Ultra-fast charge migration competes with proton transfer in the early chemistry of HO˙.

Oxidation by the ultra-short lived radical cation of water, HO˙, can potentially take place at the interface of water and numerous heterogeneous systems involved in radiation therapy, energy and environmental industries. The oxidation processes induced by HO˙ can be mimicked in highly concentrated solutions where the nearest neighbors of HO˙ may be molecules other than water. The reactivity of HO˙ and DO˙ is probed in hydrogenated and deuterated sulfuric acid solutions of various concentrations. The oxidized solute, sulfate radical, is observed at 7 ps and remarkably higher yields are found in deuterated solutions. The isotopic effects reveal the competition between two ultrafast reactions: proton transfer toward HO (DO) and electron transfer from HSO to HO˙ (DO˙). Density functional theory simulations decipher the electron transfer mechanism: it proceeds via sub-femtosecond charge migration and is not affected by isotopic substitution. This work definitively demonstrates why direct oxidation triggered by HO˙ can be competitive with proton transfer.