锂基和钠基可充电电池中各种碳缺陷的性质与电化学电荷载体存储机制的相关性

IF 6.1 Q2 CHEMISTRY, PHYSICAL
Yuta Ito, Jiayuan Ni, Changhee Lee, Xinli Gao, Yuto Miyahara, K. Miyazaki, T. Abe
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引用次数: 0

摘要

随着人们对高能量需求设备的有前途的能源越来越感兴趣,基于电化学载流子存储的可充电电池材料(如Li和Na)的开发引起了人们的高度关注。其中,碳材料(如石墨烯、石墨和无序碳)由于其关键优势,即相对良好的电荷载流子存储能力、低成本、丰富的资源和简单的制造工艺,已被广泛用作电池系统的电极材料。特别地,在制造过程中,在碳结构中不可避免地形成各种类型的缺陷,这些缺陷显著影响它们的电化学电荷载流子存储机制,从而决定碳基可再充电电池系统的电化学性能。这篇综合综述总结了碳缺陷的基本性质与锂基和钠基可充电电池的电化学锂和钠储存机制之间的相关性,锂和钠基可再充电电池是使用电池系统的代表性阳离子,特别关注原子尺度的科学和技术,其在研究和理解碳结构中缺陷相与电荷载流子之间的相互作用方面具有显著作用。首先,为了本工作的目的,对各种碳缺陷进行了分类;然后,介绍了分析它们及其关键性质(尤其是电子结构)的计算/实验方法,因为识别缺陷类型至关重要。接下来,描述了碳缺陷对锂基和钠基可充电电池的电化学电荷载流子存储机制(特别是吸附和嵌入[插入]、扩散和金属团簇的形成)的作用和影响。本研究的重点是物理化学和电化学性质,这是碳缺陷的关键特征,决定了它们在可充电电池系统中的最佳利用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Correlation between properties of various carbon defects and electrochemical charge carrier storage mechanisms for use in Li- and Na-based rechargeable batteries
With the growing interest in promising energy sources for high-energy-demand devices, the development of materials for use in rechargeable batteries based on electrochemical charge carrier storage, such as Li and Na, has attracted intensive attention. Among them, carbon materials (e.g., graphene, graphite, and disordered carbons) have been extensively used as electrode materials for battery systems because of their critical advantages, namely, relatively good charge carrier storage capability, low cost, abundant resources, and simple manufacturing process. In particular, various types of defects are indispensably formed in the carbon structure during the manufacturing processes, which significantly influence their electrochemical charge carrier storage mechanisms and thus determine the electrochemical properties of the carbon-based rechargeable battery systems. This comprehensive review summarizes the correlation between the fundamental properties of carbon defects and electrochemical Li and Na storage mechanisms for Li- and Na-based rechargeable batteries, representative cations using battery systems, with a special focus on atomic-scale science and technology, which have a notable role in investigating and understanding the interaction between the defect phases and charge carriers in carbon structures. First, various carbon defects are categorized for the purpose of this work; then, computational/experimental methods for analyzing them and their critical properties (especially electronic structure) are introduced because identifying defect types is critical. Next, the roles and influences of carbon defects on electrochemical charge carrier storage mechanisms (especially adsorption and intercalation [insertion], diffusion, and formation of metal clusters) are described for Li- and Na-based rechargeable batteries. This study focuses on the physicochemical and electrochemical properties, which are key characteristics of carbon defects that determine their optimal utilization in rechargeable battery systems.
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