Evidence for a Solid-Electrolyte Inductive Effect in the Superionic Conductor Li10Ge1-xSnxP2S12

Sean P. Culver, Alexander G. Squires, Nicolò Minafra, Callum W.F. Armstrong, Thorben Krauskopf, Felix Böcher, Cheng Li, Benjamin J. Morgan, Wolfgang G. Zeier

Research output: Contribution to journalArticlepeer-review

51 Scopus citations

Abstract

Strategies to enhance ionic conductivities in solid electrolytes typically focus on the effects of modifying their crystal structures or of tuning mobile-ion stoichiometries. A less-explored approach is to modulate the chemical bonding interactions within a material to promote fast lithium-ion diffusion. Recently, the idea of a solid-electrolyte inductive effect has been proposed, whereby changes in bonding within the solid-electrolyte host framework modify the potential energy landscape for the mobile ions, resulting in an enhanced ionic conductivity. Direct evidence for a solid-electrolyte inductive effect, however, is lacking - in part because of the challenge of quantifying changes in local bonding interactions within a solid-electrolyte host framework. Here, we consider the evidence for a solid-electrolyte inductive effect in the archetypal superionic lithium-ion conductor Li10Ge1-xSnxP2S12. Substituting Ge for Sn weakens the {Ge,Sn}-S bonding interactions and increases the charge density associated with the S2- ions. This charge redistribution modifies the Li+ substructure causing Li+ ions to bind more strongly to the host framework S2- anions, which in turn modulates the Li+ ion potential energy surface, increasing local barriers for Li+ ion diffusion. Each of these effects is consistent with the predictions of the solid-electrolyte inductive effect model. Density functional theory calculations predict that this inductive effect occurs even in the absence of changes to the host framework geometry due to Ge → Sn substitution. These results provide direct evidence in support of a measurable solid-electrolyte inductive effect and demonstrate its application as a practical strategy for tuning ionic conductivities in superionic lithium-ion conductors.

Original languageEnglish
Pages (from-to)21210-21219
Number of pages10
JournalJournal of the American Chemical Society
Volume142
Issue number50
DOIs
StatePublished - Dec 16 2020
Externally publishedYes

Funding

A.G.S. acknowledges EPSRC for PhD funding, B.J.M. acknowledges support from the Royal Society (Grants UF130329 and URF\R\191006). The theoretical work was supported by funding from the Faraday Institution ( faraday.ac.uk ) (EP/S003053/1), Grant FIRG003. Calculations were performed using the Balena High Performance Computing Service at the University of Bath, the Isambard UK National Tier-2 HPC Service ( http://gw4.ac.uk/isambard/ ) operated by GW4, and the UK Met Office and funded by EPSRC (EP/P020224/1) and the ARCHER supercomputer, through membership of the UK’s HPC Materials Chemistry Consortium, funded by EPSRC Grants EP/L000202 and EP/R029431. This research used resources at the Spallation Neutron Source, as appropriate, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. S.C. gratefully acknowledges the Alexander von Humboldt Foundation for financial support through a Postdoctoral Fellowship. The authors thank Ashfia Huq (Oak Ridge National Laboratory) for the support during the acquisition of the neutron diffraction data. a

FundersFunder number
Alexander von Humboldt-Stiftung
Faraday InstitutionEP/S003053/1, FIRG003
Faraday Institution
Engineering and Physical Sciences Research Council
Royal SocietyURF\R\191006, UF130329
Royal Society
Met OfficeEP/R029431, EP/P020224/1, EP/L000202
Met Office

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