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Autores principales:	Camposeo, A., Virgili, T., Lombardi, F., Cerullo, G., Pisignano, D., Polini, M.
Formato:	Preprint
Publicado:	2025
Materias:	Materials Science Applied Physics
Acceso en línea:	https://arxiv.org/abs/2503.03542
Etiquetas:	Agregar Etiqueta Sin Etiquetas, Sea el primero en etiquetar este registro!

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author	Camposeo, A. Virgili, T. Lombardi, F. Cerullo, G. Pisignano, D. Polini, M.
author_facet	Camposeo, A. Virgili, T. Lombardi, F. Cerullo, G. Pisignano, D. Polini, M.
contents	In the context of quantum thermodynamics, quantum batteries have emerged as promising devices for energy storage and manipulation. Over the past decade, substantial progress has been made in understanding the fundamental properties of quantum batteries, with several experimental implementations showing great promise. This Perspective provides an overview of the solid-state materials platforms that could lead to fully operational quantum batteries. After briefly introducing the basic features of quantum batteries, we discuss organic microcavities, where superextensive charging has already been demonstrated experimentally. We then explore other materials, including inorganic nanostructures (such as quantum wells and dots), perovskite systems, and (normal and high-temperature) superconductors. Key achievements in these areas, relevant to the experimental realization of quantum batteries, are highlighted. We also address challenges and future research directions. Despite their enormous potential for energy storage devices, research into advanced materials for quantum batteries is still in its infancy. This paper aims to stimulate interdisciplinarity and convergence among different materials science research communities to accelerate the development of new materials and device architectures for quantum batteries.
format	Preprint
id	arxiv_https___arxiv_org_abs_2503_03542
institution	arXiv
publishDate	2025
record_format	arxiv
spellingShingle	Quantum Batteries: A Materials Science Perspective Camposeo, A. Virgili, T. Lombardi, F. Cerullo, G. Pisignano, D. Polini, M. Materials Science Applied Physics In the context of quantum thermodynamics, quantum batteries have emerged as promising devices for energy storage and manipulation. Over the past decade, substantial progress has been made in understanding the fundamental properties of quantum batteries, with several experimental implementations showing great promise. This Perspective provides an overview of the solid-state materials platforms that could lead to fully operational quantum batteries. After briefly introducing the basic features of quantum batteries, we discuss organic microcavities, where superextensive charging has already been demonstrated experimentally. We then explore other materials, including inorganic nanostructures (such as quantum wells and dots), perovskite systems, and (normal and high-temperature) superconductors. Key achievements in these areas, relevant to the experimental realization of quantum batteries, are highlighted. We also address challenges and future research directions. Despite their enormous potential for energy storage devices, research into advanced materials for quantum batteries is still in its infancy. This paper aims to stimulate interdisciplinarity and convergence among different materials science research communities to accelerate the development of new materials and device architectures for quantum batteries.
title	Quantum Batteries: A Materials Science Perspective
topic	Materials Science Applied Physics
url	https://arxiv.org/abs/2503.03542

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