Thermodynamics of star polymer solutions: a coarse-grained study

Abstract

We consider a coarse-grained (CG) model with pairwise interactions, suitable to describe low-density solutions of star-branched polymers of functionality f. Each macromolecule is represented by a CG molecule with (f+1) interaction sites, which captures the star topology. Potentials are obtained by requiring the CG model to reproduce a set of distribution functions computed in the microscopic model in the zero-density limit. Explicit results are given for f=6,12 and 40. We use the CG model to compute the osmotic equation of state of the solution for concentrations c such that p = c/c* 1, where c* is the overlap concentration. We also investigate in detail the phase diagram for f=40, identifying the boundaries of the solid intermediate phase. Finally, we investigate how the polymer size changes with c. For p 0.3 polymers become harder as f increases at fixed reduced concentration c/c*. On the other hand, for p 0.3, polymers show the opposite behavior: At fixed p, the larger the value of f, the larger their size reduction is.