Tuning polariton splitting in a chaotic Tavis-Cummings model produces a low-coupling thermalizing regime driven by quantum chaos and a high-coupling non-thermalizing regime that suppresses ergodicity, with direct effects on cavity photon correlations.
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Entanglement asymmetry for space-inversion symmetry of free fermions on honeycomb lattices exhibits nonanalytic dependence on energy imbalance and persists after a quench to the symmetric point due to flat bands in certain geometries.
Key equilibrium distributions and entropies of statistical mechanics emerge from quantum envariance and exchange symmetry in system-environment entangled states.
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Thermalization Regimes in a Chaotic Tavis-Cummings Model
Tuning polariton splitting in a chaotic Tavis-Cummings model produces a low-coupling thermalizing regime driven by quantum chaos and a high-coupling non-thermalizing regime that suppresses ergodicity, with direct effects on cavity photon correlations.
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Dynamics of entanglement asymmetry for space-inversion symmetry of free fermions on honeycomb lattices
Entanglement asymmetry for space-inversion symmetry of free fermions on honeycomb lattices exhibits nonanalytic dependence on energy imbalance and persists after a quench to the symmetric point due to flat bands in certain geometries.
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Statistical mechanics from quantum envariance and exchange symmetry
Key equilibrium distributions and entropies of statistical mechanics emerge from quantum envariance and exchange symmetry in system-environment entangled states.