Efficient photofixation of nitrogen to ammonia over an S-scheme-based NiSnO3-g-C3N4 heterojunction

Abstract

A limited injection of photogenerated electrons in N2 molecules is the core problem limiting the performance of heterojunction materials in photofixing N2 to ammonia. In this study, an inexpensive Sn-based perovskite (NiSnO3, NSO) was anchored over the g-C3N4 (gCN) sheets under mild reaction conditions to develop an S-scheme heterojunction for the photocatalytic nitrogen reduction reaction. The NSO-gCN heterojunction, utilizing methanol as a sacrificial agent, showed remarkable N2 reduction capability with an impressive ammonia evolution of 566 µmolg−1h−1, surpassing that of gCN and NSO by the factor of 3.6 and 40, respectively, in visible light. The significantly improved performance of the material was attributed to the S-scheme charge transfer mechanism. The NSO-gCN photocatalyst showed good stability with only a marginal decrease measured in the activity over 3 cycles of the photocatalytic reaction. The study reveals a new strategy to design the highly efficient S-scheme-based heterojunctions by using Sn-based perovskite for sustainable ammonia synthesis.