Tandem Photocatalysis of CO<sub>2</sub> to C<sub>2</sub>H<sub>4</sub> via a Synergistic Rhenium-(I) Bipyridine/Copper-Porphyrinic Triazine Framework
Rui Xu, Duan‐Hui Si, Shao–Shuai Zhao, Qiu‐Jin Wu, Xusheng Wang, Tian‐Fu Liu, Hui Zhao, Rong Cao, Yuan‐Biao Huang
Abstract
The photocatalytic conversion of CO 2 into C 2+ products such as ethylene is a promising path toward the carbon neutral goal but remains a big challenge due to the high activation barrier for CO 2 and similar reduction potentials of many possible multi-electron-transfer products. Herein, an effective tandem photocatalysis strategy has been developed to support conversion of CO 2 to ethylene by construction of the synergistic dual sites in rhenium-(I) bipyridine fac -[Re I (bpy)(CO) 3 Cl] (Re-bpy) and copper-porphyrinic triazine framework [PTF(Cu)]. With these two catalysts, a large amount of ethylene can be produced at a rate of 73.2 μmol g –1 h –1 under visible light irradiation. However, ethylene cannot be obtained from CO 2 by use of either component of the Re-bpy or PTF(Cu) catalysts alone; with a single catalyst, only monocarbon product CO is produced under similar conditions. In the tandem photocatalytic system, the CO generated at the Re-bpy sites is adsorbed by the nearby Cu single sites in PTF(Cu), and this is followed by a synergistic C–C coupling process which ultimately produces ethylene. Density functional theory calculations demonstrate that the coupling process between PTF(Cu)–*CO and Re-bpy-*CO to form the key intermediate Re-bpy-*CO–*CO-PTF(Cu) is vital to the C 2 H 4 production. This work provides a new pathway for the design of efficient photocatalysts for photoconversion of CO 2 to C 2 products via a tandem process driven by visible light under mild conditions.