Suppressing void formation in all-solid-state batteries: The role of interfacial adhesion on alkali metal vacancy transport

Ieuan David Seymour; Ainara Aguadero

doi:10.1039/d1ta03254b

Suppressing void formation in all-solid-state batteries: The role of interfacial adhesion on alkali metal vacancy transport

Ieuan David Seymour^*, Ainara Aguadero

^*Corresponding author for this work

Chemistry

Imperial College London

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

12 Citations (Scopus)

Abstract

All-solid-state batteries containing a solid electrolyte and a lithium (Li) or sodium (Na) metal anode are a promising solution to simultaneously increase the energy density and safety of rechargeable batteries. However, problems remain with the stripping of alkali metal from the alkali metal/solid-state electrolyte interface during discharge in which void formation and loss of contact can occur. A novel bond breaking model is developed in this work to understand the relationship between alkali metal vacancy segregation and interfacial adhesion at the alkali metal/solid-state electrolyte interface. The bond breaking approach is tested against density functional theory (DFT) calculations of pristine Li and Na metal surfaces and interfaces between Li and Na metal and model substrate structures (LiCl, Li₃OCl, LiMg, Li₂O, γ-Li₃PO₄, AlSc, NaCl and NaBr). The activation barrier for surface to subsurface vacancy diffusion was found to be considerably larger than bulk diffusion in Li and Na slabs. At the alkali metal/solid-state electrolyte interface, the preference for alkali metal vacancy segregation is shown to be intimately linked to the interfacial work of adhesion (W_ad) and alkali metal surface energy,σ_m. Suppression of alkali vacancy segregation to the interface is found to occur whenW_ad≥ 2σ_m. The role of interfacial structure on the vacancy segregation energy is demonstrated for both coherent and incoherent Li/LiCl interfaces. This work provides novel guidelines for the materials engineering of new solid-state electrolyte and interlayer materials that can suppress void formation in all-solid-state batteries with alkali metal anodes.

Original language	English
Pages (from-to)	19901-19913
Number of pages	13
Journal	Journal of Materials Chemistry A
Volume	9
Issue number	35
Early online date	9 Jun 2021
DOIs	https://doi.org/10.1039/d1ta03254b
Publication status	Published - 21 Sept 2021

Bibliographical note

Funding Information:
I. D. S. and A. A. acknowledge funding for their research from EPSRC Platform Grant EP/R002010/1. I. D. S. acknowledges the Imperial College Research Computing Service (10.14469/hpc/ 2232), and associated support services used during this work. We are grateful to the UK Materials and Molecular Modelling Hub for computational resources, which is partially funded by EPSRC (EP/P020194/1, EP/T022213/1, EP/P003532/1 and ICSF EP/R024006/1). I. D. S. and A. A. would like to thank Professor Michael Finnis, Professor Graeme Henkelman, Edouard Quérel and Dr Rowena Brugge for valuable discussions during the initial stages of this project.

Funding Information:
I. D. S. and A. A. acknowledge funding for their research from EPSRC Platform Grant EP/R002010/1. I. D. S. acknowledges the Imperial College Research Computing Service (10.14469/hpc/2232), and associated support services used during this work. We are grateful to the UK Materials and Molecular Modelling Hub for computational resources, which is partially funded by EPSRC (EP/P020194/1, EP/T022213/1, EP/P003532/1 and ICSF EP/R024006/1). I. D. S. and A. A. would like to thank Professor Michael Finnis, Professor Graeme Henkelman, Edouard Quérel and Dr Rowena Brugge for valuable discussions during the initial stages of this project.

Publisher Copyright:
© The Royal Society of Chemistry 2021.

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title = "Suppressing void formation in all-solid-state batteries: The role of interfacial adhesion on alkali metal vacancy transport",

abstract = "All-solid-state batteries containing a solid electrolyte and a lithium (Li) or sodium (Na) metal anode are a promising solution to simultaneously increase the energy density and safety of rechargeable batteries. However, problems remain with the stripping of alkali metal from the alkali metal/solid-state electrolyte interface during discharge in which void formation and loss of contact can occur. A novel bond breaking model is developed in this work to understand the relationship between alkali metal vacancy segregation and interfacial adhesion at the alkali metal/solid-state electrolyte interface. The bond breaking approach is tested against density functional theory (DFT) calculations of pristine Li and Na metal surfaces and interfaces between Li and Na metal and model substrate structures (LiCl, Li3OCl, LiMg, Li2O, γ-Li3PO4, AlSc, NaCl and NaBr). The activation barrier for surface to subsurface vacancy diffusion was found to be considerably larger than bulk diffusion in Li and Na slabs. At the alkali metal/solid-state electrolyte interface, the preference for alkali metal vacancy segregation is shown to be intimately linked to the interfacial work of adhesion (Wad) and alkali metal surface energy,σm. Suppression of alkali vacancy segregation to the interface is found to occur whenWad≥ 2σm. The role of interfacial structure on the vacancy segregation energy is demonstrated for both coherent and incoherent Li/LiCl interfaces. This work provides novel guidelines for the materials engineering of new solid-state electrolyte and interlayer materials that can suppress void formation in all-solid-state batteries with alkali metal anodes.",

