Abstract
We use a field theory approach to study the effects of permanent dipoles on interpenetration and free energy changes as a function of distance between two identical planar polymer brushes. Melts (i.e., solvent-free) and solvated brushes made up of polymers grafted on non-adsorbing substrates are studied. In particular, the weak coupling limit of the dipolar interactions is considered, which leads to concentration dependent pairwise interactions and the effects of orientational order are neglected. It is predicted that a gradual increase in the dipole moment of the monomers can lead to attractive interactions at intermediate separation distances. Since classical theory of polymer brushes based on the strong stretching limit (SSL) and the standard self-consistent field theory (SCFT) simulations using the Flory’s chi parameter always predicts repulsive interactions at all separations, our work highlights the importance of dipolar interactions in tailoring and accurately predicting forces between polar polymeric interfaces in contact with each other.
