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Field-Dependent Ionic Conductivities from Generalized Fluctuation-Dissipation Relations

Dominika Lesnicki, Chloe Y. Gao, Benjamin Rotenberg, David T. Limmer

2020Physical Review Letters27 citationsDOIOpen Access PDF

Abstract

We derive a relationship for the electric field dependent ionic conductivity in terms of fluctuations of time integrated microscopic variables. We demonstrate this formalism with molecular dynamics simulations of solutions of differing ionic strength with implicit solvent conditions and molten salts. These calculations are aided by a novel nonequilibrium statistical reweighting scheme that allows for the conductivity to be computed as a continuous function of the applied field. In strong electrolytes, we find the fluctuations of the ionic current are Gaussian, and subsequently, the conductivity is constant with applied field. In weaker electrolytes and molten salts, we find the fluctuations of the ionic current are strongly non-Gaussian, and the conductivity increases with applied field. This nonlinear behavior, known phenomenologically for dilute electrolytes as the Onsager-Wien effect, is general and results from the suppression of ionic correlations at large applied fields, as we elucidate through both dynamic and static correlations within nonequilibrium steady states.

Topics & Concepts

DissipationField (mathematics)Ionic bondingStatistical physicsPhysicsCondensed matter physicsIonQuantum mechanicsMathematicsPure mathematicsAdvanced Thermodynamics and Statistical MechanicsThermal properties of materialsQuantum and electron transport phenomena