Lattice-mediated Geometric Frustration Drives Fast Ionic Transport

Abstract

Fast ionic conductors are commonly described from two perspectives: soft lattices that facilitate ion migration, and geometrically frustrated ionic sublattices that host multiple nearly degenerate configurations. Here we demonstrate that these two pictures are intrinsically linked within a single lattice-renormalized free-energy landscape. Eliminating the adiabatic lattice response from a coupled ion-lattice Hamiltonian, we derive a lattice-mediated free-energy correction governed by the projection of ionic configurational forces onto the inverse stiffness of the host lattice. In a coarse-grained representation, this correction decomposes into local self-trapping and non-local interference between lattice-response fields. These intertwined effects reshape the frustrated free-energy landscape, redistribute mobile ions, and promote correlated ionic transport. Large-scale atomistic simulations of cubic Li7La3Zr2O12 and AgCrSe2 show these effects across scales, from barrier reduction to collective ionic reorganization. The resulting picture recasts fast ionic transport as a lattice-renormalized geometric frustration problem, in which lattice softness, frustration and collective diffusion emerge as different expressions of the same free-energy landscape.