控制冷烧结过程中的表面化学反应,促进电池材料的发展

IF 2.9 Q1 MATERIALS SCIENCE, CERAMICS Open Ceramics Pub Date : 2024-07-10 DOI:10.1016/j.oceram.2024.100639
Y.C. Lan , Z.M. Grady , S. Dursun , E.D. Gomez , C.A. Randall
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引用次数: 0

摘要

冷烧结是最近推出的一种致密化方法,由于其在加工过程中使用的能量较低、能够致密化易变材料、能够整合材料以开发独特的复合材料,以及能够合成更易于回收的材料,因此备受关注。总之,这些优势使冷烧结成为一种很有前途的电池组件加工方法,并可与所有固态电池共同烧结。为了通过冷烧结获得高电化学性能,需要对粉末的表面化学性质进行详细控制,以避免或最大限度地减少晶界碳酸盐形成的影响,并限制因溶解过程不协调而产生的次生相的浓度。本文概述了冷烧结过程中粉末表面化学反应的重要性,以及可用于控制这些反应并为锂和氧化钕二次电池获得高性能和独特机会的缓解过程。我们重点介绍了一系列实例,这些实例展示了控制低温致密化(冷烧结)如何解决许多电池材料的环境敏感性问题,并强调了面临的问题和有待解决的问题。这些例子包括对空气敏感的固体电解质的冷烧结、粉碎固体电解质的再加工、在空气中加工对空气敏感的活性材料的表面钝化,以及固态电池固-固宏观界面的制造。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Controlling surface chemistry in cold sintering to advance battery materials

Cold sintering is a recently introduced densification method that is of interest due to the lower energy used in the process, the ability to densify metastable materials, the ability to integrate materials to develop unique composites, and the ability to synthesis materials that can be more easily recycled. Collectively, these advantages make cold sintering a promising approach for processing of battery components, and co-sintering into all solid-state batteries. To obtain high electrochemical performance with cold sintering, detailed control of the surface chemistry of powders is needed, to avoid or minimize the impact of carbonate formation in grain boundaries, and to limit concentrations of secondary phases that are a result of incongruent dissolution processes. In this paper, we outline the importance of surface chemical reactions of powders in cold sintering, and the mitigating processes that can be adopted to control these reactions and obtain high performance and unique opportunities for Li and Na-oxide secondary batteries. We focus on a series of examples that demonstrate how the control of low temperature densification (cold sintering) can address the environmental sensitivity of many battery materials, and highlight the issues faced and open questions. These examples include cold sintering of air-sensitive solid electrolytes, re-processing of crushed solid electrolytes, surface passivation of air-sensitive active materials for processing in air, and fabrication of solid-solid macroscopic interfaces for solid-state batteries.

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来源期刊
Open Ceramics
Open Ceramics Materials Science-Materials Chemistry
CiteScore
4.20
自引率
0.00%
发文量
102
审稿时长
67 days
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