Kinetic simulations for cyclization of α,ω‐telechelic polymers

In this work, we conducted kinetic simulations to examine the effects of various experimental conditions on cyclization during the feed of α,ω-telechelic polymers into a reaction mixture. The simulations showed that the interplay between the feed rate and rate coefficients for cyclization and multiblock formation were the dominant and controlling parameters. The simulations were in good agreement with previously published results on cyclization of α,ω-telechelic polystyrene with different molecular weights by the Cu-catalyzed azide/alkyne cycloaddition (CuAAC) reaction. They also showed that high dilution was not a necessary condition for cyclization and that high percentages of monocyclic could be rapidly produced in solutions that are more concentrated. Previously reported work demonstrated that cyclic polystyrene could be prepared in less than 9 min at 25 °C using the CuAAC click reaction. These simulations allow for optimization and better experimental design, leading to the possibility of large scale production of cyclic polymers. © 2010 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem.

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