Dendrite initiation and propagation in lithium metal solid-state batteries

Ziyang Ning; Guanchen Li; Dominic L.R. Melvin; Yang Chen; Junfu Bu; Dominic Spencer-Jolly; Junliang Liu; Bingkun Hu; Xiangwen Gao; Johann Perera; Chen Gong; Shengda D. Pu; Shengming Zhang; Boyang Liu; Gareth O. Hartley; Andrew J. Bodey; Richard I. Todd; Patrick S. Grant; David E. J. Armstrong; T. James Marrow; Charles W. Monroe; Peter G. Bruce

doi:10.1038/s41586-023-05970-4

Dendrite initiation and propagation in lithium metal solid-state batteries

Ziyang Ning, Guanchen Li, Dominic L.R. Melvin, Yang Chen, Junfu Bu, Dominic Spencer-Jolly, Junliang Liu, Bingkun Hu, Xiangwen Gao, Johann Perera, Chen Gong, Shengda D. Pu, Shengming Zhang, Boyang Liu, Gareth O. Hartley, Andrew J. Bodey, Richard I. Todd, Patrick S. Grant, David E. J. Armstrong, T. James Marrow^*Charles W. Monroe^*, Peter G. Bruce^*

^*Corresponding author for this work

Metallurgy and Materials

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

Abstract

All-solid-state batteries with a Li anode and ceramic electrolyte have the potential to deliver a step change in performance compared with today’s Li-ion batteries^1,2. However, Li dendrites (filaments) form on charging at practical rates and penetrate the ceramic electrolyte, leading to short circuit and cell failure^3,4. Previous models of dendrite penetration have generally focused on a single process for dendrite initiation and propagation, with Li driving the crack at its tip^5–9. Here we show that initiation and propagation are separate processes. Initiation arises from Li deposition into subsurface pores, by means of microcracks that connect the pores to the surface. Once filled, further charging builds pressure in the pores owing to the slow extrusion of Li (viscoplastic flow) back to the surface, leading to cracking. By contrast, dendrite propagation occurs by wedge opening, with Li driving the dry crack from the rear, not the tip. Whereas initiation is determined by the local (microscopic) fracture strength at the grain boundaries, the pore size, pore population density and current density, propagation depends on the (macroscopic) fracture toughness of the ceramic, the length of the Li dendrite (filament) that partially occupies the dry crack, current density, stack pressure and the charge capacity accessed during each cycle. Lower stack pressures suppress propagation, markedly extending the number of cycles before short circuit in cells in which dendrites have initiated.

Original language	English
Pages (from-to)	287-293
Number of pages	7
Journal	Nature
Volume	618
Issue number	7964
Early online date	7 Jun 2023
DOIs	https://doi.org/10.1038/s41586-023-05970-4
Publication status	Published - 8 Jun 2023

Bibliographical note

Funding Information:
P.G.B. is indebted to the Faraday Institution SOLBAT (FIRG007, FIRG008, FIRG026), as well as the Engineering and Physical Sciences Research Council, Enabling Next Generation Lithium Batteries (EP/M009521/1), the University of Oxford experimental equipment upgrade (EP/M02833X/1) and the Henry Royce Institute for Advanced Materials (EP/R0066X/1, EP/S019367/1, EP/R010145/1) for financial support. We thank the Diamond Light Source for the provision of synchrotron radiation beam time (experiment no. MG23980-1) at the I13-2 beamline at the Diamond Light Source. We acknowledge technical and experimental support at the I13-2 beamline by A. J. Bodey.

Publisher Copyright:
© 2023, The Author(s), under exclusive licence to Springer Nature Limited.

ASJC Scopus subject areas

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10.1038/s41586-023-05970-4

Cite this

Ning, Z., Li, G., Melvin, D. L. R., Chen, Y., Bu, J., Spencer-Jolly, D., Liu, J., Hu, B., Gao, X., Perera, J., Gong, C., Pu, S. D., Zhang, S., Liu, B., Hartley, G. O., Bodey, A. J., Todd, R. I., Grant, P. S., Armstrong, D. E. J., ... Bruce, P. G. (2023). Dendrite initiation and propagation in lithium metal solid-state batteries. Nature, 618(7964), 287-293. https://doi.org/10.1038/s41586-023-05970-4

@article{612ff9c8ba1a4821a3c12d8fc2ca59e1,

title = "Dendrite initiation and propagation in lithium metal solid-state batteries",

abstract = "All-solid-state batteries with a Li anode and ceramic electrolyte have the potential to deliver a step change in performance compared with today{\textquoteright}s Li-ion batteries 1,2. However, Li dendrites (filaments) form on charging at practical rates and penetrate the ceramic electrolyte, leading to short circuit and cell failure 3,4. Previous models of dendrite penetration have generally focused on a single process for dendrite initiation and propagation, with Li driving the crack at its tip 5–9. Here we show that initiation and propagation are separate processes. Initiation arises from Li deposition into subsurface pores, by means of microcracks that connect the pores to the surface. Once filled, further charging builds pressure in the pores owing to the slow extrusion of Li (viscoplastic flow) back to the surface, leading to cracking. By contrast, dendrite propagation occurs by wedge opening, with Li driving the dry crack from the rear, not the tip. Whereas initiation is determined by the local (microscopic) fracture strength at the grain boundaries, the pore size, pore population density and current density, propagation depends on the (macroscopic) fracture toughness of the ceramic, the length of the Li dendrite (filament) that partially occupies the dry crack, current density, stack pressure and the charge capacity accessed during each cycle. Lower stack pressures suppress propagation, markedly extending the number of cycles before short circuit in cells in which dendrites have initiated.",

