Effective stabilization of atomic hydrogen by Pd nanoparticles for rapid hexavalent chromium reduction and synchronous bisphenol A oxidation during the photoelectrocatalytic process.

Abstract

Atomic hydrogen (H*) plays a vital role in the synchronous redox of metallic ions and organic molecules. However, H*\xa0is extremely unstable as it is easily converted to hydrogen. Herein, we designed a novel strategy for the effective stabilization of H*\xa0to enhance its utility. The synthesized Pd nanoparticles grown on the defective MoS2 (DMS) of TiO2 nanowire arrays (TNA) (TNA/DMS/Pd) photocathode exhibited rapid Cr(VI) reduction (~95% in 10\xa0min) and bisphenol A (BPA) oxidation (~97% in 30\xa0min), with the kinetic constants almost 24- and 6-fold higher than those of the TNA photocathode, respectively. This superior performances could be attributed to: (i) the generated interface heterojunctions between TNA and DMS boosted the separation efficiencies of photogenerated electrons, thereby supplying abundant valance electrons to lower the overpotential to create a suitable microenvironment for H*\xa0generation; (ii) the stabilization of H*\xa0by Pd nanoparticles resulted in a significant increase in the yield of hydroxyl radical (•OH). This research provides a new strategy for the effective utilization of H*\xa0toward rapid reduction of heavy metals and synchronous oxidation of the refractory organics.