Issue 41, 2017

Theoretical design of solid electrolytes with superb ionic conductivity: alloying effect on Li+ transportation in cubic Li6PA5X chalcogenides

Abstract

It is of great importance to develop solid inorganic electrolytes with high ionic conductivity, which would thus enable solid-state Li-ion batteries to overcome the notorious safety issues with the current technology due to the use of highly flammable liquid organic electrolytes. On the basis of systematic first-principles modelling, we have formulated new inorganic electrolytes with ultra-low activation energies for the long-distance diffusion of Li+ ions by alloying cubic argyrodite Li6PA5X chalcogenides (A = chalcogen; X = halogen). We found that the long-distance transportation of Li+ ions is dictated by inter-octahedral diffusion, as the activation energy required for Li+ ions to migrate over an Li6A octahedron is minimal. The inter-octahedral diffusion barrier for Li+ ions is largely dependent on their interaction with chalcogen anions in the compound. A radical reduction of the diffusion barrier for Li+ ions can be realized through isovalent substitution of S using elements of lower electronegativity, together with smaller halogen ions at X sites.

Graphical abstract: Theoretical design of solid electrolytes with superb ionic conductivity: alloying effect on Li+ transportation in cubic Li6PA5X chalcogenides

Supplementary files

Article information

Article type
Paper
Submitted
08 Aug 2017
Accepted
26 Sep 2017
First published
26 Sep 2017

J. Mater. Chem. A, 2017,5, 21846-21857

Theoretical design of solid electrolytes with superb ionic conductivity: alloying effect on Li+ transportation in cubic Li6PA5X chalcogenides

Z. Wang and G. Shao, J. Mater. Chem. A, 2017, 5, 21846 DOI: 10.1039/C7TA06986C

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