Abstract
We propose a general reaction mechanism for the pyridine (Py)-catalyzed reduction of CO2 over GaP(111), CdTe(111), and CuInS2(112) photoelectrode surfaces. This mechanism proceeds via formation of a surface-bound dihydropyridine (DHP) analogue, which is a newly postulated intermediate in the Py-catalyzed mechanism. Using density functional theory, we calculate the standard reduction potential related to the formation of the DHP analogue, which demonstrates that it is thermodynamically feasible to form this intermediate on all three investigated electrode surfaces under photoelectrochemical conditions. Hydride transfer barriers from the intermediate to CO2 demonstrate that the surface-bound DHP analogue is as effective at reducing CO2 to HCOO– as the DHP(aq) molecule in solution. This intermediate is predicted to be both stable and active on many varying electrodes, therefore pointing to a mechanism that can be generalized across a variety of semiconductor surfaces, and explains the observed electrode dependence of the photocatalysis. Design principles that emerge are also outlined.
Highlights
Interest is growing in technologies enabling the reduction of CO2 to useful fuels or value-added products, which if viable could help reduce atmospheric carbon emissions
Over all three electrode surfaces. Both standard reduction potential (SRP) and conduction band minimum (CBM) positions are calculated at pH = 5.2, which corresponds to experimental conditions that maximize CO2 reduction.[6]
We find that SRP is less negative (−1.09 V vs SCE), indicating that formation of the adsorbed anion is facilitated by coadsorbed protons
Summary
Interest is growing in technologies enabling the reduction of CO2 to useful fuels or value-added products, which if viable could help reduce atmospheric carbon emissions. Jeon et al.[3] relayed that the faradaic efficiency of CO2 conversion to formic acid over the CdTe(111) surface is improved from 43.6% to 60.7% when the Py concentration is varied from 0 to 10 mM. These studies all demonstrate that the presence of Py in the electrolyte is essential to optimal performance, yet the mechanism by which Py catalyzes CO2 reduction remains controversial
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