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 language | English |
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Pages (from-to) | 21210-21219 |
Number of pages | 10 |
Journal | Journal of the American Chemical Society |
Volume | 142 |
Issue number | 50 |
DOIs | |
State | Published - Dec 16 2020 |
Externally published | Yes |
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
Funders | Funder number |
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Alexander von Humboldt-Stiftung | |
Faraday Institution | EP/S003053/1, FIRG003 |
Faraday Institution | |
Engineering and Physical Sciences Research Council | |
Royal Society | URF\R\191006, UF130329 |
Royal Society | |
Met Office | EP/R029431, EP/P020224/1, EP/L000202 |
Met Office |