Photoinduced Electrocatalysis on 3D Flexible OsOx Quantum Dots

Synthesizing active and durable catalysts for the hydrogen evolution reaction (HER) is of great significance for the development of a sustainable hydrogen economy. In this paper, an OsOx quantum dot loaded in 3D flexible graphdiyne is reported for photoelectrocatalysis, which shows greatly improved HER activity under light induction. The calculated and experimental results indicate graphdiyne (GDY) is not only used as the hole transfer layer to prevent hole-electron recombination, but can induce charge transfer for more high-coordination osmium (Os4+). Upon exposure to a Xe lamp, OsOx QDs/GDY shows greatly enhanced catalytic activities and stabilities under alkaline conditions. Significantly, GDY can promote the good distribution and stability of metal oxide quantum dots. The fundamental advantage of the OsOx QDs/GDY catalyst is to promote hole transport and generate a large number of active sites and its superior photocurrent performance and photo/electrocatalytic activity. Simultaneously, due to the unique properties of the internal electronic structure of the GDY, the Mott-Schottky effect is promoted efficiently and as a typical semiconductor catalyst, OsOx QDs/GDY shows unparalleled performance.

Automated summary

The synthesis of OsOx quantum dot loaded in 3D flexible graphdiyne for photoelectrocatalysis shows significantly improved hydrogen evolution reaction activity under light induction and promotes charge transfer. The catalyst exhibits superior stability and activity, generating a large number of active sites and improving the distribution and stability of metal oxide quantum dots.