降级(电信)
涂层
阴极
电化学
材料科学
氧化物
储能
纳米技术
电化学储能
锂(药物)
化学稳定性
化学工程
化学能
图层(电子)
工作(物理)
焊剂(冶金)
纳米线
机械强度
电池(电)
光谱学
磷酸铁锂
作者
X. R. Zheng,Zhichen Xue,Hongchang Hao,Yukio Cho,Yuanshun Li,Chanho Kim,Paweł Czaja,Samuel Lee,Sharon Bone,Eleanor Spielman-Sun,Zhelong Jiang,X. Wendy Gu,Johanna Nelson Weker,Guang Yang,Jagjit Nanda
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2025-10-08
卷期号:11 (41): eady7189-eady7189
被引量:8
标识
DOI:10.1126/sciadv.ady7189
摘要
Solid-state batteries (SSBs) hold notable promise for advancing energy storage technologies. However, their commercial viability is limited by the poor cycle stability and complex degradation mechanism. This study underscores the pivotal role of electro-chemo-mechanical interactions in driving the failure of SSBs. Leveraging advanced x-ray imaging and spectroscopy techniques, we analyzed LiNi0.8Mn0.1Co0.1O2 (NMC811) cathodes from cycled LixIn||Li6PS5Cl (LPSC)||NMC811 SSBs, uncovering the interplay between microstructure, chemical heterogeneity, mechanical characteristics, and electrochemical performance. Our results show that revealing electro-chemo-mechanical interactions is essential to develop strategies to suppress the degradation of SSBs. Particularly, we revisit a LiNbO3 (LNO) coating layer to mitigate electrochemical degradation. The LNO@NMC811 cathode retains 116 milliampere-hours per gram after 200 cycles, showing excellent stability, while the uncoated NMC811 cathode keeps degrading over time, with suppressed chemical heterogeneity and mechanical failure. This work highlights the importance of synergizing advanced material design with coating techniques, ensuring uniform lithium flux and improving mechanical properties to achieve stable, high-performance SSBs.
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