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Field
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can generate ultra-relativistic electron beams over centimeter-scale distances thanks to extreme accelerating fields. A key limitation for beam energy is the dephasing between accelerated electrons and
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and or pushing the performance frontier toward 30 keV. However, the FEL output critically depends on the quality of the electron bunches. Producing low-emittance beams through advanced spatial and
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beam line to deliver short-duration laser pulses (spanning fs, ps and ns timescales) to a reactor containing a target solution in order to generate an intense discharge directly within the liquid phase
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following areas: Transition-edge sensors (TESs) or kinetic inductance detectors (KIDs) Cleanroom microfabrication processes, including: Thin-film deposition (e.g., magnetron sputtering) Electron-beam
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performed using a data superposition approach to predict HEA material responses at high beam power conditions, and the results will be validated against new test data. The combined optimum testing matrix and
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University of North Carolina at Chapel Hill | Chapel Hill, North Carolina | United States | 2 days ago
of finding interdisciplinary solutions to real-world problems. Its newest endeavor, BeAM (Be A Maker), is a university-wide initiative that incorporates Making into research, education, and entrepreneurship
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University of North Carolina at Chapel Hill | Chapel Hill, North Carolina | United States | 2 days ago
of finding interdisciplinary solutions to real-world problems. Its newest endeavor, BeAM (Be A Maker), is a university-wide initiative that incorporates Making into research, education, and entrepreneurship
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of Schottky diodes and MOS capacitors on 4H-SiC substrates; • Controlled engineering of surface and interface defects using techniques such as focused ion beam (FIB), plasma nitridation, and plasma oxidation
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. Extension may be possible contingent upon future funding. Previous hands-on experience with semiconductor device fabrication is required. Experience working with high resolution e-beam lithography, optical
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management techniques. In terms of metasurface design and development, AVALON is targeting reconfigurable optical metasurfaces with beam-splitting and beam-steering functionalities that meet the needs