材料科学
发射率
电极
电解质
分离器(采油)
热失控
热导率
热稳定性
光电子学
介电常数
化学工程
储能
热能储存
电池(电)
红外线的
纳米技术
复合材料
光学
电介质
化学
工程类
功率(物理)
物理化学
物理
热力学
生物
量子力学
生态学
作者
Xin Pang,Hyun‐Jin Lee,Jingzhi Rong,Qiaoyu Zhu,Shumao Xu
出处
期刊:Small
[Wiley]
日期:2024-05-05
卷期号:20 (36): e2309580-e2309580
被引量:11
标识
DOI:10.1002/smll.202309580
摘要
Abstract Li‐ion batteries with superior interior thermal management are crucial to prevent thermal runaway and ensure safe, long‐lasting operation at high temperatures or during rapid discharging and charging. Typically, such thermal management is achieved by focusing on the separator and electrolyte. Here, the study introduces a Se‐terminated MXene free‐standing electrode with exceptional electrical conductivity and low infrared emissivity, synergistically combining high‐rate capacity with reduced heat radiation for safe, large, and fast Li + storage. This is achieved through a one‐step organic Lewis acid‐assisted gas‐phase reaction and vacuum filtration. The Se‐terminated Nb 2 Se 2 C outperformed conventional disordered O/OH/F‐terminated materials, enhancing Li + ‐storage capacity by ≈1.5 times in the fifth cycle (221 mAh·g −1 at 1 A·g −1 ) and improving mid‐infrared adsorption with low thermal radiation. These benefits result from its superior electrical conductivity, excellent structural stability, and high permittivity in the infrared region. Calculations further reveal that increased permittivity and conductivity along the z‐direction can reduce heat radiation from electrodes. This work highlights the potential of surface groups‐terminated layered material‐based free‐standing flexible electrodes with self‐thermal management ability for safe, fast energy storage.
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