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Abstract
The electric double layer (EDL) – arguably the central concept in electrochemistry – remains the nut everyone wants to crack to tune its properties and, thus, control the performance of electrochemical devices. One such property is the differential capacitance that determines the energy density in supercapacitors. In this communication, we show that the capacitance–potential dependence can be fitted with a four-parameter model for ionic liquid–electrode interfaces, where steric packing naturally results in a power-law scaling. First, we demonstrate how these parameters can be evaluated and used to interpret the EDL structure and properties. Second, we demonstrate how the model enables predictions of both differential capacitance and energy density.
Supplementary materials
Title
Supporting Information of Ionic Liquid–Electrode Interface: from One Law to Fit Them All to One Model to Predict Them All
Description
Derivation of Eq. 3, Description of Simulation method, Effect of potential correction, supplementary fitting data, application of the model to experimental data.
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Repository for data and code
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Data for reproducing article's figures
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