ZHU Chenxuan, YANG Zhongqing, LI Xinghang, WANG Ziqi, GUO Mingnü, RAN Jingyu
2025, 46(3): 714-721.
Ti3CN MXene exhibits remarkable electrical conductivity and photothermal conversion capabilities, making it a promising co-catalyst for photothermal catalytic CO2 reduction. This study utilizes two-dimensional mono-multilayer structured Ti3CN MXene to in-situ construct heterojunctions. A series of analyses, including AFM, SEM, TEM, XRD, XPS, UV-vis DRS, and i-t tests combined with DFT simulation calculation were conducted. The photothermal catalytic activity of each catalyst was tested under different energy input conditions. We discovered that the bandgap of Ti3CN/TiO2 is narrowed to 2.94 eV compared to that of TiO2, facilitating efficient electron transport from Ti3CN to TiO2 via the NC-Ti-O electron bridge at the interface, which enhances optical absorptivity and carrier mobility. The catalytic performance evaluation revealed a significant photothermal synergistic effect in CO2 reduction with Ti3CN/TiO2, the CO yield reached 8.34 μmol·g−1·h−1, which is 3.83 times greater than that achieved with TiO2 alone. These findings underscore the impact of Ti3CN-supported TiO2 on photothermal synergistic CO2 reduction characteristics