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Factors determining formation efficiencies of one-electron-reduced species of redox photosensitizers

Kyohei Ozawa, Yusuke Tamaki, Kei Kamogawa, Kazuhide Koike, Osamu Ishitani

2020The Journal of Chemical Physics22 citationsDOIOpen Access PDF

Abstract

Improvement in the photochemical formation efficiency of one-electron-reduced species (OERS) of a photoredox photosensitizer (a redox catalyst) is directly linked to the improvement in efficiencies of the various photocatalytic reactions themselves. We investigated the primary processes of a photochemical reduction of two series [Ru(diimine)3]2+ and [Os(diimine)3]2+ as frequently used redox photosensitizers (PS2+), by 1,3-dimethyl-2-phenyl-2,3-dihydro-1H-benzo[d]imidazole (BIH) as a typical reductant in detail using steady-irradiation and time-resolved spectroscopies. The rate constants of all elementary processes of the photochemical reduction of PS2+ by BIH to give the free PS•+ were obtained or estimated. The most important process for determining the formation efficiency of the free PS•+ was the escape yield from the solvated ion pair [PS•+–BIH•+], which was strongly dependent on both the central metal ion and the ligands. In cases with the same central metal ion, the system with larger −ΔGbet, which is the free energy change in the back-electron transfer from the OERS of PS•+ to BIH•+, tended to lower the escape yield of the free OERS of PS2+. On the other hand, different central metal ions drastically affected the escape yield even in cases with similar −ΔGbet; the escape yield in the case of RuH2+ (−ΔGbet = 1.68 eV) was 5–11 times higher compared to those of OsH2+ (−ΔGbet = 1.60 eV) and OsMe2+ (−ΔGbet = 1.71 eV). The back-electron transfer process from the free PS•+ to the free BIH•+ could not compete against the further reaction of the free BIH•+, which is the deprotonation process giving BI•, in DMA for all examples. The produced BI• gave one electron to PS2+ in the ground state to give another PS•+, quantitatively. Based on these findings and investigations, it is clarified that the photochemical formation efficiency of the free PS•+ should be affected not only by −ΔGbet but also by the heavy-atom effect of the central metal ion, and/or the oxidation power of the excited PS2+, which should determine the distance between the excited PS and BIH at the moment of the electron transfer.

Topics & Concepts

PhotosensitizerRedoxPhotochemistryElectron transferChemistryYield (engineering)DiiminePhotocatalysisIonQuantum yieldMetal ions in aqueous solutionIrradiationCatalysisMetalImidazoleFluorescenceInorganic chemistryMaterials scienceStereochemistryOrganic chemistryMetallurgyPhysicsNuclear physicsQuantum mechanicsRadical Photochemical ReactionsElectrochemical Analysis and ApplicationsCO2 Reduction Techniques and Catalysts