author = "Seymour, {Ieuan David} and Ainara Aguadero",

note = "Funding Information: I. D. S. and A. A. acknowledge funding for their research from EPSRC Platform Grant EP/R002010/1. I. D. S. acknowledges the Imperial College Research Computing Service (10.14469/hpc/ 2232), and associated support services used during this work. We are grateful to the UK Materials and Molecular Modelling Hub for computational resources, which is partially funded by EPSRC (EP/P020194/1, EP/T022213/1, EP/P003532/1 and ICSF EP/R024006/1). I. D. S. and A. A. would like to thank Professor Michael Finnis, Professor Graeme Henkelman, Edouard Qu{\'e}rel and Dr Rowena Brugge for valuable discussions during the initial stages of this project. Funding Information: I. D. S. and A. A. acknowledge funding for their research from EPSRC Platform Grant EP/R002010/1. I. D. S. acknowledges the Imperial College Research Computing Service (10.14469/hpc/2232), and associated support services used during this work. We are grateful to the UK Materials and Molecular Modelling Hub for computational resources, which is partially funded by EPSRC (EP/P020194/1, EP/T022213/1, EP/P003532/1 and ICSF EP/R024006/1). I. D. S. and A. A. would like to thank Professor Michael Finnis, Professor Graeme Henkelman, Edouard Qu{\'e}rel and Dr Rowena Brugge for valuable discussions during the initial stages of this project. Publisher Copyright: {\textcopyright} The Royal Society of Chemistry 2021.",

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N2 - All-solid-state batteries containing a solid electrolyte and a lithium (Li) or sodium (Na) metal anode are a promising solution to simultaneously increase the energy density and safety of rechargeable batteries. However, problems remain with the stripping of alkali metal from the alkali metal/solid-state electrolyte interface during discharge in which void formation and loss of contact can occur. A novel bond breaking model is developed in this work to understand the relationship between alkali metal vacancy segregation and interfacial adhesion at the alkali metal/solid-state electrolyte interface. The bond breaking approach is tested against density functional theory (DFT) calculations of pristine Li and Na metal surfaces and interfaces between Li and Na metal and model substrate structures (LiCl, Li3OCl, LiMg, Li2O, γ-Li3PO4, AlSc, NaCl and NaBr). The activation barrier for surface to subsurface vacancy diffusion was found to be considerably larger than bulk diffusion in Li and Na slabs. At the alkali metal/solid-state electrolyte interface, the preference for alkali metal vacancy segregation is shown to be intimately linked to the interfacial work of adhesion (Wad) and alkali metal surface energy,σm. Suppression of alkali vacancy segregation to the interface is found to occur whenWad≥ 2σm. The role of interfacial structure on the vacancy segregation energy is demonstrated for both coherent and incoherent Li/LiCl interfaces. This work provides novel guidelines for the materials engineering of new solid-state electrolyte and interlayer materials that can suppress void formation in all-solid-state batteries with alkali metal anodes.

AB - All-solid-state batteries containing a solid electrolyte and a lithium (Li) or sodium (Na) metal anode are a promising solution to simultaneously increase the energy density and safety of rechargeable batteries. However, problems remain with the stripping of alkali metal from the alkali metal/solid-state electrolyte interface during discharge in which void formation and loss of contact can occur. A novel bond breaking model is developed in this work to understand the relationship between alkali metal vacancy segregation and interfacial adhesion at the alkali metal/solid-state electrolyte interface. The bond breaking approach is tested against density functional theory (DFT) calculations of pristine Li and Na metal surfaces and interfaces between Li and Na metal and model substrate structures (LiCl, Li3OCl, LiMg, Li2O, γ-Li3PO4, AlSc, NaCl and NaBr). The activation barrier for surface to subsurface vacancy diffusion was found to be considerably larger than bulk diffusion in Li and Na slabs. At the alkali metal/solid-state electrolyte interface, the preference for alkali metal vacancy segregation is shown to be intimately linked to the interfacial work of adhesion (Wad) and alkali metal surface energy,σm. Suppression of alkali vacancy segregation to the interface is found to occur whenWad≥ 2σm. The role of interfacial structure on the vacancy segregation energy is demonstrated for both coherent and incoherent Li/LiCl interfaces. This work provides novel guidelines for the materials engineering of new solid-state electrolyte and interlayer materials that can suppress void formation in all-solid-state batteries with alkali metal anodes.

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Suppressing void formation in all-solid-state batteries: The role of interfacial adhesion on alkali metal vacancy transport

Abstract

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