author = "Ziyang Ning and Guanchen Li and Melvin, {Dominic L.R.} and Yang Chen and Junfu Bu and Dominic Spencer-Jolly and Junliang Liu and Bingkun Hu and Xiangwen Gao and Johann Perera and Chen Gong and Pu, {Shengda D.} and Shengming Zhang and Boyang Liu and Hartley, {Gareth O.} and Bodey, {Andrew J.} and Todd, {Richard I.} and Grant, {Patrick S.} and Armstrong, {David E. J.} and Marrow, {T. James} and Monroe, {Charles W.} and Bruce, {Peter G.}",

note = "Funding Information: P.G.B. is indebted to the Faraday Institution SOLBAT (FIRG007, FIRG008, FIRG026), as well as the Engineering and Physical Sciences Research Council, Enabling Next Generation Lithium Batteries (EP/M009521/1), the University of Oxford experimental equipment upgrade (EP/M02833X/1) and the Henry Royce Institute for Advanced Materials (EP/R0066X/1, EP/S019367/1, EP/R010145/1) for financial support. We thank the Diamond Light Source for the provision of synchrotron radiation beam time (experiment no. MG23980-1) at the I13-2 beamline at the Diamond Light Source. We acknowledge technical and experimental support at the I13-2 beamline by A. J. Bodey. Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive licence to Springer Nature Limited.",

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Ning, Z, Li, G, Melvin, DLR, Chen, Y, Bu, J, Spencer-Jolly, D, Liu, J, Hu, B, Gao, X, Perera, J, Gong, C, Pu, SD, Zhang, S, Liu, B, Hartley, GO, Bodey, AJ, Todd, RI, Grant, PS, Armstrong, DEJ, Marrow, TJ, Monroe, CW & Bruce, PG 2023, 'Dendrite initiation and propagation in lithium metal solid-state batteries', Nature, vol. 618, no. 7964, pp. 287-293. https://doi.org/10.1038/s41586-023-05970-4

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T1 - Dendrite initiation and propagation in lithium metal solid-state batteries

AU - Ning, Ziyang

AU - Li, Guanchen

AU - Melvin, Dominic L.R.

AU - Chen, Yang

AU - Bu, Junfu

AU - Spencer-Jolly, Dominic

AU - Liu, Junliang

AU - Hu, Bingkun

AU - Gao, Xiangwen

AU - Perera, Johann

AU - Gong, Chen

AU - Pu, Shengda D.

AU - Zhang, Shengming

AU - Liu, Boyang

AU - Hartley, Gareth O.

AU - Bodey, Andrew J.

AU - Todd, Richard I.

AU - Grant, Patrick S.

AU - Armstrong, David E. J.

AU - Marrow, T. James

AU - Monroe, Charles W.

AU - Bruce, Peter G.

N1 - Funding Information: P.G.B. is indebted to the Faraday Institution SOLBAT (FIRG007, FIRG008, FIRG026), as well as the Engineering and Physical Sciences Research Council, Enabling Next Generation Lithium Batteries (EP/M009521/1), the University of Oxford experimental equipment upgrade (EP/M02833X/1) and the Henry Royce Institute for Advanced Materials (EP/R0066X/1, EP/S019367/1, EP/R010145/1) for financial support. We thank the Diamond Light Source for the provision of synchrotron radiation beam time (experiment no. MG23980-1) at the I13-2 beamline at the Diamond Light Source. We acknowledge technical and experimental support at the I13-2 beamline by A. J. Bodey. Publisher Copyright: © 2023, The Author(s), under exclusive licence to Springer Nature Limited.

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Y1 - 2023/6/8

N2 - All-solid-state batteries with a Li anode and ceramic electrolyte have the potential to deliver a step change in performance compared with today’s Li-ion batteries 1,2. However, Li dendrites (filaments) form on charging at practical rates and penetrate the ceramic electrolyte, leading to short circuit and cell failure 3,4. Previous models of dendrite penetration have generally focused on a single process for dendrite initiation and propagation, with Li driving the crack at its tip 5–9. Here we show that initiation and propagation are separate processes. Initiation arises from Li deposition into subsurface pores, by means of microcracks that connect the pores to the surface. Once filled, further charging builds pressure in the pores owing to the slow extrusion of Li (viscoplastic flow) back to the surface, leading to cracking. By contrast, dendrite propagation occurs by wedge opening, with Li driving the dry crack from the rear, not the tip. Whereas initiation is determined by the local (microscopic) fracture strength at the grain boundaries, the pore size, pore population density and current density, propagation depends on the (macroscopic) fracture toughness of the ceramic, the length of the Li dendrite (filament) that partially occupies the dry crack, current density, stack pressure and the charge capacity accessed during each cycle. Lower stack pressures suppress propagation, markedly extending the number of cycles before short circuit in cells in which dendrites have initiated.

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Dendrite initiation and propagation in lithium metal solid-state batteries

Abstract

Bibliographical note

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