Tuning the local chemical environment of ZnSe quantum dots with dithiols towards photocatalytic CO reduction

Sunlight-driven CO 2 reduction to renewable fuels is a promising strategy towards a closed carbon cycle in a circular economy. For that purpose, colloidal quantum dots (QDs) have emerged as a versatile light absorber platform that offers many possibilities for surface modification strategies. Considerable attention has been focused on tailoring the local chemical environment of the catalytic site for CO 2 reduction with chemical functionalities ranging from amino acids to amines, imidazolium, pyridines, and others. Here we show that dithiols, a class of organic compounds previously unexplored in the context of CO 2 reduction, can enhance photocatalytic CO 2 reduction on ZnSe QDs. A short dithiol (1,2-ethanedithiol) activates the QD surface for CO 2 reduction accompanied by a suppression of the competing H 2 evolution reaction. In contrast, in the presence of an immobilized Ni(cyclam) co-catalyst, a longer dithiol (1,6-hexanedithiol) accelerates CO 2 reduction. 1 H-NMR spectroscopy studies of the dithiol-QD surface interactions reveal a strong affinity of the dithiols for the QD surface accompanied by a solvation sphere governed by hydrophobic interactions. Control experiments with a series of dithiol analogues (monothiol, mercaptoalcohol) render the hydrophobic chemical environment unlikely as the sole contribution of the enhancement of CO 2 reduction. Density functional theory (DFT) calculations provide a framework to rationalize the observed dithiol length dependent activity through the analysis of the non-covalent interactions between the dangling thiol moiety and the CO 2 reduction intermediates at the catalytic site. This work therefore introduces dithiol capping ligands as a straightforward means to enhance CO 2 reduction catalysis on both bare and co-catalyst modified QDs by engineering the particle's chemical environment. ZnSe quantum dots (yellow sphere) are modified with dithiols of various lengths for enhanced visible light-driven CO 2 to CO reduction in either the absence or presence of a molecular Ni co-catalyst.