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Abstract

With the increasing demand for storage devices with higher energy output and better safety performance, all-solid-state batteries show their potential to replace the traditional liquid-based Li-ion batteries in the future storage market. Garnet-type Li ₇La ₃Zr ₂O ₁₂is one of the most attractive solid electrolyte materials because of its high ionic conductivity and stability to lithium metal. However, the large interfacial resistance originating from the insufficient solid-solid contact and the penetration of the lithium dendrite due to the inhomogeneous dissolution and deposition of lithium, hinder the all-solid-state batteries from developing. Focusing on the main interfacial problems in garnet-type all-solid battery, this review provides a fundamental understanding of the Li ₂CO ₃issues in Li ₇La ₃Zr ₂O ₁₂solid electrolyte and addresses the key factors influencing Li/ Li ₇La ₃Zr ₂O ₁₂/cathode interfacial wettability and the growth of Li dendrite, thus giving the key factors of constructing ideal interfaces. Finally, the possible research direction of garnet-type all-solid-state battery in the future is also prospected, which provides a guidance for developing and using all-solid-state batteries.

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Corresponding author:Liu Xiao-Song,xliu3@mail.sim.ac.cn

Funds:Project supported by the National Natural Science Foundation of China (Grant Nos. 11905283, U1632269, 11227902) and the National Key R&D Program of China (Grant No. 2019YFA0405600)

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LLZO与空气中的水和二氧化碳可能的反应过程	吉布斯自由能 ΔG/kJ·mol^–1
Li₅₆La₂₄Zr₁₆O₉₆+H₂O(g) → Li₅₅HLa₂₄Zr₁₆O₉₆+LiOH	–33
LiOH+1/2 CO₂(g) → 1/2 Li₂CO₃+1/2 H₂O(g)	–33.6
Li₅₆La₂₄Zr₁₆O₉₆+CO₂(g) → Li₅₄La₂₄Zr₁₆O₉₅+Li₂CO₃	+21.5
Li₂O+CO₂(g)→Li₂CO₃	–147.6
Li₅₆La₂₄Zr₁₆O₉₆+H₂O(g) → Li₅₄La₂₄Zr₁₆O₉₅+2 LiOH	+82.8
Li₅₆La₂₄Zr₁₆O₉₆+CO₂(g) → Li₅₄La₂₄Zr₁₆O₉₅+Li₂CO₃	+15.6

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Vol. 69, Issue 22 - 2020-11-20

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