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various government laboratories to elucidate mechanisms of protein binding to BLMs. We comprise researchers with a broad range of expertise and are actively developing advanced biochemical and biophysical
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@nist.gov 301.975.4127 Description This research is centered on the development and application of analytical methods to the characterization of nanomaterials. Opportunities exist to study the composition
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are needed to support the clinical testing community and manufacturers of working standard materials. Challenges lie in developing relevant standards in a timely fashion to support new clinical targets and
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components. To develop this program in oxide electronics, a successful applicant will have a solid background in programming (Matlab, Python, or equivalent). Experience with any of the following lock
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microfluidic networks.Our goal is to develop systems that enable accurate, high-throughput, and dynamic measurement of materials in flow, which will, for example, improve the ability to specify composition and
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of materials under operational conditions improves fundamental understanding and accelerates development of highly-reliable materials and devices. Applicants will work to develop relevant test approaches
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, but face technical challenges to achieve their potential for high efficiency. Third generation devices are now being developed that exploit nanoscale three-dimensional (3D) structures to achieve higher
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determination of marijuana components, development of vapor measurement technology and canine training aid materials for opioids and improvised explosives, targeted and non-targeted screening of bulk samples and
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Development of magnetism-based future electronics is fueled by demand for large memory capacity and high data processing rates. New technologies such as hard drives with bit-patterned media and magnetic memory
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prevent a true function-by-design approach to development and manufacturing. We are interested in using analytical theory, large-scale molecular dynamics (MD) simulations, and density functional theory (DFT