Flow-electrode capacitive deionization (FCDI) offers
infinite ion
adsorption for continuous desalination of high-concentration saline
water by supplying a flow-electrode to the cell. Although extensive
efforts have been made to maximize the desalination rate and efficiency
of FCDI cells, the electrochemical properties of these cells are not
fully understood. This study investigated the factors affecting the
electrochemical properties of FCDI cells containing activated carbon
(AC; 1–20 wt %) and various flow rates (6–24 mL/min)
for the flow-electrode using electrochemical impedance spectroscopy
before and after desalination. Examination of the impedance spectra
using the distribution of relaxation time and equivalent circuit fitting
analysis revealed three distinctive resistances such as internal,
charge transfer, and ion adsorption resistances. The overall impedance
decreased significantly after the desalination experiment due to increased
ion concentrations in the flow-electrode. The three resistances decreased
with increasing concentrations of AC in the flow-electrode due to
the extension of electrically connected AC particles that participated
in the electrochemical desalination reaction. The ion adsorption resistance
decreased significantly due to the flow rate dependence of the impedance
spectra. In contrast, the internal and charge transfer resistances
were invariant.
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