Dry-processed technology for flexible and high-performance FeS2-based all-solid-state lithium batteries at low stack pressure

阴极 材料科学 锂(药物) 储能 电解质 堆积 复合数 电极 纳米技术 电化学 复合材料 电池(电) 化学工程 工程类 电气工程 化学 量子力学 物理化学 有机化学 物理 功率(物理) 内分泌学 医学
作者
Chao Shen,Libin Hu,Haihua Tao,Yiqian Liu,Qiuhong Li,Wenrong Li,Tengzhou Ma,Bing Zhao,Jiujun Zhang,Yong Jiang
出处
期刊:Journal of Colloid and Interface Science [Elsevier BV]
卷期号:666: 472-480 被引量:5
标识
DOI:10.1016/j.jcis.2024.04.043
摘要

All-solid-state lithium batteries (ASSLBs) are considered promising energy storage systems due to their high energy density and inherent safety. However, scalable fabrication of ASSLBs based on transition metal sulfide cathodes through the conventional powder cold-pressing method with ultrahigh stacking pressure remains challenging. This article elucidates a dry process methodology for preparing flexible and high-performance FeS2-based ASSLBs under low stack pressure by utilizing polytetrafluoroethylene (PTFE) binder. In this design, fibrous PTFE interweaves Li6PS5Cl particles and FeS2 cathode components, forming flexible electrolyte and composite cathode membranes. Beneficial to the robust adhesion, the composite cathode and Li6PS5Cl membranes are tightly compacted under a low stacking pressure of 100 MPa which is a fifth of the conventional pressure. Moreover, the electrode/electrolyte interface can sustain adequate contact throughout electrochemical cycling. As expected, the FeS2-based ASSLBs exhibit outstanding rate performance and cyclic stability, contributing a reversible discharged capacity of 370.7 mAh g−1 at 0.3C after 200 cycles. More importantly, the meticulous dQ/dV analysis reveals that the three-dimensional PTFE binder effectively binds the discharge products with sluggish kinetics (Li2S and Fe) to the ion–electron conductive network in the composite cathode, thereby preventing the electrochemical inactivation of products and enhancing electrochemical performance. Furthermore, FeS2-based pouch-type cells are fabricated, demonstrating the potential of PTFE-based dry-process technology to scale up ASSLBs from laboratory-scale mold cells to factory-scale pouch cells. This feasible dry-processed technology provides valuable insights to advance the practical applications of ASSLBs.
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