LiH formation and its impact on Li batteries revealed by cryogenic electron microscopy

Rafael A. Vilá; David T. Boyle; Alan Dai; Wenbo Zhang; Philaphon Sayavong; Yusheng Ye; Yufei Yang; Jennifer A. Dionne; Yi Cui

doi:10.1126/sciadv.adf3609

LiH formation and its impact on Li batteries revealed by cryogenic electron microscopy

Rafael A. Vilá, David T. Boyle, Alan Dai, Wenbo Zhang, Philaphon Sayavong, Yusheng Ye, Yufei Yang, Jennifer A. Dionne, Yi Cui^*

^*Corresponding author for this work

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

38 Citations (Scopus)

Abstract

Little is known about howevolved hydrogen affects the cycling of Li batteries. Hypotheses include the formation of LiH in the solid-electrolyte interphase (SEI) and dendritic growth of LiH. Here, we discover that LiH formation in Li batteries likely follows a different pathway: Hydrogen evolved during cycling reacts to nucleate and grow LiH within already deposited Li metal, consuming active Li. We provide the evidence that LiH formed in Li batteries electrically isolates active Li from the current collector that degrades battery capacity. We detect the coexistence of Li metal and LiH also on graphite and silicon anodes, showing that LiH forms in most Li battery anode chemistries. Last, we find that LiH has its own SEI layer that is chemically and structurally distinct from the SEI on Li metal. Our results highlight the formation mechanism and chemical origins of LiH, providing critical insight into how to prevent its formation.

Original language	English
Article number	eadf3609
Journal	Science advances
Volume	9
Issue number	12
DOIs	https://doi.org/10.1126/sciadv.adf3609
Publication status	Published - Mar 2023
Externally published	Yes

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title = "LiH formation and its impact on Li batteries revealed by cryogenic electron microscopy",

abstract = "Little is known about howevolved hydrogen affects the cycling of Li batteries. Hypotheses include the formation of LiH in the solid-electrolyte interphase (SEI) and dendritic growth of LiH. Here, we discover that LiH formation in Li batteries likely follows a different pathway: Hydrogen evolved during cycling reacts to nucleate and grow LiH within already deposited Li metal, consuming active Li. We provide the evidence that LiH formed in Li batteries electrically isolates active Li from the current collector that degrades battery capacity. We detect the coexistence of Li metal and LiH also on graphite and silicon anodes, showing that LiH forms in most Li battery anode chemistries. Last, we find that LiH has its own SEI layer that is chemically and structurally distinct from the SEI on Li metal. Our results highlight the formation mechanism and chemical origins of LiH, providing critical insight into how to prevent its formation.",

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doi = "10.1126/sciadv.adf3609",

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T1 - LiH formation and its impact on Li batteries revealed by cryogenic electron microscopy

AU - Vilá, Rafael A.

AU - Boyle, David T.

AU - Dai, Alan

AU - Zhang, Wenbo

AU - Sayavong, Philaphon

AU - Ye, Yusheng

AU - Yang, Yufei

AU - Dionne, Jennifer A.

AU - Cui, Yi

PY - 2023/3

Y1 - 2023/3

N2 - Little is known about howevolved hydrogen affects the cycling of Li batteries. Hypotheses include the formation of LiH in the solid-electrolyte interphase (SEI) and dendritic growth of LiH. Here, we discover that LiH formation in Li batteries likely follows a different pathway: Hydrogen evolved during cycling reacts to nucleate and grow LiH within already deposited Li metal, consuming active Li. We provide the evidence that LiH formed in Li batteries electrically isolates active Li from the current collector that degrades battery capacity. We detect the coexistence of Li metal and LiH also on graphite and silicon anodes, showing that LiH forms in most Li battery anode chemistries. Last, we find that LiH has its own SEI layer that is chemically and structurally distinct from the SEI on Li metal. Our results highlight the formation mechanism and chemical origins of LiH, providing critical insight into how to prevent its formation.

AB - Little is known about howevolved hydrogen affects the cycling of Li batteries. Hypotheses include the formation of LiH in the solid-electrolyte interphase (SEI) and dendritic growth of LiH. Here, we discover that LiH formation in Li batteries likely follows a different pathway: Hydrogen evolved during cycling reacts to nucleate and grow LiH within already deposited Li metal, consuming active Li. We provide the evidence that LiH formed in Li batteries electrically isolates active Li from the current collector that degrades battery capacity. We detect the coexistence of Li metal and LiH also on graphite and silicon anodes, showing that LiH forms in most Li battery anode chemistries. Last, we find that LiH has its own SEI layer that is chemically and structurally distinct from the SEI on Li metal. Our results highlight the formation mechanism and chemical origins of LiH, providing critical insight into how to prevent its formation.

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LiH formation and its impact on Li batteries revealed by cryogenic electron microscopy

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