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are developing object-oriented computational tools for the analysis of materials with complex microstructures. Starting from a digitized micrograph, the program identifies features in the image, assigns material
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characterization (ultrasound, x-ray scattering, IR imaging), and experimental equipment design (CAD, controls (i.e., LabView, Python, Arduino, G-code), image/video processing (i.e., ImageJ). [1] A
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state lighting and water purification), and field emitting ion sources for mass spectrometry. We are also working on the design and fabrication of prototype nanowire electronic devices such as FETs. We
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the measurement of infrared radiation for applications to remote sensing, fundamental metrology, process monitoring, homeland security, defense, and biomedical areas. Specific interests include (1) the development
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Description The National Institute of Standards and Technology (NIST) is developing next-generation microfabricated magnetic devices and magnetic resonance imaging (MRI) contrast agents and sensors based
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microscope (STEM) image. This is a fundamental transformation from the existing image acquisition paradigm and could enable new types of nano- and atomic-scale metrology. The Material Measurement Laboratory
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imaging and analysis methods, as well as collaborative efforts with other NIST laboratories for image processing and 3D visualization methods. key words Electron microscopy; Confocal microscopy
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of hormones in biological matrices. Hormones are essential for major developmental and reproductive processes. Because hormones are highly similar in structure and found at nanomolar concentrations
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the pattern through etching or deposition processes into the functional material of interest. NIL is a simple stamping technique amenable to patterning a wide range of materials. However, NIL often imposes
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of atomically precise patterning to deterministically place dopant atoms in a Si lattice to make prototype atom-based solid state devices and qubits, measurement of the properties of individual atomically precise