Abstract
Development of Li+-containing electrolytes with improved transport properties requires reliable, reproducible, and ideally low volume techniques to rigorously understand ion-transport with varying composition. Precisely measuring the complete set of transport coefficients in liquid electrolytes under battery-relevant operating conditions is difficult and the reliability of these methods are sparsely described in electrolyte transport literature. In this work, we apply a potentiostatic polarization-based transport characterization approach typically used for polymer electrolytes to liquid electrolyte systems in an attempt to fully measure all transport coefficients (conductivity, total salt diffusion coefficient, thermodynamic factor and transference number) for the model system of LiPF6 in an ethylene carbonate—ethyl methyl carbonate (EC:EMC) mixture. Using systematic timescale and statistical analyses, we find that transport coefficients measured using potentiostatic polarization of Li-Li symmetric cells exhibit strong correlation to Li electrode interfacial resistance, indicating that such methods are probing both bulk and interfacial phenomena. This reveals a major roadblock in characterizing electrolyte systems where the interfacial resistance is significantly larger than ohmic electrolyte resistance. As a result, we find that methods that rely on potentiostatic Li metal stripping/plating do not readily result in reliable liquid electrolyte transport coefficients, unlike similar methods for solid polymer electrolytes, where interfacial resistances are typically smaller than electrolyte resistances at the elevated temperatures typically of interest for such electrolytes.
Highlights
This method has been widely used for polymer systems[13,14] but only limited data exists for liquid electrolytes,[15,16] and even not traditional Li-ion battery carbonate electrolytes which suffer from additional Li metal-related complications including significant Li metal corrosion,[17] large and unstable interfacial impedance, and complexities related to compounding error from inter-related measurements
Ionic conductivity values extracted from AC Impedance Spectroscopy with non-blocking lithium according to Eq 29 are in good agreement with those obtained from conductivity probe measurements with blocking platinum electrodes
At the highest measured salt concentrations we observe a deviation between the conductivity measured with blocking and non-blocking electrodes, with lithium metal electrodes resulting in a 30% lower ionic conductivity for a 1.5 mol/kg electrolyte
Summary
Advances in Li-ion battery (LIB) technology have enabled significant development of portable electronics, electric vehicles (EVs), and distributed energy storage Despite their ubiquity, improvements in Li-ion battery performance are still sought, with enhanced charging rates, increased energy density, and reduced safety risks all being essential topics of ongoing research.[1] Current state-of-the-art Li-ion batteries make use of dissociated binary lithium salts, typically lithium hexafluorophosphate (LiPF6) in a blend of liquid carbonate solvents. Newman method is a Bruce-Vincent type polarization measurement of the current ratio which in the limit of an ideal solution is equal to the transference number.[12,13] This method has been widely used for polymer systems[13,14] but only limited data exists for liquid electrolytes,[15,16] and even not traditional Li-ion battery carbonate electrolytes which suffer from additional Li metal-related complications including significant Li metal corrosion,[17] large and unstable interfacial impedance, and complexities related to compounding error from inter-related measurements. These limitations are not unique to the Balsara-Newman method, and are present in most lithium metal-liquid electrolyte polarization measurements
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