电极材料中的离子输运现象

IF 6.1 Q2 CHEMISTRY, PHYSICAL
Jing Wen, Xinzhi Ma, Lu Li, Xitian Zhang, Bin Wang
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引用次数: 0

摘要

由于需求的不断增长,基于电极材料的大功率、高速率储能器件引起了极大的关注。然而,要改进离子扩散的浓度依赖性动力学,并了解随颗粒形态和扫描速率变化的相变、界面反应和电容行为,仍有挑战需要解决。了解电极材料中离子传输的微观起源是有价值的。在这篇综述中,我们通过比较几十种经过充分研究的过渡金属氧化物、硫化物和磷酸盐,以及阳极材料中的微观输运现象及其对离子浓度的依赖性,包括几种碳物种和碳化物。我们在充分研究系统的基础上,从现象学的角度推广了微观离子输运过程的动力学效应。对离子扩散的主要动力学效应随离子浓度的变化而变化,并证明了颗粒尺寸和边界对路径和形态依赖的扩散和电容行为的影响。讨论了相变、转移电子和水分子对离子传输的重要动力学效应。该结果有望揭示充电/放电速率的微观限制因素,用于开发新的插层和转化反应体系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ion transport phenomena in electrode materials
Because of the increasing demand, high-power, high-rate energy storage devices based on electrode materials have attracted immense attention. However, challenges remain to be addressed to improve the concentration-dependent kinetics of ionic diffusion and understand phase transformation, interfacial reactions, and capacitive behaviors that vary with particle morphology and scanning rates. It is valuable to understand the microscopic origins of ion transport in electrode materials. In this review, we discuss the microscopic transport phenomena and their dependence on ion concentration in the cathode materials, by comparing dozens of well-studied transition metal oxides, sulfides, and phosphates, and in the anode materials, including several carbon species and carbides. We generalize the kinetic effects on the microscopic ionic transport processes from the phenomenological points of view based on the well-studied systems. The dominant kinetic effects on ion diffusion varied with ion concentration, and the pathway- and morphology-dependent diffusion and capacitive behaviors affected by the sizes and boundaries of particles are demonstrated. The important kinetic effects on ion transport by phase transformation, transferred electrons, and water molecules are discussed. The results are expected to shed light on the microscopic limiting factors of charging/discharging rates for developing new intercalation and conversion reaction systems.
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