The carrier transition from Li atoms to Li vacancies in solid-state lithium alloy anodes

Yang Lu; Chen Zi Zhao; Rui Zhang; Hong Yuan; Li Peng Hou; Zhong Heng Fu; Xiang Chen; Jia Qi Huang; Qiang Zhang

doi:10.1126/sciadv.abi5520

The carrier transition from Li atoms to Li vacancies in solid-state lithium alloy anodes

Yang Lu
, Chen Zi Zhao
, Rui Zhang
, Hong Yuan
, Li Peng Hou
, Zhong Heng Fu
, Xiang Chen
, Jia Qi Huang
, Qiang Zhang^*

^*此作品的通讯作者

Tsinghua University
Beijing Institute of Technology

科研成果: 期刊稿件 › 文章 › 同行评审

327 引用（Scopus）

摘要

The stable cycling of energy-dense solid-state batteries is highly relied on the kinetically stable solid-state Li alloying reactions. The Li metal precipitation at solid-solid interfaces is the primary cause of interface fluctuations and battery failures, whose formation requires a clear mechanism interpretation, especially on the key kinetic short board. Here, we introduce the lithium alloy anode as a model system to quantify the Li kinetic evolution and transition from the alloying reaction to the metal deposition in solid-state batteries, identifying that there is a carrier transition from Li atoms to Li vacancies during lithiation processes. The rate-determining step is charge transfer or Li atom diffusion at different lithiation stages.

源语言	英语
文章编号	eabi5520
期刊	Science advances
卷	7
期	38
DOI	https://doi.org/10.1126/sciadv.abi5520
出版状态	已出版 - 9月 2021
已对外发布	是

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title = "The carrier transition from Li atoms to Li vacancies in solid-state lithium alloy anodes",

abstract = "The stable cycling of energy-dense solid-state batteries is highly relied on the kinetically stable solid-state Li alloying reactions. The Li metal precipitation at solid-solid interfaces is the primary cause of interface fluctuations and battery failures, whose formation requires a clear mechanism interpretation, especially on the key kinetic short board. Here, we introduce the lithium alloy anode as a model system to quantify the Li kinetic evolution and transition from the alloying reaction to the metal deposition in solid-state batteries, identifying that there is a carrier transition from Li atoms to Li vacancies during lithiation processes. The rate-determining step is charge transfer or Li atom diffusion at different lithiation stages.",

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AU - Lu, Yang

AU - Zhao, Chen Zi

AU - Zhang, Rui

AU - Yuan, Hong

AU - Hou, Li Peng

AU - Fu, Zhong Heng

AU - Chen, Xiang

AU - Huang, Jia Qi

AU - Zhang, Qiang

N1 - Publisher Copyright: Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).

PY - 2021/9

Y1 - 2021/9

N2 - The stable cycling of energy-dense solid-state batteries is highly relied on the kinetically stable solid-state Li alloying reactions. The Li metal precipitation at solid-solid interfaces is the primary cause of interface fluctuations and battery failures, whose formation requires a clear mechanism interpretation, especially on the key kinetic short board. Here, we introduce the lithium alloy anode as a model system to quantify the Li kinetic evolution and transition from the alloying reaction to the metal deposition in solid-state batteries, identifying that there is a carrier transition from Li atoms to Li vacancies during lithiation processes. The rate-determining step is charge transfer or Li atom diffusion at different lithiation stages.

AB - The stable cycling of energy-dense solid-state batteries is highly relied on the kinetically stable solid-state Li alloying reactions. The Li metal precipitation at solid-solid interfaces is the primary cause of interface fluctuations and battery failures, whose formation requires a clear mechanism interpretation, especially on the key kinetic short board. Here, we introduce the lithium alloy anode as a model system to quantify the Li kinetic evolution and transition from the alloying reaction to the metal deposition in solid-state batteries, identifying that there is a carrier transition from Li atoms to Li vacancies during lithiation processes. The rate-determining step is charge transfer or Li atom diffusion at different lithiation stages.

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JO - Science advances

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The carrier transition from Li atoms to Li vacancies in solid-state lithium alloy anodes

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