Abstract:

Carbon nitride has drawn numerous eyes in the past decade, whereas the photocatalytic performance is significantly limited by its wide band-gap (~2.7 eV for C₃N₄) simultaneously. Recently, C₃N₅ with narrower band-gap has been reported, however, a systematically investigation on its photoactivity for H₂ production has not been reported. The present work demonstrates the synthesis of C₃N₅ by thermal treatment of 3-amino-1,2,4-triazole, and the photocatalytic performance for H₂ production of C₃N₅ is investigated comprehensively. Photocatalytic H₂ production rate of C₃N₅ is ~2.2 times higher than that of C₃N₄ with 1.0 wt% Pt as co-catalyst, and series of experiments are carried out to explore the behind elements accounting for the high photoactivity. Combining the results of DRS, PL and photocurrent, it is found that C₃N₅ possesses wider visible light absorption region, lower band-gap and quicker photogenerated e ^-/h ⁺ separation efficiency. Moreover, characterizations including in-situ DRIFTS are adopted to monitor the adsorption property of H₂O on C₃N₅, which plays a significant role in surface water reduction reaction, and higher amount of adsorbed H₂O molecules on C₃N₅ is confirmed. The present work exhibits new insights into the high photocatalytic performance of N-rich carbon nitride catalysts.

Key words: C₃N₅, Photocatalysis, H₂ production, In-situ DRIFTS, Water adsorption