Catalytic engineering of a cerium vanadate-bismuth vanadate system to yield a bifunctional photocatalyst for simultaneous hydrogen generation and pollutant degradation
Document Type
Article
Publication Title
Rsc Advances
Abstract
A cerium vanadate-bismuth vanadate (CV-BV) composite is developed to facilitate dual functionality in photocatalytic hydrogen generation and degradation and is synthesized via a one pot hydrothermal method. Despite its strong pollutant degradation capability, BV remains ineffective for hydrogen evolution, whereas CV, with favourable band position, actively participates in hydrogen evolution. BV shows a pollutant degradation rate of 90% in 1 hour but does not produce hydrogen, while CV exhibits a hydrogen evolution rate of 590.0 μmol h−1 g−1 but only a 10% degradation of methyl orange (MO) for the same duration. Notably, the CV-BV heterojunction, governed by an S-scheme mechanism that favours charge carrier separation and redox potential, exhibits excellent performance, simultaneously achieving a hydrogen evolution rate of 1011 μmol h−1 g−1 and a 98% degradation efficiency for MO. The total organic carbon analysis indicates 93% removal of organic carbon from the dye solution. The system maintains stable catalytic performance over five consecutive cycles, indicating its durability. The solar-to-hydrogen (STH) efficiency for the CV-BV system is determined to be 3.99%. The activity of the CV-BV catalyst is demonstrated in actual wastewater, achieving 96% dye degradation and 803.0 μmol h−1 g−1 hydrogen generation. Its dual performance remained effective even in MO-contaminated seawater (310.0 μmol h−1 g−1 and 98% MO degradation), proving its adaptability to harsh, complex environments. The heterojunction efficiently absorbs a broad light spectrum, generating electron-hole pairs, and conduction band electrons of CV participate in proton reduction to produce hydrogen in the presence of a hole scavenger while superoxide radicals partake in degradation as proven from the radical trapping experiments. The synergistic S-scheme charge transfer mechanism within the CV-BV system enhances its bifunctional efficiency, demonstrating significant potential for fuel generation from wastewater with simultaneous environmental remediation.
First Page
29439
Last Page
29452
DOI
10.1039/d5ra04077a
Publication Date
8-18-2025
Recommended Citation
Perutil, Jil Rose; Francis, Mathew K.; Verma, Manish; and John, Neena S., "Catalytic engineering of a cerium vanadate-bismuth vanadate system to yield a bifunctional photocatalyst for simultaneous hydrogen generation and pollutant degradation" (2025). Open Access archive. 12790.
https://impressions.manipal.edu/open-access-archive/12790
