In Situ Construction of Fuzzy Sea‐Urchin ZnIn<sub>2</sub>S<sub>4</sub>/W<sub>18</sub>O<sub>49</sub>: Leveraging Interfacial Z‐Scheme Redox Sites toward Cooperative Electron–Hole Utilization in Photocatalysis
Grayson Zhi Sheng Ling, Steven Hao Wan Kok, Peipei Zhang, Zi‐Jing Chiah, Lling‐Lling Tan, Binghui Chen, Wee‐Jun Ong
Abstract
Abstract Despite the significant milestones in the half‐reduction process of photocatalysis, challenges remain in fully utilizing electron–hole pairs in the simultaneous redox reactions. Herein, a Z‐scheme ZnIn 2 S 4 /W 18 O 49 (ZW) hybrid with complementary band edge potential is in situ constructed. The resultant fuzzy 1D‐assembled sea‐urchin photocatalyst demonstrates an optimal H 2 and benzaldehyde yield of 122 and 106 µmol h −1 under λ > 420 nm light irradiation. This sacrificial‐agent‐free system entails solar‐to‐hydrogen (STH) and apparent quantum efficiency (AQE) values of 0.466% and 2.48% (420 nm), respectively, surpassing most of the recently reported photocatalytic systems without the aid of noble metal cocatalysts. The outstanding performance is mainly attributed to the synergistic formation of intimate Z‐scheme heterojunction and the induction of localized surface plasmon resonances. Comprehensive characterization studies prove the direct injection of energetic hot electrons to promote the number of long‐lived active electrons. Besides, electron paramagnetic resonance and scavenger tests clarify the complicated mechanistic puzzle of the dual‐redox reaction, where benzaldehyde is formed dominantly via O─H activation followed by C─H cleavage of benzyl alcohol over ZW hybrid. Lastly, the universal use of the ZnIn 2 S 4 /W 18 O 49 composites is testified in various dual‐redox systems. This study offers a novel outlook for designing dual‐functioning heterojunctions toward a feasible photoredox application.