Micellization of Diblock Copolymer Modified by Cononsolvency Effect

Spherical micelle modified by cononsolvency effect is investigated by using self-consistent field theory (SCFT) and random phase approximation, which is formed by diblock copolymers consisted of one permanent hydrophobic block and one hydrophilic block. The addition of the cosolvent will bring about the cononsolvency effect on the hydrophilic block. The result shows that cononsolvency effect will expand the micelle size and changes the critical micelle concentration. By analyzing density profiles predicted by SCFT calculation, the micelle shell exhibits extension-collapse-extension transition with the addition of the cosolvent, which is responsible for the micelle size change. The driving force of the micellization is analyzed in the framework of SCFT calculation. The conventional micelle, which is formed by amphiphilic diblock copolymer in pure solvent, is compared with the micelle modified by cononsolvency effect. The reduction of the core-block - solvent contact area drives the formation of the conventional micelle. But in cononsolvency modified micelle, it is shown that the shell-block - cosolvent favorable interaction also plays the role to minimize the total free energy, whose mechanism is significantly different from that of the conventional micelle.