Floquet engineering of nonreciprocal light-induced dipolar interactions in tweezer arrays realizes beamsplitter, squeezing operations, negative-mass-like signatures, and tunable complex eigenfrequencies.
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EIT cooling with fluorescence imaging achieves 99.7% readout fidelity and 98.2% survival for 87Rb atom arrays in 2.3 G fields, validated up to 10 G.
A framework with operational criteria and a trapped-atom hardware proposal for achieving statistically significant quantum advantage in latency-constrained nonlocal games.
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Floquet engineering of nonreciprocal light-induced dipolar interactions
Floquet engineering of nonreciprocal light-induced dipolar interactions in tweezer arrays realizes beamsplitter, squeezing operations, negative-mass-like signatures, and tunable complex eigenfrequencies.
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Loading and Imaging Atom Arrays via Electromagnetically Induced Transparency
EIT cooling with fluorescence imaging achieves 99.7% readout fidelity and 98.2% survival for 87Rb atom arrays in 2.3 G fields, validated up to 10 G.
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Operational criteria for quantum advantage in latency-constrained nonlocal games
A framework with operational criteria and a trapped-atom hardware proposal for achieving statistically significant quantum advantage in latency-constrained nonlocal games.