Initial Quenching Efficiency Determines Light‐Driven H₂ Evolution of [Mo₃S₁₃]²⁻ in Lipid Bilayers

Abstract: Nature uses reactive components embedded in biological membranes to perform light‐driven photosynthesis. Here, we report a model artificial photosynthetic system for light‐driven hydrogen (H2) evolution. The system is based on liposomes where amphiphilic ruthenium trisbipyridine based photosensitizer (RuC9) and the H2 evolution reaction (HER) catalyst [Mo3S13]2‐ are embedded in biomimetic phospholipid membranes. When DMPC was used as the main lipid of these light‐active liposomes, increased catalytic activity … Show more

“…Functional groups present on the photosensitizer that are competent for hydrogen bonding, π-stacking, and/or a cationic/anionic charge may tune cage escape yields in a rational manner. An avenue that deserves further investigation is the supramolecular assembly of photosensitizers within micelles or liposomes (Figure D). ,,, Such supramolecular assemblies provide unique opportunities for vectoral electron transfer that provides the physical separation of the redox products and, hence, enhanced cage escape. In addition, local charges on the micelles or liposomes prove useful platforms for the study of Coulombic attraction/repulsion on cage escape processes.…”

“…Micelles or lipid bilayer have been chemically engineered to tune the cage escape yields by introduction of ionic charges, micelles, or lipid bilayers that attract or repel redox-active species. ,− In these assemblies, charge separation was modulated and facilitated by preassociation of the photosensitizers and the redox-active quenchers at the micelle interface. After excited-state electron transfer, the cage escape process was impacted by the hydrophobicity and ionic charges of the radical products that differed from those of the ground state.…”

Factors that Impact Photochemical Cage Escape Yields

“…Functional groups present on the photosensitizer that are competent for hydrogen bonding, π-stacking, and/or a cationic/anionic charge may tune cage escape yields in a rational manner. An avenue that deserves further investigation is the supramolecular assembly of photosensitizers within micelles or liposomes (Figure D). ,,, Such supramolecular assemblies provide unique opportunities for vectoral electron transfer that provides the physical separation of the redox products and, hence, enhanced cage escape. In addition, local charges on the micelles or liposomes prove useful platforms for the study of Coulombic attraction/repulsion on cage escape processes.…”

“…Micelles or lipid bilayer have been chemically engineered to tune the cage escape yields by introduction of ionic charges, micelles, or lipid bilayers that attract or repel redox-active species. ,− In these assemblies, charge separation was modulated and facilitated by preassociation of the photosensitizers and the redox-active quenchers at the micelle interface. After excited-state electron transfer, the cage escape process was impacted by the hydrophobicity and ionic charges of the radical products that differed from those of the ground state.…”

Factors that Impact Photochemical Cage Escape Yields