Abstract

Abstract Laser flash photolysis studies and stationary polymerizations were carried out with the aim to elucidate kinetics and mechanisms of photoinitiation processes based on thioxanthone (TX)/amine interactions. During these studies prominence was given to reactions which significantly influence the initiator efficiencies. Thus, rate constants of the reactions 3 TX * + monomer ( k q ), 3 TX * + amine ( k XH ), and ketyl radical + monomer ( k ) were determined; k q decreases according to the series: styrene (St) > N ‐vinyl‐2‐pyrrolidone (VP) > methyl methacrylate (MMA) > acrylonitrile (AN) > butyl vinyl ether (BVE) > vinyl acetate (VA) from 6 ·10 9 l·mol −1 ·s −;1 to 2·10 4 l·mol −1 ·s −1 . Substitution in the 2‐position of TX by methyl (MTX), isopropyl (ITX) and Cl (CTX) generally causes a decrease of k q , except for the systems CTX/VP and CTX/BVE. The k XH values range from 6 to 8·10 9 l·mol −1 ·s −1 for typical amines, e.g. ethyl 4‐((dimethylamino)benzoate). Ketyl radicals react rather slowly with monomers; for CTX k in l·mol −1 ·s −1 : 7·10 3 (St), 4·10 2 (VP), 4·10 1 (MMA), ⩽ 10 (BVE). O 2 reacts rapidly with ketyl radicals: k = 2·10 9 l·mol −1 ·s −1 (TX). Rates of polymerization ν (monomer consumption) determined at [M] = 5 mol/l and [amine] = 10 −1 mol/l are equal for TX, ITX, MTX, and CTX, but increase according to the series AN < MMA < VP; ν depends on the thioxanthone and the monomer concentration according to ν ∝ [TX] 1/2 [M].