CO₂ Reduction Using Water as an Electron Donor over Heterogeneous Photocatalysts Aiming at Artificial Photosynthesis

Abstract: Conspectus Photocatalytic and photoelectrochemical CO2 reduction of artificial photosynthesis is a promising chemical process to solve resource, energy, and environmental problems. An advantage of artificial photosynthesis is that solar energy is converted to chemical products using abundant water as electron and proton sources. It can be operated under ambient temperature and pressure. Especially, photocatalytic CO2 reduction employing a powdered material would be a low-cost and scalable system for practical … Show more

“…The increasing use of fossil fuels generates a large amount of CO 2 that can affect the global climate and solar‐driven CO 2 conversion is a promising strategy to reduce the carbon footprint. [ 1,2 ] However, the efficiency of CO 2 reduction photocatalysts is unsatisfactory on account of inefficient separation of photogenerated carriers as well as the poor capture/activation ability of the CO 2 . [ 3 ] In addition, the current exploration of photocatalytic mechanism is mainly in the research of ground‐state semiconductor materials.…”

Excited Electron‐Rich Bi^(3–x)+ Sites: A Quantum Well‐Like Structure for Highly Promoted Selective Photocatalytic CO₂ Reduction Performance

“…The increasing use of fossil fuels generates a large amount of CO 2 that can affect the global climate and solar‐driven CO 2 conversion is a promising strategy to reduce the carbon footprint. [ 1,2 ] However, the efficiency of CO 2 reduction photocatalysts is unsatisfactory on account of inefficient separation of photogenerated carriers as well as the poor capture/activation ability of the CO 2 . [ 3 ] In addition, the current exploration of photocatalytic mechanism is mainly in the research of ground‐state semiconductor materials.…”

Excited Electron‐Rich Bi^(3–x)+ Sites: A Quantum Well‐Like Structure for Highly Promoted Selective Photocatalytic CO₂ Reduction Performance

“…The combination of metal and polymer moieties merges the advantage of both materials: Metal centers build up the functional core as redox-active species, whereas polymeric materials are able to optimize the catalyst performance while acting as stabilizing structures due to their feature of being tunable. Especially for carbon dioxide conversion, metal-containing polymers can support photocatalytic [ 11 , 12 , 13 , 14 , 15 ], electrocatalytic [ 16 , 17 , 18 , 19 , 20 ], photo-electrocatalytic [ 13 , 15 , 21 , 22 , 23 ] or thermochemical [ 24 ] reduction reactions.…”

Photocatalytic CO2 Conversion Using Metal-Containing Coordination Polymers and Networks: Recent Developments in Material Design and Mechanistic Details

“…[9][10][11] In particular, the development of photocatalyst materials, which facilitate CO 2 reduction without high temperature and/or pressure, has been regarded as a promising way. 7,8 For the past four decades, molecular-based photocatalysts including metal complexes 12,13 and semiconductor-based photocatalysts including metal oxides [14][15][16] and mixed-anion materials 16,17 have been extensively studied. High selectivity for CO 2 reduction, based on well-dened and tunable active sites, is one of the advantages of molecular photocatalysts, as has been demonstrated so far.…”

“…8,15 The band-gap excitation of semiconductors generates multiple electrons and holes in the conduction and valence bands. Therefore, simultaneous multi-electron reduction and oxidation reactions, e.g., overall water splitting [19][20][21][22] and CO 2 reduction using water as the electron source, 16 have been accomplished using a number of semiconductor photocatalysts, while such reactions have hardly been reported using a molecular photocatalyst system. 23 In terms of CO 2 reduction, however, semiconductor photocatalysts frequently suffer from the low selectivity of CO 2 reduction by competing with efficient proton reduction.…”

“…23 In terms of CO 2 reduction, however, semiconductor photocatalysts frequently suffer from the low selectivity of CO 2 reduction by competing with efficient proton reduction. 16 Recently, molecular-semiconductor hybrid photocatalysts have been developed to maximize their advantages, although it still remains a challenge for efficient photocatalytic CO 2 reduction. [24][25][26] Recently, organic conjugated polymers have emerged as new candidates for photocatalyst materials.…”

Photoexcited charge manipulation in conjugated polymers bearing a Ru(ii) complex catalyst for visible-light CO₂ reduction