Reaction Kinetics in Polymer Melts

Abstract

We study the reaction kinetics of end-functionalized polymer chains dispersed in an unreactive polymer melt. Starting from an infinite hierarchy of coupled equations for many-chain correlation functions, a closed equation is derived for the 2nd order rate constant k after postulating simple physical bounds. Our results generalize previous 2-chain treatments (valid in dilute reactants limit) by Doi, de Gennes, and Friedman and O'Shaughnessy, to arbitrary initial reactive group density n0 and local chemical reactivity Q. Simple mean field (MF) kinetics apply at short times, k Q. For high Q, a transition occurs to diffusion-controlled (DC) kinetics with k ≈ xt3/t (where xt is rms monomer displacement in time t) leading to a density decay nt ≈ n0 - n02 xt3. If n0 exceeds the chain overlap threshold, this behavior is followed by a regime where nt ≈ 1/xt3 during which k has the same power law dependence in time, k ≈ xt3/t, but possibly different numerical coefficient. For unentangled melts this gives nt t-3/4 while for entangled cases one or more of the successive regimes nt t-3/4, t-3/8 and t-3/4 may be realized depending on the magnitudes of Q and n0. Kinetics at times longer than the longest polymer relaxation time τ are always MF. If a DC regime has developed before τ then the long time rate constant is k ≈ R3/τ where R is the coil radius. We propose measuring the above kinetics in a model experiment where radical end groups are generated by photolysis.

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