Dynamically Cyclic Fe <sup>2+</sup> /Fe <sup>3+</sup> Active Sites as Electron and Proton-Feeding Centers Boosting CO <sub>2</sub> Photoreduction Powered by Benzyl Alcohol Oxidation
Abstract
Solar-driven CO 2 photoreduction holds promise for sustainable fuel and chemical productions, but the complex proton-coupled multi-electron transfer processes and sluggish oxidation half-reaction kinetics substantially hinder its efficiency. Here, we devised a rational catalyst design to address these challenges by fabricating ferrocene carboxylic acid-functionalized Cs 3 Sb 2 Br 9 nanocrystals (CSB-Fc NCs), which facilitate simultaneous benzyl alcohol oxidation and CO 2 reduction reactions under visible-light irradiation. The synchronized proton-coupled electron transfer processes between the reduction and oxidation half-reactions on CSB-Fc NCs resulted in a 5-fold increase in the CO 2 reduction rate (45.56 μmol g −1 h −1 , 97.9% CO selectivity) and a 5.8-fold enhancement in benzyl alcohol conversion (97.7% selectivity for benzaldehyde) compared to the CSB. In situ Raman and ultraviolet-visible diffuse reflectance spectra revealed that the dynamic Fe 2+ /Fe 3+ redox loop within the Fc unit serves as the actual active site, facilitating the activation of substrate molecules. More importantly, in situ attenuated total reflection Fourier transform infrared spectroscopy and gas chromatography–mass spectrometry spectroscopy, with isotope labeling of Deuteron-benzyl alcohol and 13 CO 2 , confirmed that proton transfer from the hydroxyl group generates reactive protons at the Fe 2+ /Fe 3+ site, enabling efficient CO 2 photoreduction through subsequent protonation steps. This work offers a cost-effective and efficient approach for synergetic CO 2 photoreduction driven by organic synthesis, advancing solar energy utilization.