异质结
催化作用
光催化
红外线的
密度泛函理论
光化学
吸附
可见光谱
材料科学
卟啉
紫外线
载流子
反应中间体
速率决定步骤
红外光谱学
化学工程
化学
光电子学
硫黄
反应机理
反应速率
一氧化碳
还原(数学)
选择性
纳米技术
紫外线
作者
Chenxi Tang,Ruijing Zhang,Teng Liang,Li X,Heng Rao,Ping She,Jun‐Sheng Qin
标识
DOI:10.1021/acscatal.6c01188
摘要
Most photocatalysts for CO2 reduction can only respond to ultraviolet and visible light, while infrared light-responsive photocatalysts remain scarce. In particular, converting CO2 into CH4 is a complex process involving the transfer of eight electrons, and its activity is often compromised by side reactions. Herein, we developed an organic−inorganic hybrid heterojunction with sulfur vacancies of In2S3-cobalt porphyrin ([meso-tetra(4-sulfonatophenyl)porphyrin], CoTPPS). This heterojunction was achieved by assembling tubular MIL-68(In)-derived In2S3 with CoTPPS via coordination interaction, achieving precise control over *COOH/*CHO intermediates to regulate CH4 selectivity. The optimized In2S3-CoTPPS exhibits a CO evolution rate of 38.84 μmol g−1 h−1, which is 5.43 times that of pure In2S3 (7.15 μmol g−1 h−1). Moreover, In2S3-CoTPPS demonstrates a high CH4 evolution rate of 36.65 μmol g−1 h−1 under infrared light (λ = 800−1100 nm). The enhanced catalytic performance is attributed to the improved light absorption, optimized CO2 adsorption and activation capabilities, and facilitated charge carrier separation by the heterojunction. Density functional theory calculations also indicate that the heterojunction reduces the energy barrier of the key intermediate (*COOH) and the Gibbs-free energy of the *+CO2→ *CHO transformation, thereby promoting the selective formation of multiple products. This study provides a research idea for the preparation of infrared light-responsive photocatalysts.
科研通智能强力驱动
Strongly Powered by AbleSci AI