Paper detail

Enhancement of coil--stretch hysteresis by self-concentration in extensional flows, and its implications for capillary thinning of liquid bridges of dilute polymer solutions

The coil-stretch transition in extensional flows of viscoelastic dilute polymer solutions is known to be associated with a strong hysteresis in molecular conformations and rheo-optical properties. At infinite dilution, hysteresis is caused by the large difference in frictional drag coefficient between undeformed isotropic polymer coils and highly stretched conformations. At the low extension rates in the hysteresis regime, stretched molecules pervade larger volumes than equilibrium coils since the flow is too weak to suppress transverse fluctuations. The onset of intermolecular overlap occurs for such stretched conformations at polymer concentrations much smaller than c*, the conventional critical overlap concentration for equilibrium coils. Therefore, for a range of concentrations c < c*, intramolecular hydrodynamic interactions may be significantly screened in stretched conformations. Scaling arguments based on "blob" concepts are used here to argue that the stretched state drag coefficient can grow strongly with concentration in the dilute regime. A dumbbell model with conformation-dependent drag model is used to predict a concomitant strong enhancement of coil-stretch hysteresis with increasing concentration in the dilute regime. This extensional flow induced self-concentration leads to a maximum in hysteretic effects around c*, which progressively diminish in the semi-dilute regime where screening in isotropic coils reduces the difference in drag coefficient between stretched and coiled states. It is shown that the concentration dependence observed by Clasen et al. (2006) of capillary-thinning dynamics in liquid bridges of polymer solutions provides direct evidence of coil-stretch hysteresis enhancement by self-concentration.