A method that utilizes reversible addition fragmentation chain transfer (RAFT) chemistry is evaluated on a theoretical basis to deduce the termination rate coefficient for disparate length radicals ks;l t in acrylate free radical polymerization, where s and l represent the arbitrary yet disparate chain lengths from either a 'short' or 'long' RAFT distribution. The method is based on a previously developed method for elucidation of ks;l t for the model monomer system styrene. The method was expanded to account for intramolecular chain transfer (i.e., the formation of mid-chain radicals via backbiting) and the free radical polymerization kinetic parameters of methyl acrylate. Simulations show that the method's predictive capability is sensitive to the polymerization rate's dependence on monomer concentration, i.e., the virtual monomer reaction order, which varies with the termination rate coefficient's value and chain length dependence. However, attaining the virtual monomer reaction order is a facile process and once known the method developed here that accounts for mid-chain radicals and virtual monomer reaction orders other than one seems robust enough to elucidate the chain length dependence of ks;l t for the more complex acrylate free radical polymerization.
|Title of host publication||Radical Polymerization|
|Subtitle of host publication||Kinetics and Mechanism|
|Number of pages||12|
|Publication status||Published - 31 May 2007|
- Chain length dependent termination (CLDT)
- Reversible addition fragmentation chain transfer (RAFT)