On the Mechanisms of Hydrogen‐Atom Transfer from Water to the Heteronuclear Oxide Cluster [Ga2Mg2O5].+: Remarkable Electronic Structure Effects

Mechanistic insight into the homolytic cleavage of the O? H bond of water by the heteronuclear oxide cluster [Ga₂Mg₂O₅]^.+ has been derived from state‐of‐the‐art gas‐phase experiments in conjunction with quantum chemical calculations. Three pathways have been identified computationally. In addition to the conventional hydrogen‐atom transfer (HAT) to the radical center of a bridging oxygen atom, two mechanistically distinct proton‐coupled electron‐transfer (PCET) processes have been identified. The energetically most favored path involves initial coordination of the incoming water ligand to a magnesium atom followed by an intramolecular proton transfer to the lone‐pair of the bridging oxygen atom. This step, which is accomplished by an electronic reorganization, generates two structurally equivalent OH groups either of which can be liberated, in agreement with labeling experiments.