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Main Authors: Hadipour, Maryam, Yousefi, Negar Nikdel, Mortezapour, Ali, Miavaghi, Amir Sharifi, Haseli, Soroush
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2501.17526
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author Hadipour, Maryam
Yousefi, Negar Nikdel
Mortezapour, Ali
Miavaghi, Amir Sharifi
Haseli, Soroush
author_facet Hadipour, Maryam
Yousefi, Negar Nikdel
Mortezapour, Ali
Miavaghi, Amir Sharifi
Haseli, Soroush
contents We investigate the charging dynamics of a frequency-modulated quantum battery (QB) placed within a dissipative cavity environment. Our study focuses on the interaction of such a battery under both weak and strong coupling regimes, employing a model in which the quantum battery and charger are represented as frequency-modulated qubits indirectly coupled through a zero-temperature environment. It is demonstrated that both the modulation frequency and amplitude are crucial for optimizing the charging process and the ergotropy of the quantum battery. Specifically, high-amplitude, low-frequency modulation significantly enhances charging performance and work extraction in the strong coupling regime. As an intriguing result, it is deduced that modulation at very low frequencies leads to the emergence of energy storage and work extraction in the weak coupling regime. Such a result can never be achieved without modulation in the weak coupling regime. These results highlight the importance of adjusting modulation parameters to optimize the performance of quantum batteries for real-world applications in quantum technologies.
format Preprint
id arxiv_https___arxiv_org_abs_2501_17526
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Amplified quantum battery via dynamical modulation
Hadipour, Maryam
Yousefi, Negar Nikdel
Mortezapour, Ali
Miavaghi, Amir Sharifi
Haseli, Soroush
Quantum Physics
We investigate the charging dynamics of a frequency-modulated quantum battery (QB) placed within a dissipative cavity environment. Our study focuses on the interaction of such a battery under both weak and strong coupling regimes, employing a model in which the quantum battery and charger are represented as frequency-modulated qubits indirectly coupled through a zero-temperature environment. It is demonstrated that both the modulation frequency and amplitude are crucial for optimizing the charging process and the ergotropy of the quantum battery. Specifically, high-amplitude, low-frequency modulation significantly enhances charging performance and work extraction in the strong coupling regime. As an intriguing result, it is deduced that modulation at very low frequencies leads to the emergence of energy storage and work extraction in the weak coupling regime. Such a result can never be achieved without modulation in the weak coupling regime. These results highlight the importance of adjusting modulation parameters to optimize the performance of quantum batteries for real-world applications in quantum technologies.
title Amplified quantum battery via dynamical modulation
topic Quantum Physics
url https://arxiv.org/abs/2501.17526