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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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also have familiarity with X-ray Diffraction and Pair Distribution Function anaylisis, experience with data acquisition using the Bluesky experiment orchestration package, and knowledge of beamline
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for data sharing in single, distributed, or mobile environments as well as learn the limitations and practical approaches of their applications. The program will also research testing and verification
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absorption fine structure), development of data-analysis approaches and computer software for simultaneous structural refinements using multiple types of data combined with ab initio theoretical modeling
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images. However, the current limitations of desktop computers in terms of memory, disk storage and computational power, and the lack of image processing algorithms for advanced parallel and distributed
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-quantum cryptography; quantum random number generation (QRNG) and quantum key distribution (QKD); position-based cryptography; and cryptography based on near-term quantum computing devices. Research will be
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@nist.gov 301.975.2105 Description Quantum communication, the distribution of entangled particles (usually photons), offers a fundamentally new physical resource for technological experimentation and
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and distributed control intelligence that can be applied to solve these problems through the application of machine learning, intelligent optimization techniques, automated fault detections and
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, scattering, etc. Concurrently, computational modeling will be used to predict both structure-property relationships and degradation rates based on the number and distribution of the monomers with
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renewable energy sources. Modern integrated building automation and control systems create an environment rich with sensor data and distributed control intelligence that can be applied to solve these problems