Dissipative dynamics activate finite ergotropy from thermal quantum spin chains, with collective effects creating temperature- and size-dependent steady-state passivity via dark subspaces, while dephasing suppresses extraction.
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A transmon quantum battery charged by coherent ancillas achieves improved control of stored energy and extraction in experimentally accessible parameter regimes.
A Lambda-type many-body quantum battery model shows collective charging and discharge suppression in the strong-coupling non-Markovian regime, with numerical simulations indicating that optimized driving and reservoir engineering enable rapid stable charging.
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Charging Quantum Batteries via Dissipative Quenches
Dissipative dynamics activate finite ergotropy from thermal quantum spin chains, with collective effects creating temperature- and size-dependent steady-state passivity via dark subspaces, while dephasing suppresses extraction.
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Collisional charging of a transmon quantum battery
A transmon quantum battery charged by coherent ancillas achieves improved control of stored energy and extraction in experimentally accessible parameter regimes.
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Rapid and Stable Collective Charging and Discharge Suppression in Strongly Coupled Many-Body Quantum Batteries
A Lambda-type many-body quantum battery model shows collective charging and discharge suppression in the strong-coupling non-Markovian regime, with numerical simulations indicating that optimized driving and reservoir engineering enable rapid stable charging.