Shape-dependent hydrogen generation performance of PtPd bimetallic co-catalyst coupled with C3N4 photocatalyst

The shape-dependent performance of metal co-catalysts in photocatalysis has been one of the research focal points in recent years. In this study, PtPd/C3N4 hybrid structures were constructed to reveal the effect of the shape of the PtPd bimetallic co-catalyst on the performance of photocatalytic hydrogen generation. PtPd nanocubes (NCs) and nanotetrahedrons (NTs) were sequentially deposited in situ on the surface of C(3)N(4 )nanosheets, establishing a strong contact interface to ensure the smooth transfer of photoinduced electrons. Ultraviolet-visible (UV-Vis) diffuse reflectance spectroscopy and photoelectrochemical experiments revealed that the PtPd NCs/C(3)N(4 )photocatalyst had comparable light absorption ability and equivalent carrier separation and transfer efficiency in comparison with the PtPd NTs/C(3)N(4 )photocatalyst, which excluded the influence of these factors on shape-dependent performance. The photocatalytic hydrogen generation results indicate that the hydrogen generation rate of the PtPd NCs/C(3)N(4 )photocatalyst is 1.33 times higher than that of the PtPd NTs/C(3)N(4 )photocatalyst, demonstrating that the cubic PtPd bimetallic co-catalyst is more conducive to hydrogen generation compared to the tetrahedral PtPd bimetallic co-catalyst.

Automated summary

The study found that nanocube PtPd bimetallic co-catalyst is more conducive to photocatalytic hydrogen generation compared to nanotetrahedron PtPd bimetallic co-catalyst, through constructing PtPd/C3N4 hybrid structures and examining their performance in light absorption ability and carrier transfer efficiency.