Linking void and interphase evolution to electrochemistry in solid-state batteries using operando X-ray tomography

John A. Lewis; Francisco Javier Quintero Cortes; Yuhgene Liu; John C. Miers; Ankit Verma; Bairav S. Vishnugopi; Jared Tippens; Dhruv Prakash; Thomas S. Marchese; Sang Yun Han; Chanhee Lee; Pralav P. Shetty; Hyun Wook Lee; Pavel Shevchenko; Francesco De Carlo; Christopher Saldana; Partha P. Mukherjee; Matthew T. McDowell

doi:10.1038/s41563-020-00903-2

Linking void and interphase evolution to electrochemistry in solid-state batteries using operando X-ray tomography

John A. Lewis
, Francisco Javier Quintero Cortes
, Yuhgene Liu
, John C. Miers
, Ankit Verma
, Bairav S. Vishnugopi
, Jared Tippens
, Dhruv Prakash
, Thomas S. Marchese
, Sang Yun Han
, Chanhee Lee
, Pralav P. Shetty
, Hyun Wook Lee
, Pavel Shevchenko
, Francesco De Carlo
, Christopher Saldana
, Partha P. Mukherjee
, Matthew T. McDowell

Georgia Institute of Technology
Purdue University
Ulsan National Institute of Science and Technology
United States Department of Energy

Research output: Contribution to journal › Article › peer-review

366 Scopus citations

Abstract

Despite progress in solid-state battery engineering, our understanding of the chemo-mechanical phenomena that govern electrochemical behaviour and stability at solid–solid interfaces remains limited compared to at solid–liquid interfaces. Here, we use operando synchrotron X-ray computed microtomography to investigate the evolution of lithium/solid-state electrolyte interfaces during battery cycling, revealing how the complex interplay among void formation, interphase growth and volumetric changes determines cell behaviour. Void formation during lithium stripping is directly visualized in symmetric cells, and the loss of contact that drives current constriction at the interface between lithium and the solid-state electrolyte (Li₁₀SnP₂S₁₂) is quantified and found to be the primary cause of cell failure. The interphase is found to be redox-active upon charge, and global volume changes occur owing to partial molar volume mismatches at either electrode. These results provide insight into how chemo-mechanical phenomena can affect cell performance, thus facilitating the development of solid-state batteries.

Original language	English
Pages (from-to)	503-510
Number of pages	8
Journal	Nature Materials
Volume	20
Issue number	4
DOIs	https://doi.org/10.1038/s41563-020-00903-2
State	Published - Apr 2021
Externally published	Yes

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Lewis, J. A., Cortes, F. J. Q., Liu, Y., Miers, J. C., Verma, A., Vishnugopi, B. S., Tippens, J., Prakash, D., Marchese, T. S., Han, S. Y., Lee, C., Shetty, P. P., Lee, H. W., Shevchenko, P., De Carlo, F., Saldana, C., Mukherjee, P. P., & McDowell, M. T. (2021). Linking void and interphase evolution to electrochemistry in solid-state batteries using operando X-ray tomography. Nature Materials, 20(4), 503-510. https://doi.org/10.1038/s41563-020-00903-2

@article{8d6175af022446faa25d68def84d59aa,

title = "Linking void and interphase evolution to electrochemistry in solid-state batteries using operando X-ray tomography",

abstract = "Despite progress in solid-state battery engineering, our understanding of the chemo-mechanical phenomena that govern electrochemical behaviour and stability at solid–solid interfaces remains limited compared to at solid–liquid interfaces. Here, we use operando synchrotron X-ray computed microtomography to investigate the evolution of lithium/solid-state electrolyte interfaces during battery cycling, revealing how the complex interplay among void formation, interphase growth and volumetric changes determines cell behaviour. Void formation during lithium stripping is directly visualized in symmetric cells, and the loss of contact that drives current constriction at the interface between lithium and the solid-state electrolyte (Li10SnP2S12) is quantified and found to be the primary cause of cell failure. The interphase is found to be redox-active upon charge, and global volume changes occur owing to partial molar volume mismatches at either electrode. These results provide insight into how chemo-mechanical phenomena can affect cell performance, thus facilitating the development of solid-state batteries.",

