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.
New Journal of Physics , abstract =
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The virtual-excitation protocol outperforms the trimer-model approximation for entanglement distribution in spin chains in speed, fidelity, and noise resilience.
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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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Spin Chains for Quantum Information Processing
The virtual-excitation protocol outperforms the trimer-model approximation for entanglement distribution in spin chains in speed, fidelity, and noise resilience.