Hot pressing a high loading FeS2 all-solid-state composite cathode improves initial cycle performance

IF 2.6 4区化学 Q3 ELECTROCHEMISTRY

Journal of Solid State Electrochemistry Pub Date : 2024-06-27 DOI:10.1007/s10008-024-05989-1

Thomas A. Yersak, Hernando J. Gonzalez Malabet, Mei Cai

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Abstract

This study reports that hot pressing a high loading (9.375 mg cm⁻²; > 5 mAh cm⁻²) all-solid-state FeS₂ composite cathodes at 240 °C and 47 MPa improved initial cycle performance. At 25 °C, a cold-pressed cell delivered negligible capacity whereas a hot-pressed cell delivered 332 mAh g⁻¹ (2.34 mAh cm⁻²). At 60 °C, a cold-pressed cell delivered 666 mAh g⁻¹ (4.70 mAh cm⁻²) whereas a hot-pressed cell delivered 782 mAh g⁻¹ (5.52 mAh cm⁻²). Hot-pressed cathode composites had a 20% porosity whereas cold-pressed cathode composites had a 30% porosity. Increased initial discharge capacity was attributed to better solid–solid interfacial contact between sulfide solid-state electrolyte (SSE) particles and between SSE and FeS₂ active material particles. Cell failure occurred upon extended cycling due to the stresses generated by the expansion of lithiated FeS₂. FIBSEM cross-sectional imaging of post mortem cathode composites revealed horizontal cracking indicative of electrode delamination due to electrode expansion.

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热压高负载 FeS2 全固态复合阴极可提高初始循环性能

本研究报告称，在 240 °C 和 47 MPa 条件下热压高负载（9.375 mg cm-2; > 5 mAh cm-2）全固态 FeS2 复合阴极可提高初始循环性能。25 °C 时，冷压电池的容量可忽略不计，而热压电池的容量为 332 mAh g-1（2.34 mAh cm-2）。60 °C 时，冷压电池的容量为 666 mAh g-1（4.70 mAh cm-2），而热压电池的容量为 782 mAh g-1（5.52 mAh cm-2）。热压阴极复合材料的孔隙率为 20%，而冷压阴极复合材料的孔隙率为 30%。初始放电容量的增加归因于硫化物固态电解质（SSE）颗粒之间以及 SSE 和 FeS2 活性材料颗粒之间更好的固-固界面接触。由于石化 FeS2 膨胀产生的应力，电池在长时间循环后发生失效。对死后阴极复合材料的 FIBSEM 横截面成像显示出水平裂纹，表明电极膨胀导致电极分层。

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来源期刊

Journal of Solid State Electrochemistry 工程技术-电化学

CiteScore

4.80

自引率

4.00%

发文量

227

审稿时长

4.1 months

期刊介绍： The Journal of Solid State Electrochemistry is devoted to all aspects of solid-state chemistry and solid-state physics in electrochemistry. The Journal of Solid State Electrochemistry publishes papers on all aspects of electrochemistry of solid compounds, including experimental and theoretical, basic and applied work. It equally publishes papers on the thermodynamics and kinetics of electrochemical reactions if at least one actively participating phase is solid. Also of interest are articles on the transport of ions and electrons in solids whenever these processes are relevant to electrochemical reactions and on the use of solid-state electrochemical reactions in the analysis of solids and their surfaces. The journal covers solid-state electrochemistry and focusses on the following fields: mechanisms of solid-state electrochemical reactions, semiconductor electrochemistry, electrochemical batteries, accumulators and fuel cells, electrochemical mineral leaching, galvanic metal plating, electrochemical potential memory devices, solid-state electrochemical sensors, ion and electron transport in solid materials and polymers, electrocatalysis, photoelectrochemistry, corrosion of solid materials, solid-state electroanalysis, electrochemical machining of materials, electrochromism and electrochromic devices, new electrochemical solid-state synthesis. The Journal of Solid State Electrochemistry makes the professional in research and industry aware of this swift progress and its importance for future developments and success in the above-mentioned fields.