A TFLN photonic chip achieves gigahertz-rate active manipulation of time-bin quantum states, enabling loophole-free entanglement certification and continuous QKD operation at 25 kbit/s.
Korzh , author Q
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Transmission line models produce analytical absorptance formulas for SSPDs with single-side, double-side, and multilayer cavities, while impedance matching explains the condition for peak absorption.
New SNSPD architecture with tapers and SNAPs improves readout SNR in the mid-infrared while preserving high internal detection efficiency at 7.4 and 10.6 μm.
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Gigahertz-rate thin-film lithium niobate receiver for time-bin quantum communication
A TFLN photonic chip achieves gigahertz-rate active manipulation of time-bin quantum states, enabling loophole-free entanglement certification and continuous QKD operation at 25 kbit/s.
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Elucidating mechanism of optical cavities in superconducting strip single photon detectors using transmission line and impedance models
Transmission line models produce analytical absorptance formulas for SSPDs with single-side, double-side, and multilayer cavities, while impedance matching explains the condition for peak absorption.
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Improvements of readout signal integrity in mid-infrared superconducting nanowire single photon detectors
New SNSPD architecture with tapers and SNAPs improves readout SNR in the mid-infrared while preserving high internal detection efficiency at 7.4 and 10.6 μm.