Photoinduced Electron Transfer Reactions as Photosynthetic Models: Reduction of Anthraquinones in SiO₂ and ZrO₂ Colloids

The photoinduced reduction of anthraquinone‐2‐sulfonate, AQS⁻, and anthraquinone‐2,6‐disulfonate AQS_2‐2, in a negatively charged SiO₂ colloid has been examined. Ru(bipy)²⁺₃ was used as sensitizer and triethanolamine, TEOA, as an ultimate electron donor. The reduction of the quinones to the corresponding semiquinone radicals, AQS_2‐ and AQS^3‐₂ proceeds only with propylviologen sulfonate, PVS⁰, (1), as a mediating electron acceptor. The primary electron acceptor, PVS⁰, functions as an efficient quencher of the excited species. The formation of AQS^3‐₂ is 4‐fold enhanced as compared to that of AQS^2‐. This enhancement is attributed to the additional stabilization of AQS^3‐₂ from recombination with the oxidized species, Ru(bipy)³⁺₃, due to electrostatic repulsions from the colloidal interface. Consequently, the subsequent oxidation of TEOA is facilitated. Similarly, a positively charged ZrO₂ colloid has been used in controlling photosensitized electron transfer reactions. Anthraquinone‐2,6‐disulfonate, AQS^2‐₂, is photoreduced in the ZrO₂ colloid to the respective AQHS^2‐₂ with the neutral sensitizer, Ru(bipy)₂(CN)⁰₂, and cysteine as electron donor (Φ = 3 × 10⁻²). No photoreduction of the quinone is observed in a homogeneous aqueous phase. The success in driving the photoinduced reaction in the ZrO₂ colloid is again attributed to the stabilization of the intermediate photoproducts from recombination by means of electrostatic interactions with the charged interface.