved methods using electron microscopy and high energy X-ray diffraction, analytical electron microscopy, and advanced imaging techniques for understanding rapid solidification. He holds B.S. and M.S degrees in geo mechanics and geology from the University of Rochester and a Ph.D. in geology from Iowa State University.
Lawrence Berkeley National Laboratory (Berkeley Lab), a U. S. Department of Energy Office of Science national lab managed by the University of California, delivers science solutions to the world – solutions derived from hundreds of patented and patent pending technologies plus scores of copyrighted software tools and published, peer-reviewed manuscripts.
Berkeley Lab has more than one hundred cutting-edge research projects using AI to find new scientific solutions to national problems. Through this effort, computer scientists, mathematicians, and domain scientists are collaborating to turn burgeoning datasets into scientific insights. Visit Berkeley Lab’s Machine Learning for Science site for more information.
Berkeley Lab’s advanced materials expertise is applied to innovation in batteries and other energy storage technologies, semiconductors, and photovoltaics. Additional energy-related areas of expertise include grid modernization and security, bio-based fuels and chemicals and building energy and demand response. Several National User Facilities are available for collaborative engagement: the Advanced Light Source, Molecular Foundry, National Energy Research Scientific Computing Center (NERSC), Energy Sciences Network, and the Joint Genome Institute. Other specialized facilities include FLEXLAB for building energy research and the Advanced Biofuels Process Demonstration Unit.
Ernest Orlando Lawrence, the lab's founder, believed team science yielded the greatest discoveries. That belief is reflected today in interdisciplinary teams and collaborative projects connecting Berkeley Lab, industry, and other research organizations. Berkeley Lab's Intellectual Property Office, connects industry partners with lab innovations and unique facilities to enable lab-to-market transition.
Fermilab is America's premier laboratory for particle physics and accelerator research. Since 1967, Fermilab has worked to expand humanity's understanding of matter, energy, space and time, studying the smallest building blocks of matter using some of the largest and most complex machines in the world.
The laboratory's 6,800-acre site is located in Batavia, Illinois, and its 1,700-plus employees include scientists and engineers from around the world. More than 4,000 scientists from over 50 countries also collaborate with Fermilab to build and operate world-leading accelerator, detector and computing facilities to investigate the physics of fundamental particles.
One of the world's pioneering laboratories for accelerator science and technology, Fermilab is home to the 83,000-square-foot Illinois Accelerator Research Center (IARC), where lab scientists and engineers partner with industry to translate technology developed in the pursuit of science into the next generation of industrial accelerators, products and applications. The center features an experimental area and provides state-of-the-art facilities for visiting scientists and entrepreneurs, including the Accelerator Applications Development and Demonstration (A2D2) machine, a test platform for electron-beam- and X-ray-based inspection and testing.
Fermilab's Office of Partnerships and Technology Transfer is a vital part of the laboratory, transitioning technologies to private-sector partners to enhance the nation's economic competitiveness. The office enables the formation of high-impact partnerships with industry, academia and other institutions that support the global and scientific missions of the lab.
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