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Phase-Migrating Z-Scheme Charge Transportation Enables Photoredox Catalysis Harnessing Water as an Electron Source

Ren Itagaki, Akinobu Nakada, Hajime Suzuki, Osamu Tomita, Ho‐Chol Chang, Ryu Abe

2025Journal of the American Chemical Society6 citationsDOI

Abstract

Z-schematic photocatalytic reactions are of considerable interest because of their potential for application to reductive molecular conversions to value-added chemicals using water as an electron source. However, most demonstrations of Z-scheme photocatalysis have been limited to overall water splitting. In particular, it has been basically impossible to couple the reduction of “water-insoluble compounds” with water oxidation by conventional Z-scheme systems in aqueous solution. In this work, an unconventional Z-scheme electron transportation system with a “phase-migrating” redox mediator is constructed that enables photocatalytic conversion of water-insoluble compounds by using water as an electron/proton source. In a dichloroethane (DCE)/water biphasic solution, a molecular Ir(III) complex acts as a photoredox catalyst for the reductive coupling of benzyl bromide by using ferrocene (Fc) as an electron donor in the DCE phase. On the other side, an aqueous dispersion of a Bi 4 TaO 8 Cl semiconductor loaded with a (Fe,Ru)O x cocatalyst photocatalyzed water oxidation using ferrocenium (Fc + ) as an electron acceptor. Because the partition coefficients of Fc + /Fc are significantly different, the Fc + and Fc generated by photoinduced electron transfer in each reaction could be selectively extracted to the opposite liquid phase. Spontaneous phase migration enables direction-selective electron transport across the organic/water interface that connects the reduction and oxidation reactions in the separated reaction phase. Eventually, photocatalytic reductive conversion of “water-insoluble” organic compounds using “water as the electron/proton source” was demonstrated through the step-by-step Z-scheme photocatalysis with the phase-migrating Fc + /Fc electron transportation.

Topics & Concepts

ChemistryElectronCharge (physics)Phase (matter)Scheme (mathematics)CatalysisChemical physicsPhotoredox catalysisPhotochemistryNanotechnologyPhotocatalysisNuclear physicsOrganic chemistryPhysicsQuantum mechanicsMathematical analysisMathematicsMaterials scienceAdvanced Photocatalysis TechniquesTiO2 Photocatalysis and Solar CellsAdvanced biosensing and bioanalysis techniques