ZnFe2O4 has attracted significant interest as a photoanode material for solar water splitting, yet its photoelectrochemical performance remains inferior to that of well-studied materials such as hematite (α-Fe2O3). Here, we investigate charge carrier dynamics in epitaxial ZnFe2O4 thin films using time-resolved microwave conductivity (TRMC). TRMC measurements show that ZnFe2O4 exhibits a carrier yield-mobility product roughly an order of magnitude lower than that of hematite. Furthermore, the microwave photoconductance action spectrum deviates strongly from the optical absorption spectrum, independent of illumination direction, revealing an excitation-wavelength-dependent, subunity yield of mobile charge carriers. Near-band-edge excitation results in reduced photoconductivity, indicating that a substantial fraction of absorbed photons do not generate mobile charge carriers on nanosecond timescales, accounting for the wavelength-dependent external quantum efficiency (EQE) behavior commonly observed in ZnFe2O4 photoanodes. Overall, these findings reveal inherent limitations in both carrier yield and transport properties, offering a mechanistic basis for the photoelectrochemical performance of ZnFe2O4.
Saini et al. (Mon,) studied this question.