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Solar-driven CO2 reduction to ethanol is extremely challenging due to the limited efficiency of charge separation, sluggish kinetics of C-C coupling, and unfavorable formation of oxygenate intermediates. Here, we elaborately design a red polymer carbon nitride (RPCN) consisting of S-N and Cu-N4 dual active sites (Cu/S-RPCN) to address this challenge, which achieves an impressive ethanol evolution rate of 50.4 μmol g-1 h-1 with 99.5 % selectivity for CO2 photoreduction in pure water. Cu and S atoms within the Cu-N-S configuration can serve as trapping centers for electrons and holes, respectively, providing spatial separation for photogenerated charge carriers. The incorporation of S atoms optimizes the adsorption of *CO on Cu atoms and reduces the energy barrier for the formation of *CO-COH intermediate. The adsorption strength of *OCHCH2OH intermediate on the Cu atoms via the O-Cu-C configuration can affect the selectivity of the C2 products as the cleavage of the Cu-O/Cu-C bonds determines the ethanol/ethylene pathway. The S-N-Cu structure weakens the Cu-O bond, thereby promoting the production of ethanol. This work provides a novel approach to fine-tune the surrounding microenvironment of metal atoms on carbon nitride for highly effective photocatalytic conversion of CO2 to ethanol.
Li et al. (Wed,) studied this question.
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