Intercalation-type positive electrode materials for nonaqueous calcium-ion batteries

IF 6.1 Q2 CHEMISTRY, PHYSICAL Chemical physics reviews Pub Date : 2022-03-01 DOI:10.1063/5.0073087
H. Bu, Hyungjin Lee, Dedy Setiawan, Seung‐Tae Hong
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引用次数: 3

Abstract

Calcium-ion batteries (CIBs) are among the promising alternatives to overcome the limitation of lithium-ion batteries in current use. Compared with lithium, calcium is environmentally friendly, reliable, safe, and abundant in resources. Despite the development of intercalation-type cathode materials for CIBs in its infancy, the number of newly discovered materials has remarkably increased in the last few years. In this Review, we present the recent accomplishments and challenges in the development of cathode materials for nonaqueous CIBs, classified by the constituent anion type: oxides, polyanions, and others (chalcogenides, fluorides, and nitrides), and further subdivided based on Ca diffusion dimensionality (one-, two-, and three-dimensions). Each of the materials is presented, emphasizing structural aspects, electrochemical properties, intercalation mechanisms during cycling, and problems to be solved. Finally, this Review concludes by providing overview and perspectives on each type of materials. To date, the observed capacities are still far below the theoretically expected doubled capacity due to the divalency of calcium. Nevertheless, the research progress during the past few years suggests that unexplored opportunities for discovering new cathode materials with improved performances are wide open. This Review will help researchers easily grasp the overall accomplishments and challenges of the CIB cathode materials, stimulating further development.
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非水钙离子电池用插层式正极材料
钙离子电池(cib)是克服目前使用的锂离子电池局限性的有前途的替代品之一。与锂相比,钙具有环保、可靠、安全、资源丰富等优点。尽管cib的插层型阴极材料的发展还处于起步阶段,但近年来新发现的材料数量显著增加。在这篇综述中,我们介绍了非水阴极材料的最新成就和挑战,按阴离子类型分类:氧化物、聚阴离子和其他阴离子(硫族化物、氟化物和氮化物),并根据Ca扩散维度进一步细分(一维、二维和三维)。介绍了每一种材料,强调结构方面,电化学性质,循环过程中的嵌入机制,以及有待解决的问题。最后,本综述通过对每种材料的概述和观点进行总结。到目前为止,由于钙的二价性,观察到的容量仍然远远低于理论上预期的双倍容量。然而,过去几年的研究进展表明,发现具有改进性能的新阴极材料的未开发机会是开放的。本文综述有助于研究人员更好地把握CIB阴极材料的总体成就和面临的挑战,促进其进一步发展。
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