Enhancing photocatalytic nitrogen fixation performance of Co-doped bismuth molybdate through band engineering tuning

Energy band engineering strategy by doping has been extensively proved to have great influence on photocatalytic properties of semiconductors. Herein, a novel Co-doped Bi2MoO6 (Co-BMO) photocatalyst was developed for photocatalytic nitrogen fixation. Co-BMO with microsphere structure was synthesized by a one-step solvothermal method. The NH3 yield of 0.3 % Co-BMO (130.07 mu mol.h(-1).g(cat)(-1)) was about 3.9 times higher than that of pure BMO without scavengers and visible light irradiation. The band gap of 0.3 % Co-BMO was reduced and the average PL lifetime was improved due to the successful doping of Co2+, which directly led to higher separation efficiency of photogenerated carriers and improved photocatalyst activity. In addition, gas chromatography (GC) tests showed that 0.3 % Co-BMO had a higher photocatalytic oxygen production capacity, which meant that more protons would be involved in the nitrogen reduction reaction. Their synergistic effect greatly enhanced the photocatalytic nitrogen fixation ability of 0.3 % Co-BMO. This novel photocatalyst may be a promising candidate for photocatalytic nitrogen fixation.

Automated summary

Energy band engineering through doping is shown to greatly influence the photocatalytic properties of semiconductors. In this study, a novel Co-doped Bi2MoO6 (Co-BMO) photocatalyst was developed for photocatalytic nitrogen fixation. The Co-BMO with microsphere structure achieved significantly higher NH3 yield and improved separation efficiency of photogenerated carriers due to successful Co2+ doping, leading to enhanced photocatalyst activity.