Microstructure and rheological properties of pH-responsive core–shell particles

Abstract

The microstructure and rheological properties of core–shell pH-responsive microgels consisting of poly(methyl methacrylate) (PMMA) particles grafted with a soft layer of methacrylic acid–ethyl acrylate (MAA–EA) cross-linked with di-allyl phthalate (DAP) were examined using dynamic light scattering and rheological techniques. The validity and limitation of the semi-empirical approach to model charged soft microgel particles developed by our group were tested on this core–shell system. The viscosity data for three different core–shell particles showed excellent agreement with the modified Krieger–Dougherty (K–D) model. Good agreement was also observed when our semi-empirical approach was compared against a theoretical model, which confirmed the validity of the semi-empirical approach to model charged soft particles. In addition, we confirmed that the new scaling law which relates the swelling ratio Q of microgels as a function of neutralization degree, α, average number of monomers between two cross-links, N x , molar fraction of acidic units, y and concentration of mobile counter-ions, C K + and C Na + , represented as ( N x / c 0 ) ( C K + + C Na + ) Q + Q 2 / 3 is proportional to yN x α. All the core–shell data at varying ionic strength and mobile counter-ions concentrations fall onto a master curve.