author = "Lewis, \{John A.\} and Cortes, \{Francisco Javier Quintero\} and Yuhgene Liu and Miers, \{John C.\} and Ankit Verma and Vishnugopi, \{Bairav S.\} and Jared Tippens and Dhruv Prakash and Marchese, \{Thomas S.\} and Han, \{Sang Yun\} and Chanhee Lee and Shetty, \{Pralav P.\} and Lee, \{Hyun Wook\} and Pavel Shevchenko and \{De Carlo\}, Francesco and Christopher Saldana and Mukherjee, \{Partha P.\} and McDowell, \{Matthew T.\}",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2021",

month = apr,

doi = "10.1038/s41563-020-00903-2",

language = "English",

volume = "20",

pages = "503--510",

journal = "Nature Materials",

issn = "1476-1122",

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Lewis, JA, Cortes, FJQ, Liu, Y, Miers, JC, Verma, A, Vishnugopi, BS, Tippens, J, Prakash, D, Marchese, TS, Han, SY, Lee, C, Shetty, PP, Lee, HW, Shevchenko, P, De Carlo, F, Saldana, C, Mukherjee, PP & McDowell, MT 2021, 'Linking void and interphase evolution to electrochemistry in solid-state batteries using operando X-ray tomography', Nature Materials, vol. 20, no. 4, pp. 503-510. https://doi.org/10.1038/s41563-020-00903-2

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T1 - Linking void and interphase evolution to electrochemistry in solid-state batteries using operando X-ray tomography

AU - Lewis, John A.

AU - Cortes, Francisco Javier Quintero

AU - Liu, Yuhgene

AU - Miers, John C.

AU - Verma, Ankit

AU - Vishnugopi, Bairav S.

AU - Tippens, Jared

AU - Prakash, Dhruv

AU - Marchese, Thomas S.

AU - Han, Sang Yun

AU - Lee, Chanhee

AU - Shetty, Pralav P.

AU - Lee, Hyun Wook

AU - Shevchenko, Pavel

AU - De Carlo, Francesco

AU - Saldana, Christopher

AU - Mukherjee, Partha P.

AU - McDowell, Matthew T.

PY - 2021/4

Y1 - 2021/4

N2 - Despite progress in solid-state battery engineering, our understanding of the chemo-mechanical phenomena that govern electrochemical behaviour and stability at solid–solid interfaces remains limited compared to at solid–liquid interfaces. Here, we use operando synchrotron X-ray computed microtomography to investigate the evolution of lithium/solid-state electrolyte interfaces during battery cycling, revealing how the complex interplay among void formation, interphase growth and volumetric changes determines cell behaviour. Void formation during lithium stripping is directly visualized in symmetric cells, and the loss of contact that drives current constriction at the interface between lithium and the solid-state electrolyte (Li10SnP2S12) is quantified and found to be the primary cause of cell failure. The interphase is found to be redox-active upon charge, and global volume changes occur owing to partial molar volume mismatches at either electrode. These results provide insight into how chemo-mechanical phenomena can affect cell performance, thus facilitating the development of solid-state batteries.

AB - Despite progress in solid-state battery engineering, our understanding of the chemo-mechanical phenomena that govern electrochemical behaviour and stability at solid–solid interfaces remains limited compared to at solid–liquid interfaces. Here, we use operando synchrotron X-ray computed microtomography to investigate the evolution of lithium/solid-state electrolyte interfaces during battery cycling, revealing how the complex interplay among void formation, interphase growth and volumetric changes determines cell behaviour. Void formation during lithium stripping is directly visualized in symmetric cells, and the loss of contact that drives current constriction at the interface between lithium and the solid-state electrolyte (Li10SnP2S12) is quantified and found to be the primary cause of cell failure. The interphase is found to be redox-active upon charge, and global volume changes occur owing to partial molar volume mismatches at either electrode. These results provide insight into how chemo-mechanical phenomena can affect cell performance, thus facilitating the development of solid-state batteries.

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VL - 20

SP - 503

EP - 510

JO - Nature Materials

JF - Nature Materials

IS - 4

ER -

Linking void and interphase evolution to electrochemistry in solid-state batteries using operando X-ray tomography

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