Dynamic Exchange of Amphiphilic Random Copolymers between Micelles in Water: Kinetics and Mechanism Analyzed by TR-SANS

Amphiphilic random copolymers bearing poly(ethylene glycol) (PEG) and alkyl groups as side chains are intermolecularly self-assembled into size-controlled multichain micelles in water. The random copolymer micelles are known to induce the exchange of their polymer chains, whereas the details of the kinetics and mechanism have not been elucidated yet. Herein, we investigated the exchange kinetics and mechanism of the random copolymer chains between their micelles by time-resolved small-angle neutron scattering (TR-SANS). For this purpose, random copolymers carrying PEG and deuterated butyl or dodecyl groups were designed for deuterated micelles. After mixing deuterated and non-deuterated micelle solutions, the resulting mixtures were monitored by TR-SANS at various concentrations and temperatures. The scattering intensity of the micelle mixtures decayed with time, indicating that deuterated copolymers were gradually mixed with non-deuterated copolymers via chain exchange between their micelles to form micelles consisting of both deuterated and non-deuterated copolymers. The kinetic analysis revealed that the exchange of their polymer chains involved two mechanisms: A unimer release and insertion pathway was dominant in diluted conditions, whereas the contribution of a micelle collision pathway increased with increasing total polymer concentration and temperature. The activation energy of the polymer exchange process was dependent on the hydrophobic alkyl groups and larger than that of a related surfactant micelle.

Automated summary

Amphiphilic random copolymers with PEG and alkyl groups form size-controlled micelles in water. The exchange kinetics and mechanism of the copolymer chains between micelles were investigated using TR-SANS. The exchange involved two mechanisms: a dominant unimer release and insertion pathway under diluted conditions, and an increasing contribution of micelle collision pathway with higher polymer concentration and temperature. The activation energy for the exchange process was dependent on the hydrophobic alkyl groups.