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Main Authors: Song, Wan-Lu, Wang, Ji-Ling, Zhou, Bin, Yang, Wan-Li, An, Jun-Hong
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.01679
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author Song, Wan-Lu
Wang, Ji-Ling
Zhou, Bin
Yang, Wan-Li
An, Jun-Hong
author_facet Song, Wan-Lu
Wang, Ji-Ling
Zhou, Bin
Yang, Wan-Li
An, Jun-Hong
contents As a quantum thermodynamic device that utilizes quantum systems for energy storage and delivery, the quantum battery (QB) is expected to offer revolutionary advantages in terms of increasing the charging power and the extractable work by using quantum resources. However, the ubiquitous decoherence in the microscopic world inevitably forces the QB to spontaneously lose its stored energy. This is called the self-discharging of the QB and severely limits its realization. We propose a QB scheme based on the nitrogen-vacancy center in diamond, where the electronic spin serves as the QB. Inspired by our finding that the coherent ergotropy decays more slowly than the incoherent ergotropy, we reveal a mechanism to enhance the inherent robustness of the QB to the self-discharging by improving the ratio of coherent ergotropy to total ergotropy. The unique hyperfine interaction between the electron and the native $^{14}$N nucleus in our scheme allows one to coherently optimize this ratio. Mitigating the self-discharging and optimizing the extractable work simultaneously, our results pave the way for the practical realization of the QB.
format Preprint
id arxiv_https___arxiv_org_abs_2504_01679
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Self-Discharging Mitigated Quantum Battery
Song, Wan-Lu
Wang, Ji-Ling
Zhou, Bin
Yang, Wan-Li
An, Jun-Hong
Quantum Physics
As a quantum thermodynamic device that utilizes quantum systems for energy storage and delivery, the quantum battery (QB) is expected to offer revolutionary advantages in terms of increasing the charging power and the extractable work by using quantum resources. However, the ubiquitous decoherence in the microscopic world inevitably forces the QB to spontaneously lose its stored energy. This is called the self-discharging of the QB and severely limits its realization. We propose a QB scheme based on the nitrogen-vacancy center in diamond, where the electronic spin serves as the QB. Inspired by our finding that the coherent ergotropy decays more slowly than the incoherent ergotropy, we reveal a mechanism to enhance the inherent robustness of the QB to the self-discharging by improving the ratio of coherent ergotropy to total ergotropy. The unique hyperfine interaction between the electron and the native $^{14}$N nucleus in our scheme allows one to coherently optimize this ratio. Mitigating the self-discharging and optimizing the extractable work simultaneously, our results pave the way for the practical realization of the QB.
title Self-Discharging Mitigated Quantum Battery
topic Quantum Physics
url https://arxiv.org/abs/2504.01679