Introducing Iodide Ligands on IrAu12 Cluster Enhances Phosphorescence Efficiency and Photoredox Activity

The effects of halide ligands on the photoluminescence (PL) and photoredox properties were examined on [IrAu12(dppe)5X2]+ (1X; X=Cl, Br, I; dppe=1,2‐bis(diphenylphosphino)ethane). The PL quantum yield was enhanced in the order of 1Cl (67 %)1I due to the acceleration of radiative relaxation by the heavy atom effect in 1I. Despite the shortest PL lifetime, cluster 1I exhibited the highest conversion in the photocatalytic [2+2] cycloaddition of bisenone. The PL from 1Cl and 1Br was quenched by adding Lewis acid Li+, required for activation of bisenone, whereas that from 1I remained unaffected. Theoretical calculations showed that the Au−Cl and Au−Br bonds of 1Cl and 1Br were weakened by interaction with Li+, while the Au−I bond of 1I was not. Clusters 1Cl and 1Br underwent halide exchange with isocyanide in the presence of Li+, whereas 1I did not. These results suggested that the photoredox activity of 1Cl and 1Br was suppressed by the Li+‐induced nonradiative quenching of the photoexcited state. This study highlights the unexpected importance of halide ligands in the design of efficient cluster photocatalysts. We investigated the halide ligand effects on the photoluminescence properties and photoredox activity of IrAu12 clusters. The iodide‐ligated cluster exhibited the highest photoluminescence quantum yield and shortest photoexcited lifetime due to acceleration of the phosphorescence process. The iodide‐ligated cluster showed the highest photoredox activity due to the resistance to quenching by Lewis acid added to activate the substrate.