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for critical applications that require qualification and certification—increasingly require that computational models and in-situ monitoring of such processes be experimentally validated under highly controlled
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are critical for attaining measurement quality objectives and meeting the needs of the health and medical community. The isotope metallomics program at NIST focuses on analytical method development, rapid
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for accelerated science. This research opportunity focuses on developing, evaluating, and applying computational methods for materials characterization and/or simulation that combine the best aspects of physics
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: algorithm design for the interpretation of measurements, designing algorithms for deciding which experiments to perform, communicating with the instruments, orchestrating the steps of the research campaign
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-film samples on waveguide interfaces and gas phase samples over temperature ranges from 1.7 K to 350 K. The experimental results are modeled using high-level quantum mechanical methods (DFT/MP2/MRCI
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is insensitive to variations in molecular architecture reducing its use for sorting chemically similar polymers such as high-density polyethylene, low-density polyethylene, linear low-density
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must be solved in order to fully exploit Johnson noise as a primary thermometer with high accuracy. Opportunities exist for experimental investigations in Johnson Noise Thermometry (JNT) with advanced
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performing high-resolution optical spectroscopy on self-assembled semiconductor quantum dots. Our technique employs narrow linewidth tunable lasers and heterodyne detection. Recent results from our group have
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, including linear optical quantum computing, quantum metrology (e.g., Heisenberg limited interferometry), and fundamental physics (loop-hole free Bell measurements). We are particularly interested in utilizing
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and calibration, radiation-hardness testing, personnel protection, radiation modification of materials, waste treatment, and high-energy computed tomography. These accelerator facilities afford