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Main Authors: Wang, Zhihai, Yu, Hongwei, Wang, Jin
Format: Preprint
Published: 2022
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Online Access:https://arxiv.org/abs/2210.08775
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author Wang, Zhihai
Yu, Hongwei
Wang, Jin
author_facet Wang, Zhihai
Yu, Hongwei
Wang, Jin
contents We investigate a quantum battery system under both external driving and dissipation. The system consists of a coupled two-level charger and battery immersed in nonequilibrium fermionic reservoirs. By considering the changes in the energy spectrum induced by external driving and charger-battery coupling in a non-perturbative manner, we go beyond the secular approximation to derive the Redfield master equation. In the nonequilibrium scenario, both charging efficiency and power of the quantum battery can be optimized through a compensation mechanism. When the charger and battery are off-resonance, a significant chemical potential difference between the reservoirs, which characterizes the degree of nonequilibrium, plays a crucial role. Specifically, the charger's frequency should be higher (lower) than that of the battery when the average chemical potential is negative (positive) to achieve enhanced charging efficiency and power under strong nonequilibrium conditions. Remarkably, the efficiency in the nonequilibrium case can surpass that in the equilibrium setup. Moreover, we find no positive correlation between entanglement and efficiency, challenging the prevailing assumption that entanglement necessarily enhances the performance of quantum devices. Our results provide insights into the design and optimization of quantum batteries in nonequilibrium open systems.
format Preprint
id arxiv_https___arxiv_org_abs_2210_08775
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Driven-dissipative quantum battery with nonequilibrium reservoirs
Wang, Zhihai
Yu, Hongwei
Wang, Jin
Quantum Physics
We investigate a quantum battery system under both external driving and dissipation. The system consists of a coupled two-level charger and battery immersed in nonequilibrium fermionic reservoirs. By considering the changes in the energy spectrum induced by external driving and charger-battery coupling in a non-perturbative manner, we go beyond the secular approximation to derive the Redfield master equation. In the nonequilibrium scenario, both charging efficiency and power of the quantum battery can be optimized through a compensation mechanism. When the charger and battery are off-resonance, a significant chemical potential difference between the reservoirs, which characterizes the degree of nonequilibrium, plays a crucial role. Specifically, the charger's frequency should be higher (lower) than that of the battery when the average chemical potential is negative (positive) to achieve enhanced charging efficiency and power under strong nonequilibrium conditions. Remarkably, the efficiency in the nonequilibrium case can surpass that in the equilibrium setup. Moreover, we find no positive correlation between entanglement and efficiency, challenging the prevailing assumption that entanglement necessarily enhances the performance of quantum devices. Our results provide insights into the design and optimization of quantum batteries in nonequilibrium open systems.
title Driven-dissipative quantum battery with nonequilibrium reservoirs
topic Quantum Physics
url https://arxiv.org/abs/2210.08775