Tri-sulfur radical trapping in lithium–sulfur batteries

IF 5.4 Q2 CHEMISTRY, PHYSICAL
Roza Bouchal , Clément Pechberty , Athmane Boulaoued , Niklas Lindahl , Patrik Johansson
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Abstract

Lithium-sulfur (Li–S) batteries have emerged as a next-generation battery technology owing to their prospects of high capacity and energy density. They, however, suffer from rapid capacity decay due to the shuttling of reaction intermediate species: Li polysulfides (LiPSs). One of the more important and intriguing PSs is the tri-sulfur radical (S3), observed mainly in high-donor number (DN) solvent-based electrolytes. Although this radical has been proposed to be crucial to full active material (AM) utilization, there is currently no direct evidence of the impact of S3 on cycling stability. To gain more insight into the role of the S3, we studied the use of radical traps in low and high DN solvent-based electrolytes by operando Raman spectroscopy. The traps were based on nitrone and iminium cation, and S3 was indeed successfully trapped in ex situ analysis. However, it was the ionic liquid-based trap, specifically pyridinium, that effectively suppressed S3 during battery operation. Overall, the PS formation was altered in the presence of the traps and we confirmed the impact of S3 formation on the Li–S battery redox reactions and show how the trapping correlates with Li–S battery performance. Therefore, stabilization of the S3 might be a path to improved Li–S batteries.

Abstract Image

锂硫电池中的三硫自由基陷阱
锂硫(Li-S)电池因其高容量和高能量密度的前景而成为下一代电池技术。然而,由于反应中间产物的穿梭,它们的容量衰减很快:多硫化锂(LiPSs)。三硫自由基(S3--)是其中一种较为重要且引人关注的多硫化物,主要出现在高放电数(DN)溶剂型电解质中。虽然这种自由基被认为对活性材料(AM)的充分利用至关重要,但目前还没有直接证据表明 S3--对循环稳定性的影响。为了更深入地了解 S3--的作用,我们通过操作拉曼光谱研究了低 DN 和高 DN 溶剂型电解质中自由基陷阱的使用情况。捕获器基于腈和亚胺阳离子,在原位分析中确实成功捕获了 S3--。然而,在电池运行过程中,基于离子液体的捕集器(特别是吡啶鎓)有效地抑制了 S3--。总之,PS 的形成在捕集剂的存在下发生了改变,我们证实了 S3--的形成对锂-S 电池氧化还原反应的影响,并展示了捕集剂与锂-S 电池性能之间的关联。因此,稳定 S3--可能是改进锂-S 电池的一条途径。
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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来源期刊
CiteScore
9.10
自引率
0.00%
发文量
18
审稿时长
64 days
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