Solid-state batteries enabled by ultra-high-frequency self-heating

IF 38.6 1区材料科学 Q1 CHEMISTRY, PHYSICAL

Joule Pub Date : 2025-06-10 DOI:10.1016/j.joule.2025.101973

Buyi Zhang, Divya Chalise, Yuqiang Zeng, Fengyu Shen, Michael Tucker, Sumanjeet Kaur, Chris Dames, Ravi Prasher

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Abstract

Solid-state batteries (SSBs) are promising next-generation batteries due to their high energy density and enhanced thermal stability and safety. However, their sluggish kinetics and transport at room temperature result in high internal impedance and critically reduce the attainable discharge energy density. Taking advantage of their strong temperature-dependent ionic conductivity, here we introduce ultra-high-frequency (greater than 10⁵ Hz) self-heating (UHFSH) of SSBs, which can rapidly warm up the batteries from room temperature to operating temperature (∼65°C) in less than a minute. As proof of concept, UHFSH experiments were conducted on symmetric solid-state cells with lithium aluminum germanium phosphate electrolyte in different configurations. Using an experimentally validated model, pack-level simulations predict fast heating (50 K/min) and minimized heating energy consumption (less than 4%). Without any modification of the materials or structure of the batteries, our non-intrusive self-heating strategy potentially enables SSBs to discharge more than 2-fold energy in 25°C ambient.

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超高频自加热固态电池

固态电池（SSBs）因其高能量密度、增强的热稳定性和安全性而成为下一代电池。然而，它们在室温下缓慢的动力学和传输导致高内部阻抗，严重降低了可实现的放电能量密度。利用其强大的温度依赖离子电导率，我们在这里引入了超高频（大于105 Hz）自加热（UHFSH）的ssb，它可以在不到一分钟的时间内将电池从室温快速加热到工作温度（~ 65°C）。为了验证这一概念，我们在含有不同构型磷酸锂铝锗电解质的对称固态电池上进行了UHFSH实验。使用实验验证的模型，包级模拟预测快速加热（50 K/min）和最小化加热能耗（低于4%）。无需对电池的材料或结构进行任何修改，我们的非侵入式自加热策略有可能使ssb在25°C的环境中放电超过2倍的能量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Joule Energy-General Energy

CiteScore

53.10

自引率

2.00%

发文量

198

期刊介绍： Joule is a sister journal to Cell that focuses on research, analysis, and ideas related to sustainable energy. It aims to address the global challenge of the need for more sustainable energy solutions. Joule is a forward-looking journal that bridges disciplines and scales of energy research. It connects researchers and analysts working on scientific, technical, economic, policy, and social challenges related to sustainable energy. The journal covers a wide range of energy research, from fundamental laboratory studies on energy conversion and storage to global-level analysis. Joule aims to highlight and amplify the implications, challenges, and opportunities of novel energy research for different groups in the field.