Response of Sulfonated Polystyrene Melts to Nonlinear Elongation Flows

Ionizable polymers form dynamic networks with domains controlled by two distinct energy scales, ionic interactions and van der Waals forces; both evolve under elongational flows during their processing into viable materials. A molecular level insight of their nonlinear response, paramount to controlling their structure, is attained by fully atomistic molecular dynamics simulations of a model ionizable polymer, polystyrene sulfonate. As a function of increasing elongational flow rate, the systems display an initial elastic response, followed by an ionic fraction dependent strain hardening, stress overshoot, and eventually strain thinning. As the sulfonation fraction increases, the chain elongation becomes more heterogeneous. Flow-driven ionic assembly dynamics that continuously break and reform control the response of the system.