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the rate of fire growth. State-of-the-art fire models designed for these simulations also require input parameters (material properties) that describe: the decomposition reaction mechanism of combustible
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such that their mechanical motion can be cooled to the quantum ground state without the need for cryogenics. One device geometry of interest combines photonic crystal reflectors with a mechanical resonator that is
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ions that are confined in electromagnetic traps and laser-cooled, in some cases to the ground state of motion. Experiments employ RF (Paul) traps and Penning traps. Precision spectroscopy experiments
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spectrum. A theoretical approach must include automatic discovery of reactions and their rates. Some tandem methods (CID, IRMPD) may be modeled as occurring on the ground electronic state. Electron
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, solids, membranes, or immobilized on surfaces). Possible projects could involve characterizing the physical processes of the destabilization mechanisms of antibodies, recombinant protein drugs, membrane
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form their gear and occuptational environments · complex, multi-scale solid state and aerosol testing and analysis · a wide range of flexibility - applied bench- and full-scale fire testing
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strains in the solid. Hence, a study of strain and its coupling with the electronic wave functions is extremely important for improving the reliability, integrity, performance, and lifetime of quantum