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Local Volume Conservation in Concentrated Electrolytes Is Governing Charge Transport in Electric Fields

Martin Lorenz, Franziska Kilchert, Pinchas Nürnberg, Max Schammer, Arnulf Latz, Birger Horstmann, Monika Schönhoff

2022The Journal of Physical Chemistry Letters44 citationsDOI

Abstract

While ion transport processes in concentrated electrolytes, e.g., based on ionic liquids (IL), are a subject of intense research, the role of conservation laws and reference frames is still a matter of debate. Employing electrophoretic NMR, we show that momentum conservation, a typical prerequisite in molecular dynamics (MD) simulations, is not governing ion transport. Involving density measurements to determine molar volumes of distinct ion species, we propose that conservation of local molar species volumes is the governing constraint for ion transport. The experimentally quantified net volume flux is found to be zero, implying a nonzero local momentum flux, as tested in pure ILs and IL-based electrolytes for a broad variety of concentrations and chemical compositions. This constraint is consistent with incompressibility, but not with a local application of momentum conservation. The constraint affects the calculation of transference numbers as well as comparisons of MD results to experimental findings.

Topics & Concepts

ElectrolyteCharge conservationConstraint (computer-aided design)Momentum (technical analysis)Conservation lawIonFlux (metallurgy)Chemical physicsIonic bondingElectric fieldIon transporterChemistryPhysicsCharge (physics)MathematicsPhysical chemistryGeometryElectrodeOrganic chemistryFinanceQuantum mechanicsEconomicsAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies ResearchNMR spectroscopy and applications