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Main Authors: Chen, Wenjing, Han, Si-Wei, Feng, Xiaoshan, Feng, Jun
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.02614
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author Chen, Wenjing
Han, Si-Wei
Feng, Xiaoshan
Feng, Jun
author_facet Chen, Wenjing
Han, Si-Wei
Feng, Xiaoshan
Feng, Jun
contents We analyze work extraction protocols using the long-lived quantum coherence of a three-level quantum system, which is coupled to a thermal bath through dipole-monopole interactions. We identify situations where persistent quantum coherence arises, i.e., for systems with degenerate excited states with aligned transition dipoles or nearly degenerate systems with small energy splittings. By designing two innovative thermodynamic protocols involving energy-preserving unitary operations, we show that quantum coherence can be transformed into population asymmetry, serving as a quantum resource for work extraction. As the system approaches final thermal equilibrium, the initial quantum coherence effectively acts as fuel, being progressively consumed. Specifically, we propose an optimized protocol capable of extracting the maximal extractable work (MEW), measured by the free energy difference (FED), from quantum coherence in a single-shot thermodynamic cycle. Our results highlight the thermodynamic advantages of long-lived coherence in a three-level quantum system and could influence future designs of coherence-driven quantum thermal machines.
format Preprint
id arxiv_https___arxiv_org_abs_2508_02614
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Work extraction from long-lived quantum coherence of a three-level system
Chen, Wenjing
Han, Si-Wei
Feng, Xiaoshan
Feng, Jun
Quantum Physics
We analyze work extraction protocols using the long-lived quantum coherence of a three-level quantum system, which is coupled to a thermal bath through dipole-monopole interactions. We identify situations where persistent quantum coherence arises, i.e., for systems with degenerate excited states with aligned transition dipoles or nearly degenerate systems with small energy splittings. By designing two innovative thermodynamic protocols involving energy-preserving unitary operations, we show that quantum coherence can be transformed into population asymmetry, serving as a quantum resource for work extraction. As the system approaches final thermal equilibrium, the initial quantum coherence effectively acts as fuel, being progressively consumed. Specifically, we propose an optimized protocol capable of extracting the maximal extractable work (MEW), measured by the free energy difference (FED), from quantum coherence in a single-shot thermodynamic cycle. Our results highlight the thermodynamic advantages of long-lived coherence in a three-level quantum system and could influence future designs of coherence-driven quantum thermal machines.
title Work extraction from long-lived quantum coherence of a three-level system
topic Quantum Physics
url https://arxiv.org/abs/2508.02614