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.
Secure quantum key distribution , Volume =
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New combinatorial proofs and circuit designs for quantum error correction reduce physical qubit overhead by up to 10x and time overhead by 2-6x for codes including Steane, Golay, and surface codes.
A review surveying coupling mechanisms in superconducting qubit-mechanical resonator hybrids and their extension to optomechanical architectures for quantum sensing applications.
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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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Lower overhead fault-tolerant building blocks for noisy quantum computers
New combinatorial proofs and circuit designs for quantum error correction reduce physical qubit overhead by up to 10x and time overhead by 2-6x for codes including Steane, Golay, and surface codes.
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Fundamentals and Applications of Hybrid Electro- and Opto-mechanical system coupled to Superconducting Qubit: A Short Review
A review surveying coupling mechanisms in superconducting qubit-mechanical resonator hybrids and their extension to optomechanical architectures for quantum sensing applications.