Complete Electrochemical Characterization and Limiting Current of Polyacetal Electrolytes

We investigate a polyacetal-based electrolyte, poly(1,3,6-trioxocane) (P(2EO-MO)) mixed with lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) salt, and report full electrochemical characterization of the transport parameters and a thermodynamic property in comparison to the previously reported poly(ethylene oxide) (PEO) electrolyte data [D. Gribble et al., J. Electrochem. Soc., 166, A3228 (2019)]. While the steady-state current fraction (rho(+)) of P(2EO-MO) electrolyte is greater than that of PEO electrolyte in the entire salt concentration window we explored, the rigorously defined transference number using Newman's concentrated solution theory (t(+)(0)) appears to be similar to that of PEO electrolyte. On the basis of full electrochemical characterization, we calculate the salt concentration profile as a function of position in the cell and predict limiting current density (i L-L) as a function of salt concentration. Experimental data were compared to the predicted values. The non-monotonic behaviors were observed both in prediction and experimental results with offset peak positions. We find that the limiting current density of P(2EO-MO) electrolyte is systematically lower than that of PEO electrolyte in most of the salt concentrations with the exception of r (av) = 0.05. It is noteworthy that even though one measure of electrolyte efficacy (kappa rho (+)) is superior in P(2EO-MO) electrolyte, the limiting current density, which is another metric of electrolyte efficacy at high currents, is not greater in P(2EO-MO). (c) 2022 The Electrochemical Society (ECS). Published on behalf of ECS by IOP Publishing Limited.

Automated summary

We investigate a polyacetal-based electrolyte, P(2EO-MO), mixed with LiTFSI salt, and provide a comprehensive electrochemical characterization of its transport parameters and thermodynamic property compared to PEO electrolyte. While the steady-state current fraction of P(2EO-MO) electrolyte is higher than PEO electrolyte, the transference numbers calculated using concentrated solution theory show similar values. Experimental data and predicted values for salt concentration and limiting current density exhibit non-monotonic behaviors with offset peak positions. The limiting current density of P(2EO-MO) electrolyte is systematically lower than PEO electrolyte except for a specific salt concentration.