In Situ Formed Shields Enabling Li 2 CO 3 -Free Solid Electrolytes: A New Route to Uncover the Intrinsic Lithiophilicity of Garnet Electrolytes for Dendrite-Free Li-Metal Batteries

In Situ Formed Shields Enabling Li 2 CO 3 -Free Solid Electrolytes: A New Route to Uncover the Intrinsic Lithiophilicity of Garnet Electrolytes for Dendrite-Free Li-Metal Batteries

Introduction of inorganic solid electrolytes is believed to be an ultimate strategy to dismiss dendritic Li in high-energy Li-metal batteries (LMBs), and garnet-type Li La Zr O (LLZO) electrolytes are impressive candidates. However, the current density for stable Li plating/stripping in LLZO is stil...

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Bibliographic Details
Published in:ACS applied materials & interfaces Vol. 11; no. 1; pp. 898 - 905
Main Authors: Wu, Jian-Fang, Pu, Bo-Wei, Wang, Da, Shi, Si-Qi, Zhao, Ning, Guo, Xiangxin, Guo, Xin
Format: Journal Article
Language:English
Published: United States 09-01-2019
Subjects:
dendritic Li
interfaces
Li-metal battery
Li7La3Zr2O12
solid electrolytes
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Summary:Introduction of inorganic solid electrolytes is believed to be an ultimate strategy to dismiss dendritic Li in high-energy Li-metal batteries (LMBs), and garnet-type Li La Zr O (LLZO) electrolytes are impressive candidates. However, the current density for stable Li plating/stripping in LLZO is still quite limited. Here, we create in situ formed Li-deficient shields by the high-temperature calcination at 900 °C. By this novel process, the formation of Li CO on LLZO is restrained, and then we successfully obtain Li CO -free LLZO after removing the Li-deficient compounds. Without any surface modification, Li CO -free LLZO shows an intrinsic "lithiophilicity" characteristic. The contact angles of metallic Li on LLZO garnets are assessed by the first-principle calculation to confirm the lithiophilicity characteristic of LLZO electrolytes. The wetting of metallic Li on the Li CO -free LLZO surface leads to a continuous and tight Li/LLZO interface, resulting in an ultralow interfacial resistance of 49 Ω cm and a homogeneous current distribution in the charge/discharge processes of LMBs. Consequently, the current density for the stable Li plating/stripping in LLZO increases to 900 μA cm at 60 °C, one of the highest current density for LMBs based on garnet-type LLZO electrolytes. Our findings not only offer insight into the lithiophilicity characteristics of LLZO electrolytes to suppress dendritic Li at high current densities but also expand the avenue toward high-performance, safe, and long-life energy-storage systems.
ISSN:1944-8244
1944-8252
DOI:10.1021/acsami.8b18356