Abstract

The reactions of e–aq, H· and OH· with phenol have been studied. The corresponding rate constants were 1.8 × 107, 1.8 × 109 and 1.4 × 1010 M–1 sec–1, respectively. The product detected after e–aq and H· attack was the H adduct (ε3300Å= 3800 M–1 cm–1). The initial product of OH· attack was the OH adduct (ε3300Å= 4400 M–1 cm–1). Both H and OH adducts are probably mixtures of isomers. OH adducts subsequently undergo either unimolecular elimination of water to form the more resonance-stabilized phenoxyl radical, ϕO·(ε4000Å= 2200 M–1 cm–1), or bimolecular radical-radical reactions. The elimination is catalyzed by H+, OH– and HPO2–4 ions. There are indications of different rates of catalysis for different isomers of the OH adduct. The uncatalyzed rate of elimination is ⩽103 sec–1. The elimination was also detected from OH adducts of p-cresol (to give p-CH3C6H4O-, ε4050Å= 2400 M–1 cm–1) and tyrosine. The ability to eliminate water appears to be a general property of OH adducts of phenols.