Beyond Inhibition: A 1H NMR Investigation of the Early Kinetics of RAFT-Mediated Polymerization with the Same Initiating and Leaving Groups
Date
2004
Authors
McLeary J.B.
Calitz F.M.
McKenzie J.M.
Tonge M.P.
Sanderson R.D.
Klumperman B.
Journal Title
Journal ISSN
Volume Title
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Abstract
In situ 1H nuclear magnetic resonance (NMR) spectroscopy has been used to directly investigate the processes that occur during the early stages (typically the first few monomer addition steps) of an AIBN-initiated reversible addition-fragmentation chain transfer polymerization of styrene in the presence of the RAFT agent cyanoisopropyl dithiobenzoate at 70 and 84°C. The change in concentration of important dithiobenzoate species as a function of time has been investigated. It was found that the reaction was extremely selective during the period of consumption of the initial RAFT agent (defined as the initialization period), with almost no production of RAFT-capped chains of degree of polymerization greater than unity until all of the cyanoisopropyl dithiobenzoate was converted to its single monomer adduct. The rate-determining step for this process was found to be the addition (propagation) of the cyanoisopropyl radicals to styrene. During the period where the initial RAFT agent was consumed, fragmentation of formed intermediate radicals strongly favored the production of the tertiary cyanoisopropyl radicals, which were the only significant propagating species during that period. This led to a greater rate of propagation during that period, since the propagation rate coefficient for the cyanoisopropyl radical is greater than that of polystyryl radicals. It was found that inhibition effects can occur in the presence of RAFT agents in homogeneous media when the kp for initiator fragments is smaller than for long chain radicals, which is a result of this aspect of the RAFT mechanism.
Description
Keywords
Free radical polymerization, Molecular weight, Nuclear magnetic resonance spectroscopy, Probability, Reaction kinetics, Styrene, Sulfur, Fragmentation, Rate-determining step, Polymers
Citation
Macromolecules
37
7
37
7