Stochastic resetting generates finite pairwise entanglement in periodically driven spin chains, with critical resetting rate r_c and optimal rate r_m showing non-monotonic dependence on drive frequency ω_D.
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In the random-field XXZ model, Wehrl-Rényi entropy growth for z-polarized product states shows non-monotonic dependence on initial entanglement, with the first regime set by local integrals of motion and the second by inter-site correlations.
Two schemes fuse n- and m-photon hyper-W states into (n+m-2)-photon versions and three states into (n+m+t-3)-photon versions, all hyperentangled in polarization and spatial modes with only one garbage output.
citing papers explorer
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Generating pairwise entanglement in periodically driven quantum spin chains with stochastic resetting
Stochastic resetting generates finite pairwise entanglement in periodically driven spin chains, with critical resetting rate r_c and optimal rate r_m showing non-monotonic dependence on drive frequency ω_D.
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Entanglement Growth from Structured Initial States in Many-Body Localized Systems
In the random-field XXZ model, Wehrl-Rényi entropy growth for z-polarized product states shows non-monotonic dependence on initial entanglement, with the first regime set by local integrals of motion and the second by inter-site correlations.
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Effective schemes for fusion of hyperentangled W states
Two schemes fuse n- and m-photon hyper-W states into (n+m-2)-photon versions and three states into (n+m+t-3)-photon versions, all hyperentangled in polarization and spatial modes with only one garbage output.