Dependence of size and morphology on shear flow for PS-based amphiphilic block copolymer micelles in aqueous solution

This contribution focuses on the impact of shear flow on size and nanostructure of PS-based amphiphilic block copolymer (BC) micelles by varying the stirring rate and copolymer composition.The results show that the vesicles formed from diblock copolymer (di-BC) of PS-b-PAA remain with vesicular morphology,although the average size decreases,with the increase of stirring rate.However,the multi-compartment micelles (MCMs) formed from tri-block copolymer (tri-BC) of PS-b-P2VP-b-PEO are quite intricate,in which the copolymer first self-assembles into spheres,then to clusters,to large compound micelles (LCMs),and finally back to spheres,as stirring rate increases from 100 r/min to 2200 r/min.Formation mechanism studies manifest that vesicles form simultaneously as water is added to the di-BC solution,termed as direct-assembly,and remain with vesicular structure in the flowing process.While for the PS-b-P2VP-b-PEO copolymer,spherical micelles at initial stage can further assemble into clusters and LCMs,termed as second-assembly,due to the speeding-up-aggregation of the favorable stirring.As a result,an invert V-relationship between tri-BC micelle dimension and stirring rate is observed in contrast to the non-linear decreasing curve of di-BC vesicles.It is by investigating these various amphiphilic BCs that the understanding of shear dependence of size and morphology of micelles is improved from self-assembly to second-assembly process.