Sedimentation field flow fractionation and flow field flow fractionation as tools for studying the aging effects of WO 3 colloids for photoelectrochemical uses

Abstract

WO 3 colloidal suspensions obtained through a simple sol–gel procedure were subjected to a controlled temperature aging process whose time evolution in terms of particle mass and size distribution was followed by sedimentation field flow fractionation (SdFFF) and flow field flow fractionation (FlFFF). The experiments performed at a temperature of 60 °C showed that in a few hours the initially transparent sol of WO 3 particles, whose size was less than 25 nm, undergoes a progressive size increase allowing nanoparticles to reach a maximum equivalent spherical size of about 130 nm after 5 h. The observed shift in particle size distribution maxima (SdFFF), the broadening of the curves (FlFFF) and the SEM–TEM observations suggest a mixed mechanism of growth-aggregation of initial nanocrystals to form larger particles. The photoelectrochemical properties of thin WO 3 films obtained from the aged suspensions at regular intervals, were tested in a biased photoelectrocatalytic cell with 1 M H 2SO 4 under solar simulated irradiation. The current–voltage polarization curves recorded in the potential range 0–1.8 V (vs. SCE) showed a diminution of the maximum photocurrent from 3.7 mA cm −2 to 2.8 mA cm −2 with aging times of 1 h and 5 h, respectively. This loss of performance was mainly attributed to the reduction of the electroactive surface area of the sintered particles as suggested by the satisfactory linear correlation between the integrated photocurrent and the cyclic voltammetry cathodic wave area of the W(VI) → W(V) process measured in the dark.