A 3D-integrated silicon MOS double quantum dot device with high-impedance NbN resonator achieves cavity Q above 10,000, dispersive charge readout SNR of 100 in 300 ns, and spin-photon coupling gs/2π = 75 MHz.
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Nanogap patterning on NbTi thin-film resonators decreases TC by 1.5 K and raises dfres/dT to 62 MHz/K at 4.2 K, enhancing cryogenic thermometry sensitivity by 10x.
A review summarizing input-output methods, theoretical proposals, and experimental demonstrations of emitter-based single-photon switches in nanophotonic structures.
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3D integration of a hybrid quantum dot circuit-QED device for fast gate dispersive charge readout and coherent spin-photon coupling
A 3D-integrated silicon MOS double quantum dot device with high-impedance NbN resonator achieves cavity Q above 10,000, dispersive charge readout SNR of 100 in 300 ns, and spin-photon coupling gs/2π = 75 MHz.
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Surface nanostructuring of NbTi superconducting thin-film resonators for enhanced cryogenic thermometry
Nanogap patterning on NbTi thin-film resonators decreases TC by 1.5 K and raises dfres/dT to 62 MHz/K at 4.2 K, enhancing cryogenic thermometry sensitivity by 10x.
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Routing single photons with quantum emitters coupled to nanostructures
A review summarizing input-output methods, theoretical proposals, and experimental demonstrations of emitter-based single-photon switches in nanophotonic structures.