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A dynamic stability design strategy for lithium metal solid state batteries

Author

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  • Luhan Ye

    (Harvard University)

  • Xin Li

    (Harvard University)

Abstract

A solid-state electrolyte is expected to suppress lithium (Li) dendrite penetration with high mechanical strength1–4. However, in practice it still remains challenging to realise a lithium metal anode for batteries, because micrometre- or submicrometre-sized cracks in ceramic pellets can frequently be generated during battery assembly or long-time cycling3,5. Once cracks form, lithium dendrite penetration is inevitable6,7. Here we describe a solid-state battery design with a hierarchy of interface stabilities (to lithium metal responses), to achieve an ultrahigh current density with no lithium dendrite penetration. Our multilayer design has the structure of a less-stable electrolyte sandwiched between more-stable solid electrolytes, which prevents any lithium dendrite growth through well localized decompositions in the less stable electrolyte layer. A mechanism analogous to the expansion screw effect is proposed, whereby any cracks are filled by dynamically generated decompositions that are also well constrained, probably by the ‘anchoring’ effect the decompositions induce. The cycling performance of the lithium metal anode paired with a LiNi0.8Mn0.1Co0.1O2 cathode is very stable, with an 82 per cent capacity retention after 10,000 cycles at a 20C rate (8.6 milliamps per centimetre squared) and 81.3 per cent capacity retention after 2,000 cycles at a 1.5C rate (0.64 milliamps per centimetre squared). Our design also enables a specific power of 110.6 kilowatts per kilogram and specific energy up to 631.1 watt hours per kilogram at the micrometre-sized cathode material level.

Suggested Citation

  • Luhan Ye & Xin Li, 2021. "A dynamic stability design strategy for lithium metal solid state batteries," Nature, Nature, vol. 593(7858), pages 218-222, May.
    • Handle: RePEc:nat:nature:v:593:y:2021:i:7858:d:10.1038_s41586-021-03486-3
    DOI: 10.1038/s41586-021-03486-3
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    Cited by:

    1. Zhi Chang & Huijun Yang & Xingyu Zhu & Ping He & Haoshen Zhou, 2022. "A stable quasi-solid electrolyte improves the safe operation of highly efficient lithium-metal pouch cells in harsh environments," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
    2. Dewu Zeng & Jingming Yao & Long Zhang & Ruonan Xu & Shaojie Wang & Xinlin Yan & Chuang Yu & Lin Wang, 2022. "Promoting favorable interfacial properties in lithium-based batteries using chlorine-rich sulfide inorganic solid-state electrolytes," Nature Communications, Nature, vol. 13(1), pages 1-13, December.
    3. Yuhgene Liu & Congcheng Wang & Sun Geun Yoon & Sang Yun Han & John A. Lewis & Dhruv Prakash & Emily J. Klein & Timothy Chen & Dae Hoon Kang & Diptarka Majumdar & Rajesh Gopalaswamy & Matthew T. McDowe, 2023. "Aluminum foil negative electrodes with multiphase microstructure for all-solid-state Li-ion batteries," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    4. Guangzhao Zhang & Jian Chang & Liguang Wang & Jiawei Li & Chaoyang Wang & Ruo Wang & Guoli Shi & Kai Yu & Wei Huang & Honghe Zheng & Tianpin Wu & Yonghong Deng & Jun Lu, 2023. "A monofluoride ether-based electrolyte solution for fast-charging and low-temperature non-aqueous lithium metal batteries," Nature Communications, Nature, vol. 14(1), pages 1-13, December.
    5. Johannes Morfeldt & Daniel J. A. Johansson, 2022. "Impacts of shared mobility on vehicle lifetimes and on the carbon footprint of electric vehicles," Nature Communications, Nature, vol. 13(1), pages 1-11, December.
    6. Hui Pan & Lei Wang & Yu Shi & Chuanchao Sheng & Sixie Yang & Ping He & Haoshen Zhou, 2024. "A solid-state lithium-ion battery with micron-sized silicon anode operating free from external pressure," Nature Communications, Nature, vol. 15(1), pages 1-12, December.
    7. Lei Gao & Xinyu Zhang & Jinlong Zhu & Songbai Han & Hao Zhang & Liping Wang & Ruo Zhao & Song Gao & Shuai Li & Yonggang Wang & Dubin Huang & Yusheng Zhao & Ruqiang Zou, 2023. "Boosting lithium ion conductivity of antiperovskite solid electrolyte by potassium ions substitution for cation clusters," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    8. Daiwei Wang & Li-Ji Jhang & Rong Kou & Meng Liao & Shiyao Zheng & Heng Jiang & Pei Shi & Guo-Xing Li & Kui Meng & Donghai Wang, 2023. "Realizing high-capacity all-solid-state lithium-sulfur batteries using a low-density inorganic solid-state electrolyte," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    9. Yantao Wang & Hongtao Qu & Bowen Liu & Xiaoju Li & Jiangwei Ju & Jiedong Li & Shu Zhang & Jun Ma & Chao Li & Zhiwei Hu & Chung-Kai Chang & Hwo-Shuenn Sheu & Longfei Cui & Feng Jiang & Ernst R. H. Eck , 2023. "Self-organized hetero-nanodomains actuating super Li+ conduction in glass ceramics," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    10. Pushun Lu & Yu Xia & Guochen Sun & Dengxu Wu & Siyuan Wu & Wenlin Yan & Xiang Zhu & Jiaze Lu & Quanhai Niu & Shaochen Shi & Zhengju Sha & Liquan Chen & Hong Li & Fan Wu, 2023. "Realizing long-cycling all-solid-state Li-In||TiS2 batteries using Li6+xMxAs1-xS5I (M=Si, Sn) sulfide solid electrolytes," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    11. Jelena Popovic, 2021. "The importance of electrode interfaces and interphases for rechargeable metal batteries," Nature Communications, Nature, vol. 12(1), pages 1-5, December.

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