Understanding the roles of carbon in carbon/g-C3N4 based photocatalysts for H2 evolution

Coupling graphitic carbon nitride (CN) with carbonaceous materials is an effective strategy to improve photocatalytic performance, but the contributions of carbonaceous materials are not fully understood. Herein, a new type of carbon/CN (CCN) complex photocatalyst is synthesized with a 6-fold enhancement of H-2 evolution rate compared to that of pristine CN. The role of carbon in photocatalytic H-2 evolution reaction is systemically studied and it is experimentally and theoretically revealed that carbon mainly contributes to the improved capability of exciton dissociation and enhanced electric conductivity for charge transfer, leading to an increased population of photo-carriers for photocatalytic reactions. Interestingly, the enhanced light absorption originated from carbon barely generates charge carriers for H-2 evolution activity. These new findings will inspire the rational design of carbon-based photocatalysts for efficient solar fuel production.

Automated summary

Coupling graphitic carbon nitride (CN) with carbonaceous materials enhances photocatalytic performance by improving exciton dissociation and charge transfer. The enhanced light absorption from carbon has little contribution to H-2 evolution activity.