High-Entropy Halides for Intercalation Battery Electrode Materials

IF 3.5 4区化学 Q2 ELECTROCHEMISTRY

ChemElectroChem Pub Date : 2025-02-21 DOI:10.1002/celc.202400659

Sebastian Schumacher, Dr. Evgeny V. Alekseev, Dr. Shicheng Yu, Dr. Hermann Tempel, Prof. Dr. Rüdiger-A. Eichel

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Abstract

The potential use of high-entropy materials in batteries has recently attracted considerable interest. Compared to traditional materials, high-entropy materials exhibit a high defect density and degree of internal entropy, resulting in enhanced ion storage capabilities, ionic conductivity, and electrochemical stability. High-entropy oxides represent a more extensively investigated material for various electrochemical applications, particularly for potential use as a cathode or electrolyte in battery applications. These multicomponent systems are distinguished by their structural complexity and exhibit enhanced cycling stability, exceeding the performance of traditional oxide materials. The exploration of high-entropy halides as electrode materials is less extensive than that of their traditional counterparts, despite the latter being the subject of considerable research. This work offers a concise overview of how high-entropy materials can be applied to halide phases, focusing on the transition from high-entropy oxides to high-entropy halides.

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用于嵌入电池电极材料的高熵卤化物

高熵材料在电池中的潜在应用最近引起了相当大的兴趣。与传统材料相比，高熵材料具有较高的缺陷密度和内部熵度，从而增强了离子存储能力、离子电导率和电化学稳定性。高熵氧化物代表了一种被广泛研究的材料，用于各种电化学应用，特别是在电池应用中作为阴极或电解质的潜在用途。这些多组分体系的特点是其结构复杂，表现出增强的循环稳定性，超过了传统氧化物材料的性能。高熵卤化物作为电极材料的探索不如传统的同类材料广泛，尽管后者是大量研究的主题。这项工作提供了高熵材料如何应用于卤化物相的简要概述，重点是从高熵氧化物到高熵卤化物的转变。

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来源期刊

ChemElectroChem ELECTROCHEMISTRY-

CiteScore

7.90

自引率

2.50%

发文量

515

审稿时长

1.2 months

期刊介绍： ChemElectroChem is aimed to become a top-ranking electrochemistry journal for primary research papers and critical secondary information from authors across the world. The journal covers the entire scope of pure and applied electrochemistry, the latter encompassing (among others) energy applications, electrochemistry at interfaces (including surfaces), photoelectrochemistry and bioelectrochemistry.