https://doi.org/10.1140/epje/i2007-10227-y
Regular Article
Non-linear scission/recombination kinetics of living polymerization
Institut Charles Sadron, 6 rue Boussingault, 67083, Strasbourg Cedex, France
* e-mail: nyrkova@cerbere.u-strasbg.fr
** e-mail: semenov@ics.u-strasbg.fr
Received:
23
April
2007
Accepted:
15
September
2007
Published online:
7
November
2007
Living polymers are formed by reversible association of primary units (unimers). Generally the chain statistical weight involves a factor σ < 1 suppressing short chains in comparison with free unimers. Living polymerization is a sharp thermodynamic transition for σ ≪ 1 which is typically the case. We show that this sharpness has an important effect on the kinetics of living polymerization (one-dimensional association). The kinetic model involves i) the unimer activation step (a transition to an assembly-competent state); ii) the scission/recombination processes providing growth of polymer chains and relaxation of their length distribution. Analyzing the polymerization with no chains but unimers at t = 0 , with initial concentration of unimers M ≳ M * (M* is the critical polymerization concentration), we determine the time evolution of the chain length distribution and find that: 1) for M * ≪ M ≪ M */σ the kinetics is characterized by 5 distinct time stages demarcated by 4 characteristic times t1, t2, t3 and t*; 2) there are transient regimes (t 1 ≲ t ≲ t 3) when the molecular-weight distribution is strongly non-exponential; 3) the chain scissions are negligible at times shorter than t2. The chain growth is auto-accelerated for t 1 ≲ t ≲ t 2 : the cut-off chain length (= polymerization degree 〈n〉w N 1 ∝ t 2 in this regime. 4) For t 2 < t < t 3 the length distribution is characterized by essentially 2 non-linear modes; the shorter cut-off length N1 is decreasing with time in this regime, while the length scale N2 of the second mode is increasing. (5) The terminal relaxation time of the polymer length distribution, t*, shows a sharp maximum in the vicinity of M*; the effective exponent is as high as ∼ σ-1/3 just above M*.
PACS: 82.35.-x Polymers: properties; reactions; polymerization – / 82.20.-w Chemical kinetics and dynamics – / 82.20.Bc State selected dynamics and product distribution – / 82.20.Db Transition state theory and statistical theories of rate constants –
© EDP Sciences, Società Italiana di Fisica and Springer-Verlag, 2007