Electrochemical
impedance spectroscopy (EIS) consists of plotting
so-called Nyquist plots representing negative of the imaginary versus the real
parts of the complex impedance of individual electrodes or electrochemical
cells. To date, interpretations of Nyquist plots have been based on
physical intuition and/or on the use of equivalent RC circuits. However,
the resulting interpretations are not unique and have often been inconsistent
in the literature. This study aims to provide unequivocal physical
interpretations of electrochemical impedance spectroscopy (EIS) results
for electric double layer capacitor (EDLC) electrodes and devices.
To do so, a physicochemical transport model was used for numerically
reproducing Nyquist plots accounting for (i) electric double layer
(EDL) formation at the electrode/electrolyte interface, (ii) charge
transport in the electrode, and (iii) ion electrodiffusion in binary
and symmetric electrolytes. Typical Nyquist plots of EDLC electrodes
were reproduced numerically for different electrode conductivity and
thickness, electrolyte domain thickness, as well as ion diameter,
diffusion coefficient, and concentrations. The electrode resistance,
electrolyte resistance, and the equilibrium differential capacitance
were identified from Nyquist plots without relying on equivalent RC
circuits. The internal resistance retrieved from the numerically generated
Nyquist plots was comparable to that retrieved from the “IR
drop” in numerically simulated galvanostatic cycling. Furthermore,
EIS simulations were performed for EDLC devices, and similar interpretations
of Nyquist plots were obtained. Finally, these results and interpretations
were confirmed experimentally using EDLC devices consisting of two
identical activated-carbon electrodes in both aqueous and nonaqueous
electrolytes.
This
study aims to provide physical interpretations of electrochemical
impedance spectroscopy (EIS) measurements for redox active electrodes
in a three-electrode configuration. To do so, a physicochemical transport
model was used accounting for (i) reversible redox reactions at the
electrode/electrolyte interface, (ii) charge transport in the electrode,
(iii) ion intercalation into the pseudocapacitive electrode, (iv)
electric double layer formation, and (v) ion electrodiffusion in binary
and symmetric electrolytes. Typical Nyquist plots generated by EIS
of redox active electrodes were reproduced numerically for a wide
range of electrode electrical conductivity, electrolyte thickness,
redox reaction rate constant, and bias potential. The electrode, bulk
electrolyte, charge transfer, and mass transfer resistances could
be unequivocally identified from the Nyquist plots. The electrode
and bulk electrolyte resistances were independent of the bias potential,
while the sum of the charge and mass transfer resistances increased
with increasing bias potential. Finally, these results and interpretation
were confirmed experimentally for LiNi0.6Co0.2Mn0.2O2 and MoS2 electrodes in organic
electrolytes.
This paper aims to understand the effect of nanoarchitecture on the performance of pseudocapacitive electrodes consisting of conducting scaffold coated with pseudocapacitive material. To do so, two-dimensional numerical simulations of ordered conducting nanorods coated with a thin film of pseudocapacitive material were performed. The simulations reproduced three-electrode cyclic voltammetry measurements based on a continuum model derived from first principles. Two empirical approaches commonly used experimentally to characterize the contributions of surface-controlled and diffusion-controlled charge storage mechanisms to the total current density with respect to scan rate were theoretically validated for the first time. Moreover, the areal capacitive capacitance, attributed to EDL formation, remained constant and independent of electrode dimensions, at low scan rates. However, at high scan rates, it decreased with decreasing conducting nanorod radius and increasing pseudocapacitive layer thickness due to resistive losses. By contrast, the gravimetric faradaic capacitance, due to reversible faradaic reactions, decreased continuously with increasing scan rate and pseudocapacitive layer thickness but was independent of conducting nanorod radius. Note that the total gravimetric capacitance predicted numerically featured values comparable to experimental measurements. Finally, an optimum pseudocapacitive layer thickness that maximizes total areal capacitance was identified as a function of scan rate and confirmed by scaling analysis. Electrochemical capacitors (ECs) have attracted significant attention in recent years due to their promises as electrical energy storage devices for high power applications.1,2 They can be classified as either electric double layer capacitors (EDLCs) or pseudocapacitors depending on the charge storage mechanism. EDLCs store energy physically in the electric double layers (EDL) forming at the electrode/electrolyte interfaces.1,2 They feature fast charging and discharging rates and thus large power density. They also have long cycle life thanks to highly reversible EDL formation. On the other hand, pseudocapacitors store energy both in the EDL and via reversible oxidation-reduction (redox) reactions occurring at the electrode surface and/or involving ion intercalation into the pseudocapacitive material.1,3-5 By combining both electrical energy storage mechanisms, pseudocapacitors offer the prospect of achieving high power density as well as high energy density.
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