Materials Chemistry & Science

Biography

Biography: Haijin Liu

Abstract

Statement of the Problem: Photocatalytic technologies, as promising strategies for environmental control, have broad and attractive prospects for the degradation of water and air resident pollutants. However, most single photocatalysts possess some defects, such as narrow light absorption range, the high recombination rate of photo-induced electrons and holes and so on.

Methodology & Theoretical Orientation: In this study, binary heterojunction photocatalysts, SnS2/Bi2MoO6 and SnO2/BiOBr were synthesized by mild hydrothermal methods for the first time. The photocatalytic activities of these materials were evaluated through the degradation of a series of organic pollutants, which possess stable chemical structures, intense carcinogenicity, as well as being recalcitrant to degradation.

Findings: The experimental results indicated that the SnS2/Bi2MoO6 and SnO2/BiOBr composites exhibited significantly enhanced performance in contrast to pure Bi2MoO6, SnS2, SnO2 or BiOBr. In details, the degradation rate constant of CV (crystal violet) using 5 wt% SnS2/Bi2MoO6 photocatalyst was 3.6 times that of the Bi2MoO6 and 2.4 times that of SnS2;  the degradation rate of RhB attained ~98.2% in 20 min. using 30 wt% SnO2/BiOBr, which was close to twice that of pure BiOBr, and 10 times that of pure SnO2. Furthermore, the primary active species in the photocatalytic oxidation process were detected via radical trapping experiments and ESR spectra.

Conclusion & Significance: Two photocatalytic mechanisms were proposed according to the different systems above to elucidate the improvement in photocatalytic efficiency. We trust that the work may provide further knowledge of the design and synthesis of advanced photocatalysts, as well as to inspire further applications of photocatalysts for water purification under visible light irradiation.