Novel electriferous charge-mosaic S(TMC@Lys-Li) separator towards efficient Li+ fast-transfer for high-energy density and long-duration lithium-sulfur batteries

IF 13.1 1区 化学 Q1 Energy Journal of Energy Chemistry Pub Date : 2024-11-07 DOI:10.1016/j.jechem.2024.10.050
Lei Ding , Dandan Li , Sihang Zhang , Zhaoyang Wang , Pengfang Zhang , Fanghui Du , Shuyue Zhao , Daoxin Zhang , Feng Yang , Shuo Zhang
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Abstract

Lithium-sulfur (Li-S) batteries with attractive capacity give remarkable potential for prospective high-capacity application scenarios but suffer a fatal flaw of short cyclability before large-scale commercialization especially owing to polysulfide (Li2Sn) transmembrane shuttling. To efficiently restrain chronic Li2Sn shuttle and expedite Li+ transfer, herein, a novel electriferous charge-mosaic S(TMC@Lys-Li) separator preparation approach is recommended. Interfacial polymerizations of lithiated lysine and trimesoyl chloride establish an electriferous charge-mosaic polyamide functional layer. Substituted Li within the charge-mosaic layer offers transition or replacement sites for smoothing Li+ migrations, which constructs efficient Li+ fast-transfer private channels and accelerates the Li+ transfer rate to 9.4 times. Negatively charged polyamide skeleton synchronously heightens Li2Sn rejections by combining Donnan and steric effects. S(TMC@Lys-Li) replenishes Li for homogenizing Li nucleation and growth, endowing stable plating/stripping behaviors over 250 cycles for Li-Cu batteries. Assembled Li-S cells thus exhibit excellent specific capacity and cyclability at multiple application scenarios such as long periods, high areal capacity, and fast charge, holding 78.1% retention after 500 cycles at 1 C. The superior thermal stability and self-discharge of S(TMC@Lys-Li) dramatically strengthen battery thermal runaway resistance even at 155 ℃, which ensures security for Li-S battery high-power and high-temperature operations. Above alluring features enable charge-mosaic separators to be potentially adopted in practical Li-S batteries demanding strict security, high-capacity density, and fast charge technology.

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新型离心电荷镶嵌式 S(TMC@Lys-Li)隔膜实现高能量密度和长寿命锂硫电池的高效 Li+ 快速转移
锂-硫(Li-S)电池具有诱人的容量,在高容量应用前景方面具有显著的潜力,但在大规模商业化之前却存在循环周期短的致命缺陷,特别是由于多硫化物(Li2Sn)的跨膜穿梭。为了有效抑制慢性 Li2Sn 穿梭并加速 Li+ 传输,本文推荐了一种新颖的电离电荷镶嵌式 S(TMC@Lys-Li)分离器制备方法。锂化赖氨酸和三甲基甲酰氯的界面聚合建立了一种带电电荷马赛克聚酰胺功能层。电荷镶嵌层中的替代锂为平滑 Li+ 迁移提供了过渡或置换位点,从而构建了高效的 Li+ 快速转移私人通道,并将 Li+ 转移率提高到 9.4 倍。带负电荷的聚酰胺骨架通过结合唐南效应和立体效应,同步提高了对 Li2Sn 的排斥。S(TMC@Lys-Li)为锂的均匀成核和生长补充了锂,使锂电池在 250 个循环周期内具有稳定的电镀/剥离性能。S(TMC@Lys-Li) 优异的热稳定性和自放电性能极大地增强了电池的抗热失控能力,即使在 155 ℃ 下也能保持稳定,从而确保锂电池在高功率和高温条件下的安全运行。上述诱人的特性使电荷镶嵌式隔膜有可能应用于对安全性、高容量密度和快速充电技术要求严格的实用锂-S 电池中。
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来源期刊
Journal of Energy Chemistry
Journal of Energy Chemistry CHEMISTRY, APPLIED-CHEMISTRY, PHYSICAL
CiteScore
19.10
自引率
8.40%
发文量
3631
审稿时长
15 days
期刊介绍: The Journal of Energy Chemistry, the official publication of Science Press and the Dalian Institute of Chemical Physics, Chinese Academy of Sciences, serves as a platform for reporting creative research and innovative applications in energy chemistry. It mainly reports on creative researches and innovative applications of chemical conversions of fossil energy, carbon dioxide, electrochemical energy and hydrogen energy, as well as the conversions of biomass and solar energy related with chemical issues to promote academic exchanges in the field of energy chemistry and to accelerate the exploration, research and development of energy science and technologies. This journal focuses on original research papers covering various topics within energy chemistry worldwide, including: Optimized utilization of fossil energy Hydrogen energy Conversion and storage of electrochemical energy Capture, storage, and chemical conversion of carbon dioxide Materials and nanotechnologies for energy conversion and storage Chemistry in biomass conversion Chemistry in the utilization of solar energy
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