The reaction is initiated by addition of a catalytic amount of
PBr3, after which one molar equivalent of
Br2 is added. PBr3 converts the carboxylic
OH to the acyl bromide. The
acyl bromide tautomerizes to an
enol, which reacts with the Br2 to brominate at the
α position. In neutral to slightly
acidic
aqueous solution,
hydrolysis of the α-bromo acyl bromide occurs spontaneously, yielding the α-bromo carboxylic acid. If an aqueous solution is desirable, a full molar equivalent of PBr3 must be used as the catalytic chain is disrupted. If little
nucleophilic solvent is present, reaction of the α-bromo acyl bromide with the carboxylic acid yields the α-bromo carboxylic acid and regenerates the acyl bromide intermediate. In practice a molar equivalent of PBr3 is often used anyway to overcome the slow
reaction kinetics. The mechanism for the exchange between an alkanoyl bromide and a carboxylic acid is below. The α-bromoalkanoyl bromide has a strongly electrophilic carbonyl carbon because of the electron-withdrawing effects of the two bromides. By quenching the reaction with an alcohol, instead of water, the α-bromo ester can be obtained. ==History==