Improved Stability of Oxysulfide Solid-State Electrolytes in Li(G3)TFSI Solvate Ionic Liquid Electrolyte

Thomas A. Yersak, Yubin Zhang, Hasnain Hafiz, N. Pieczonka, Hernando J. Gonzalez Malabet, Hayden Cunningham, Mei Cai
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Abstract

The performance of all solid-state batteries is limited by poor interfacial contact between active material and solid-state electrolyte (SSE) particles. Semi-solid batteries utilize a secondary electrolyte phase to wet the SSE/AM interface to improve cell performance. Solvate ionic liquids (SILs) are one class of liquid electrolytes under consideration for use in semi-solid batteries. This paper focuses on the Li(G3)TFSI SIL consisting of the bis(trifluoromethanesulfonyl)imide (TFSI-) anion coupled to a [Li(G3)]+ solvate cation. Sulfide SSEs are normally subject to nucleophilic attack by trigylme (G3), however, strong coordination of Li+ to G3 in the [Li(G3)]+ solvate cation prevents this reaction from taking place. Consequently, the stability of sulfide SSE depends on the ideal 1:1 molar ratio of G3 to TFSI, which may be difficult to maintain. We studied the chemical stability of 70Li2S·(30-x)P2S5·xP2O5 (x = 0, 2, 5, 10) (oxy)sulfide solid-state electrolyte in Li(G3)TFSI SIL. By physical measurement, UV-Vis spectroscopy, electrochemical evaluation, X-ray photoelectron spectroscopy, and first principles calculation it is shown that increased oxygen content improves the stability of SSE in various Li(G3)xTFSI (x = 1, 2, 3, 4) liquid electrolytes. The results suggest that an oxysulfide SSE + SIL semi-solid electrolyte is a good choice for future semi-solid battery designs.
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提高氧化硫固态电解质在 Li(G3)TFSI Solvate 离子液体电解质中的稳定性
由于活性材料与固态电解质(SSE)颗粒之间的界面接触不良,所有固态电池的性能都受到了限制。半固态电池利用第二电解质相来润湿固态电解质/AM 界面,从而提高电池性能。溶解离子液体 (SIL) 是考虑用于半固态电池的一类液态电解质。本文重点介绍 Li(G3)TFSI SIL,它由双(三氟甲磺酰)亚胺(TFSI-)阴离子与[Li(G3)]+溶质阳离子组成。硫化物 SSE 通常会受到三酰亚胺 (G3) 的亲核攻击,然而,[Li(G3)]+ 溶剂阳离子中 Li+ 与 G3 的强配位阻止了这种反应的发生。因此,硫化物 SSE 的稳定性取决于 G3 与 TFSI 1:1 的理想摩尔比,而这一摩尔比可能难以维持。我们研究了 70Li2S-(30-x)P2S5-xP2O5 (x = 0, 2, 5, 10) (氧)硫化物固态电解质在 Li(G3)TFSI SIL 中的化学稳定性。通过物理测量、紫外可见光谱、电化学评估、X 射线光电子能谱和第一性原理计算,结果表明增加氧含量可提高 SSE 在各种 Li(G3)xTFSI (x = 1、2、3、4) 液体电解质中的稳定性。结果表明,氧化硫 SSE + SIL 半固态电解质是未来半固态电池设计的良好选择。
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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