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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Source-target entanglement in quantum walks on arbitrary networks is upper-bounded by connectivity, with graph matchings controlling its generation and higher connectivity reducing the maximum in random graphs.
Non-reciprocal coupling of two Ising gauge theories yields linear asymptotic Wilson loop scaling with tunable confinement length, self-avoiding quasiparticle trails on critical percolation clusters, and non-reciprocity-tuned logarithmic noise contributions plus long-lived trapped states.
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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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Entanglement capacity of complex networks from quantum walks
Source-target entanglement in quantum walks on arbitrary networks is upper-bounded by connectivity, with graph matchings controlling its generation and higher connectivity reducing the maximum in random graphs.
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Non-reciprocal Ising gauge theory
Non-reciprocal coupling of two Ising gauge theories yields linear asymptotic Wilson loop scaling with tunable confinement length, self-avoiding quasiparticle trails on critical percolation clusters, and non-reciprocity-tuned logarithmic noise contributions plus long-lived trapped states.