348 algorithm-development-"Prof"-"Washington-University-in-St"-"Prof"-"Prof" positions at NIST
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augmented intelligent solutions that monitor, diagnose, and predict process performances to optimize production quality and yield. Proposals are welcome to develop augmented intelligent solutions
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to understand dynamic changes within microbiomes or to design interventions (e.g., modeling algal blooms, improving human health or crop yields, bioremediation). This project seeks is to develop measurement
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of the AFM probe-sample interaction. This research opportunity will focus on developing state of the art AFM instrumentation and computation modeling for 3D nanoscale property characterizations. In either
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describe and improve instrument behavior in physically relevant limits. Abundant examples are found in physics, chemistry, and biology. We are interested developing new mathematical models to simulate
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on developing predictive tools for ceramic AM by combining computational and experimental approaches to study fundamental material processes during direct-ink writing and post-processing of ceramic parts. We
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device based upon the use of nanodiamonds. It is, therefore, of paramount importance to develop modeling and measurement techniques of the lattice distortion/strain field due to a color center in
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than the actual biological changes being probed in metabolomics investigations, which is a roadblock to commercial translation of findings. Research in this area will focus on the development and
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the researcher a unique opportunity to develop and test novel dosimetry systems for quantification of patient dose in radiotherapy, or dose delivered to products in industrial electron beam processing
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, such as blood vessels and bone, we also need to develop a platform for in situ mechanical measurements, which may be achieved by measuring deformation under controlled stress and flow. 3D printing is
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viability in scaffolds as a quality attribute of a tissue engineered medical product. We will develop new methods for assessing cell viability in scaffolds that have advantages such as being label-free, non