LED-driven photocatalysis of toluene, trichloroethylene and formaldehyde by cuprous oxide modified titanate nanotube arrays

In this study, cuprous oxide modified titanate nanotube arrays photocatalyst (Cu2O/TNAs), a p-n type heterostructure, was successfully synthesized by square wave voltammetry electrodeposition method (SWVE) with copper (II) acetate monohydrate as precursor. Cu2O/TNAs photocatalysts were characterized by SEM, XRD, XPS, and UV-vis DRS to investigate the physical and chemical properties such as surface structure, light absorption, and element composition. Results of characterization indicated that the Cu2O nanoparticles (Cu2O NPs) were firmly deposited on the surface of TNAs without significant morphological change. The enhanced photocatalytic (PC) performance of as-synthesized materials was exemplified by the test of photocurrent, which revealing that the average photocurrent density of Cu2O/TNAs (0.95 mu A cm(-2)) was 1.38 times higher than TNAs (0.69 mu A cm(-2)) under 24.2 mW cm(-2) LED irradiation. Three VOCs (volatile organic compounds), namely, Toluene, Formaldehyde and Trichloroethylene can be completely removed in the Cu2O/TNAs PC process with rate constants (kobs) of 2.08 x 10(-2), 3.11 x 10(-2), and 6.58 x 10(-2) min(-1), respectively, with the effort of the synergism of the photo-generated holes and hydroxyl radicals. Detail mechanism of hetero-junction Cu2O/TNAs composite PC system was proposed to clarify the redox reaction.

Automated summary

In this study, Cu2O/TNAs photocatalyst with enhanced photocatalytic performance was successfully synthesized. The photocurrent test showed improved performance under LED irradiation. The Cu2O/TNAs composite system demonstrated efficient removal of VOCs with a proposed mechanism involving the synergy of photo-generated holes and hydroxyl radicals.