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@nist.gov 917.913.7268 Description This research opportunity focuses on precisely controlled quantum systems of neutral atoms in microscale optical potentials, for applications in quantum simulation
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that couples naturally to free-space optics. We have optically cooled these devices to cryogenic temperatures and are planning to cool them further, into the quantum domain. We have used them in a
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NIST only participates in the February and August reviews. Grating-based magneto-optical traps (MOTs) have recently opened up a new path toward miniaturization of cold-atom technologies. In
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Metrology and Prototyping of Wide-Bandgap Semiconductor Quantum Nanowire Structures and Devices NIST only participates in the February and August reviews. Semiconductor quantum nanowires offer new
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; and developing new measurement techniques or devices to characterize sources, detectors, and optical components at few photon levels. key words Single photon; Superconductivity; Quantum information
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Description Exploiting atom-based solid-state technology and nanotechnology for quantum technologies such as quantum computing, quantum simulators, quantum nano-optics, and nanoscale sensing requires
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NIST only participates in the February and August reviews. Electro-optic frequency combs provide tremendous flexibility and agility while being applicable to a wide range of present problems in
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-free Bell measurements, and sources of quantum randomness. References Shainline J, et al, Optics Express 25 10322 (2017) Gentry, et al: Optica 2: 1065, 2015 Shalm, et al: Physical Review Letters 115
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@nist.gov 303.497.7948 Description We are currently performing high-resolution optical spectroscopy on self-assembled semiconductor quantum dots. Our technique employs narrow linewidth tunable lasers and
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optical quantum computing, quantum metrology (e.g., Heisenberg limited interferometry), and fundamental physics (loop-hole free Bell measurements). We are particularly interested in utilizing our high