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Dual Near‐Infrared‐Response S‐Scheme Heterojunction with Asymmetric Adsorption Sites for Enhanced Nitrogen Photoreduction

Jiaxin Li, Chaoqi Zhang, Tong Bao, Yamin Xi, Ling Yuan, Yingying Zou, Yin Bi, Chao Liu, Chengzhong Yu

2024Advanced Materials30 citationsDOIOpen Access PDF

Abstract

Abstract Photocatalytic nitrogen reduction reaction (PNRR) holds immense promise for sustainable ammonia (NH 3 ) synthesis. However, few photocatalysts can utilize NIR light that carries over 50% of the solar energy for NH 3 production with high performance. Herein, a dual NIR‐responsive S‐scheme ZnCoS x /Fe 3 S 4 heterojunction photocatalyst is designed with asymmetric adsorption sites and excellent PNRR performance. The heterojunction possesses a hollow‐on‐hollow superstructure: Fe 3 S 4 nanocrystal‐modified ZnCoS x nanocages as building blocks assemble into spindle‐shaped particles with a spindle‐like cavity. Both Fe 3 S 4 and ZnCoS x are NIR active, allowing efficient utilization of full‐spectrum light. Moreover, an S‐scheme heterojunction is constructed that promotes charge separation. In addition, the Fe/Co dual‐metal sites at the interface enable an asymmetric side‐on adsorption mode of N 2 , favoring the polarization and activation of N 2 molecules. In combination with the promoted mass transfer and active site exposure of hollow superstructure, a superior PNRR performance is achieved, with a high NH 3 evolution rate of 2523.4 µmol g −1 h −1 , an apparent quantum yield of 9.4% at 400 nm and 8% at 1000 nm, and a solar‐to‐chemical conversion efficiency of 0.32%. The work paves the way for the rational design of advanced heterojunction catalysts for PNRR.

Topics & Concepts

HeterojunctionMaterials scienceNanocagesPhotocatalysisAdsorptionNanocrystalNanotechnologyOptoelectronicsChemical engineeringCatalysisOrganic chemistryChemistryEngineeringAdvanced Photocatalysis TechniquesAmmonia Synthesis and Nitrogen ReductionMXene and MAX Phase Materials