The effects of dynamic binding on the phase behaviour and properties of polymer blends undergoing complex coacervation

Associative polymer networks have shown a major promise in fabrication of self-healing and responsive materials. The can also serve as simple models to study more complex biological systems where transient interactions play an important role. In this work we investigate the properties of charged polymer blends whose constituents are capable of creating dynamic bonds. We model dynamic bonds as harmonic springs with additional bond formation energy, $\varepsilon_a$, which can be adjusted to influence the reaction rates for binding and unbinding. We show that varying the number of binding sites on the chains and $\varepsilon_a$ has a major effect on the resulting phase diagram. We further investigate the diffusive behaviour of the coacervates. We also study, how the network structure changes with varying number of active site, and increasing $\varepsilon_a$, and identify the values which result in the network percolation. Lastly, we explore the possibility of inducing orthogonal phase separation by by introducing a second type of binding site, which cannot interact with the first kind.