A thermal ensemble of 10^12 rubidium atoms functions as a room-temperature quantum battery with capacity enhanced by coherence and quantitatively linked to entropy measures via operational unitary protocols.
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Loss in an auxiliary cavity induces nonreciprocal excitation exchange in a three-cavity quantum battery, yielding significantly higher steady-state energy in the battery than the charger.
Defines isoergotropic states and ergotropy-preserving operations that redistribute coherent-incoherent or displacement-squeezing components in quantum batteries without changing total ergotropy.
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Thermal vapor quantum battery based on collective atomic spins
A thermal ensemble of 10^12 rubidium atoms functions as a room-temperature quantum battery with capacity enhanced by coherence and quantitatively linked to entropy measures via operational unitary protocols.
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Loss-induced nonreciprocal quantum battery
Loss in an auxiliary cavity induces nonreciprocal excitation exchange in a three-cavity quantum battery, yielding significantly higher steady-state energy in the battery than the charger.
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Charge-Preserving Operations in Quantum Batteries
Defines isoergotropic states and ergotropy-preserving operations that redistribute coherent-incoherent or displacement-squeezing components in quantum batteries without changing total ergotropy.