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Abstract
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With the advancement of quantum technology, there is a growing interest in schemes that utilize quantum effects to enable superior performance of future technological devices [1-4]. Recently, it has shown great success in several practical fields, such as quantum computing, quantum cryptography, and thermodynamic nanoscale device, which are expected to completely solve data analysis in the communication process, optimize sensitive parameters to improve network security, and provide more accurate temperature measurement [5-9]. Overall, the development of quantum technology promises to offer more miniaturized and more precise devices. The devices with potential quantum information processing have also been developed, but strategies for storing and releasing energy in these devices remain a major problem to be addressed [10-12]. Despite the advancements in quantum battery technology, there remains a critical need to optimize energy storage and charging processes in quantum devices. The existing literature has primarily focused on conventional coupling mechanisms in models like the Dicke model, often overlooking the potential benefits of long-distance dipole-dipole interactions among atoms. This lack of exploration raises an important question: Can the charging process of quantum batteries be accelerated by considering long-distance interactions between atoms, and how do these interactions influence the overall performance of the quantum battery system? Addressing this question is essential for advancing the efficiency of quantum batteries and enhancing the viability of quantum technology in practical applications. This study seeks to investigate these interactions and their implications for energy storage and charging dynamics in quantum batteries, ultimately contributing to the development of more efficient quantum devices.
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