Litcius/Paper detail

BiVO4 charge transfer control by a water-insoluble iron complex for solar water oxidation

Tímea Benkó, Shaohua Shen, Miklós Németh, Jinzhan Su, Ákos Szamosvölgyi, Zoltán Kovács, György Sáfrán, Sahir M. Al-Zuraiji, Endre Zsolt Horváth, András Sápi, Zoltán Kónya, József S. Pap

2023Applied Catalysis A General13 citationsDOIOpen Access PDF

Abstract

Photoelectrochemical water splitting can become efficient by grafting co-catalysts on semiconductors that improve the interfacial oxygen evolution reaction. We applied a simple non-noble metal pre-catalyst, [FeII(PBI)3]2+ (PBI is 2-(2′-pyridyl)benzimidazole ligand) for this purpose on a nanopyramidal BiVO4 semiconductor that was morphologically optimal for efficient light harvesting, but its performance suffered from V-poor surface recombination sites. The [FeII(PBI)3]2+ in situ transformed to α-Fe2O3 nanoparticles on V-vacant areas of BiVO4 mending their photocurrent-limiting effect. Photoelectrochemistry at pH 8.2 confirmed that the α-Fe2O3 co-catalyst improved the charge transfer efficiency by an order of magnitude, suppressed the recombination in the bulk and reduced the charge transfer resistance. Overall, the α-Fe2O3 suppressed the recombination on the V-poor surface, while at high potentials it provided high-valent centers for the oxygen evolution. The resulting photocurrent density far exceeding that of BiVO4 or samples modified by FeCl3 or Fe(NO3)3 underlines the metallochaperone-like effect of the PBI ligand.

Topics & Concepts

PhotocurrentWater splittingOxygen evolutionSemiconductorCatalysisPhotoelectrochemistryLigand (biochemistry)Materials scienceRecombinationChemistryPhotochemistryPhotocatalysisElectrochemistryElectrodeOptoelectronicsPhysical chemistryReceptorGeneBiochemistryAdvanced Photocatalysis TechniquesCopper-based nanomaterials and applicationsIron oxide chemistry and applications