So‐Yoen Kim scite author profile

A series of cationic Ir(III) complexes ([Ir(btp)(bpy-X)] (Ir-X: btp = (2-pyridyl)benzo[b]thiophen-3-yl; bpy-X = 4,4'-X-2,2'-bipyridine (X = OMe, Bu, Me, H, and CN)) were applied as visible-light photosensitizer to the CO reduction to CO using a hybrid catalyst (TiO/ReP) prepared by anchoring of Re(4,4'-Y-bpy)(CO)Cl (ReP; Y = CHPO(OH)) on TiO particles. Irradiation of a solution containing Ir-X, TiO/ReP particles, and an electron donor (1,3-dimethyl-2-phenyl-1,3-dihydrobenzimidazole) in N,N-dimethylformamide at greater than 400 nm resulted in the reduction of CO to CO with efficiencies in the order X = OMe > Bu ≈ Me> H; Ir-CN has no photosensitization effect. A notable observation is that Ir-Bu and Ir-Me are less efficient than Ir-OMe at an early stage of the reaction but reveal persistent photosensitization behavior for a much longer period of time unlike the latter. Comparable experiments showed that (1) the Ir-X sensitizers are commonly superior compared to Ru(bpy), a widely used transition-metal photosensitizer, and (2) the system comprising Ir-OMe and TiO/ReP is much more efficient than a homogeneous-solution system using Ir-OMe and Re(4,4'-Y'-bpy)(CO)Cl (Y' = CHPO(OEt)). Implications of the present observations involving reaction mechanisms associated with the different behavior of the photosensitizers are discussed in detail.

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Highly Selective and Durable Photochemical CO₂ Reduction by Molecular Mn(I) Catalyst Fixed on a Particular Dye-Sensitized TiO₂ Platform

Woo

Choi

Kim

et al. 2019

ACS Catal.

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A Mn(I)-based hybrid system (OrgD-|TiO2|-MnP) for photocatalytic CO2 reduction is designed to be a coassembly of Mn(4,4′-Y2-bpy)(CO)3Br (MnP; Y = CH2PO(OH)2) and (E)-3-[5-(4-(diphenylamino)phenyl)-2,2′-bithiophen-2′-yl]-2-cyanoacrylic acid (OrgD) on TiO2 semiconductor particles. The OrgD-|TiO2|-MnP hybrid reveals persistent photocatalytic behavior, giving high turnover numbers and good product selectivity (HCOO– versus CO). As a typical run, visible-light irradiation of the hybrid catalyst in the presence of 0.1 M electron donor (ED) and 0.001 M LiClO4 persistently produced HCOO– with a >99% selectivity accompanied by a trace amount of CO; the turnover number (TONformate) reached ∼250 after 23 h of irradiation. The product selectivity (HCOO–/CO) was found to be controlled by changing the loading amount of MnP on the TiO2 surface. In situ FTIR analysis of the hybrid during photocatalysis revealed that, at low Mn concentration, the Mn–H monomeric mechanism associated with HCOO– formation is dominant, whereas at high Mn concentration, CO is formed via a Mn–Mn dimer mechanism.

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Organometallic Iridium(III) Complex Sensitized Ternary Hybrid Photocatalyst for CO₂ to CO Conversion

Kim

Choi

Kim

et al. 2019

Chemistry A European J

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As eries of heteroleptic iridium(III) complexes functionalized with two phosphonic acid (ÀPO 3 H 2 )g roups ( dfppy IrP, ppy IrP, btp IrP,a nd piq IrP)w ere prepared and anchored onto rhenium(I) catalyst( ReP)-loadedT iO 2 particles (TiO 2 / ReP) to build up an ew IrP-sensitized TiO 2 photocatalyst system (IrP/TiO 2 /ReP). The photosensitizing behavior of the IrP series was examined within the IrP/TiO 2 /ReP platform for the photocatalytic conversion of CO 2 into CO. The four IrPbased ternary hybridss howed increased conversion activity and durability than that of the corresponding homo-(IrP + ReP) and heterogeneous (IrP + TiO 2 /ReP) mixed systems.Amongt he four IrP/TiO 2 /ReP photocatalysts, the lowenergy-light (> 500 nm) activated piq IrP immobilized ternary system ( piq IrP/TiO 2 /ReP) exhibitedt he most durable conversion activity,g iving at urnover number of ! 730 for 170 h. A similark inetic feature observed through time-resolved photoluminescence measurements of both btp IrP/TiO 2 and TiO 2free btp IrP films suggestst hat the net electron flow in the ternary hybrid proceeds dominantly through ar eductive quenching mechanism,u nlike the oxidative quenching route of typical dye/TiO 2 -based photolysis.[a] P.Scheme1.Schematicrepresentation of the photocatalytic IrP/TiO 2 /ReP ternary system and components used in this study.TON = turnovern umber, NP = nanoparticle.

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Intriguing emission properties of triphenylamine–carborane systems

Kim

Cho

Jin

et al. 2015

Phys. Chem. Chem. Phys.

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So‐Yoen Kim

Photosensitization Behavior of Ir(III) Complexes in Selective Reduction of CO₂ by Re(I)-Complex-Anchored TiO₂ Hybrid Catalyst

Highly Selective and Durable Photochemical CO₂ Reduction by Molecular Mn(I) Catalyst Fixed on a Particular Dye-Sensitized TiO₂ Platform

Organometallic Iridium(III) Complex Sensitized Ternary Hybrid Photocatalyst for CO₂ to CO Conversion

Intriguing emission properties of triphenylamine–carborane systems

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So‐Yoen Kim

Photosensitization Behavior of Ir(III) Complexes in Selective Reduction of CO2 by Re(I)-Complex-Anchored TiO2 Hybrid Catalyst

Highly Selective and Durable Photochemical CO2 Reduction by Molecular Mn(I) Catalyst Fixed on a Particular Dye-Sensitized TiO2 Platform

Organometallic Iridium(III) Complex Sensitized Ternary Hybrid Photocatalyst for CO2 to CO Conversion

Intriguing emission properties of triphenylamine–carborane systems

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Product

Resources

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Photosensitization Behavior of Ir(III) Complexes in Selective Reduction of CO₂ by Re(I)-Complex-Anchored TiO₂ Hybrid Catalyst

Highly Selective and Durable Photochemical CO₂ Reduction by Molecular Mn(I) Catalyst Fixed on a Particular Dye-Sensitized TiO₂ Platform

Organometallic Iridium(III) Complex Sensitized Ternary Hybrid Photocatalyst for CO₂ to CO Conversion