材料科学
碳纳米管
光催化
异质结
聚合物
载流子
化学工程
纳米技术
氮化碳
量子效率
密度泛函理论
半导体
甲烷
碳纤维
石墨氮化碳
欧姆接触
光电子学
表面工程
氮化物
合理设计
光催化分解水
吸热过程
作者
Xiaolong Zhao,Ying Tao,Mingyu Xia,Kee Wah Leong,Yingguang Zhang,Shijing Luo,Weicheng Chen,Mahmoud Samy,Xiaoping Yi,Wending Pan,Guisheng Li,Dennis Y.C. Leung
标识
DOI:10.1002/aenm.202504203
摘要
Abstract The construction of semiconductor heterojunctions presents a promising strategy for enhancing the efficiency of photocatalytic CO 2 reduction. However, the weak interfacial interactions between dissimilar materials often hinder effective charge separation, making the establishment of a robust and well‐connected interface, a significant challenge. In this study, a novel vacuum ultraviolet (VUV) irradiation‐driven fragmentation technique is introduced to synthesize graphitic carbon nitride fragments (CNF). These fragments are integrated in situ with single‐walled carbon nanotubes (SWNT), forming a SWNT/CNF heterojunction with optimized charge carrier dynamics and improves separation efficiency. Density functional theory (DFT) calculations demonstrate that CNF thermodynamically favors methane production by converting the *CO hydrogenation step from endothermic (pristine CN) to exothermic, thereby stabilizing the critical *CHO intermediate. The resulting SWNT/CNF heterostructure exhibits a higher specific surface area with abundant exposed active sites. The SWNT network acts as an efficient electron highway, establishing Ohmic contact that prolongs the lifetime of photogenerated carrier and suppresses recombination. Consequently, the SWNT/CNF photocatalyst achieves a methane production rate of 46.0 µmol h g −1 —representing 6.0‐fold and 2.5‐fold increases over pristine CN and CNF, respectively, along with an apparent quantum efficiency (AQE) of 0.96% for CH 4 and exceptional cyclic stability. This work provides a scalable strategy for engineering robust, high‐performance carbon nitride‐based heterojunctions, paving the way for more efficient and selective CO 2 photoreduction.
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