The development of efficient artificial photocatalysts and photoelectrocatalysts for the reduction of CO2 with H2O to fuels and chemicals has attracted much attention in recent years. Although the state-of-the-art for the production of fuels or chemicals from CO2 using solar energy is still far from practical consideration, rich knowledge has been accumulated to understand the key factors that determine the catalytic performances. This Feature article highlights recent advances in the photocatalytic and photoelectrocatalytic reduction of CO2 with H2O using heterogeneous semiconductor-based catalysts. The effects of structural aspects of semiconductors, such as crystalline phases, particle sizes, morphologies, exposed facets and heterojunctions, on their catalytic behaviours are discussed. The roles of different types of cocatalysts and the impact of their nanostructures on surface CO2 chemisorption and reduction are also analysed. The present article aims to provide insights into the rational design of efficient heterogeneous catalysts with controlled nanostructures for the photocatalytic and photoelectrocatalytic reduction of CO2 with H2O.
Electrocatalytic reduction of CO2 to fuels and chemicals is one of the most attractive routes for CO2 utilization. Current catalysts suffer from low faradaic efficiency of a CO2-reduction product at high current density (or reaction rate). Here, we report that a sulfur-doped indium catalyst exhibits high faradaic efficiency of formate (>85%) in a broad range of current density (25–100 mA cm−2) for electrocatalytic CO2 reduction in aqueous media. The formation rate of formate reaches 1449 μmol h−1 cm−2 with 93% faradaic efficiency, the highest value reported to date. Our studies suggest that sulfur accelerates CO2 reduction by a unique mechanism. Sulfur enhances the activation of water, forming hydrogen species that can readily react with CO2 to produce formate. The promoting effect of chalcogen modifiers can be extended to other metal catalysts. This work offers a simple and useful strategy for designing both active and selective electrocatalysts for CO2 reduction.
The photocatalytic reduction of carbon
dioxide with water to fuels
and chemicals is a longstanding challenge. This article focuses on
the effects of cocatalysts and reaction modes on photocatalytic behaviors
of TiO2 with an emphasis on the selectivity of photogenerated
electrons for CO2 reduction in the presence of H2O, which has been overlooked in most of the published papers. Our
results clarified that the reaction using H2O vapor exhibited
significantly higher selectivity for CO2 reduction than
that by immersing the photocatalyst into liquid H2O. We
examined the effect of noble metal cocatalysts and found that the
rate of CH4 formation increased in the sequence of Ag <
Rh < Au < Pd < Pt, corresponding well to the increase in
the efficiency of electron–hole separation. This indicates
that Pt is the most effective cocatalyst to extract photogenerated
electrons for CO2 reduction. The selectivity of CH4 in CO2 reduction was also enhanced by Pt. The
size and loading amount of Pt affected the activity; a smaller mean
size of Pt particles and an appropriate loading amount favored the
formation of reduction products. The reduction of H2O to
H2 was accelerated more than the reduction of CO2 in the presence of Pt, leading to a lower selectivity for CO2 reduction and limited increases in CH4 formation
rate. We demonstrated that the addition of MgO into the Pt–TiO2 catalyst could further enhance the formation of CH4. The formation of H2 was suppressed simultaneously, suggesting
the increase in the selectivity for CO2 reduction in the
presence of MgO. Furthermore, the MgO- and Pt-modified TiO2 catalyst exhibited a higher CH4 selectivity in CO2 reduction.
This review highlights recent advances in photocatalytic transformations of lignocellulosic biomass (polysaccharides and lignin) into chemicals (in particular organic oxygenates).
The development of new methods for the direct transformation of methanol into two or multi-carbon compounds via controlled carbon–carbon coupling is a highly attractive but challenging goal. Here, we report the first visible-light-driven dehydrogenative coupling of methanol into ethylene glycol, an important chemical currently produced from petroleum. Ethylene glycol is formed with 90% selectivity and high efficiency, together with hydrogen over a molybdenum disulfide nanofoam-modified cadmium sulfide nanorod catalyst. Mechanistic studies reveal a preferential activation of C−H bond instead of O−H bond in methanol by photoexcited holes on CdS via a concerted proton–electron transfer mechanism, forming a hydroxymethyl radical (⋅CH2OH) that can readily desorb from catalyst surfaces for subsequent coupling. This work not only offers an alternative nonpetroleum route for the synthesis of EG but also presents a unique visible-light-driven catalytic C−H activation with the hydroxyl group in the same molecule keeping intact.
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