AI Article Synopsis
- A coarse-grained molecular-dynamics model of polymer chains is developed to study the effects of hydrodynamic interactions, thermal fluctuations, nonlinear elasticity, and solvent-mediated excluded volume interactions.
- The model analyzes polymer knots under strong extensional flow conditions, revealing that knots impede the stretching of polymers due to entanglements that hinder natural and flow-induced motions.
- The findings indicate that knotted chains exhibit shorter lengths and lower stress values compared to simpler, non-knotted chains, highlighting how knot dynamics influence the rheological behavior of polymer solutions.
Article Abstract
We formulate a coarse-grained molecular-dynamics model of polymer chains in solution that includes hydrodynamic interactions, thermal fluctuations, nonlinear elasticity, and topology-preserving solvent mediated excluded volume interactions. The latter involve a combination of potential forces with explicit geometric detection and tracking of chain entanglements. By solving this model with numerical and computational methods, we study the physics of polymer knots in a strong extensional flow (Deborah number De=1.6 ). We show that knots slow down the stretching of individual polymers by obstructing via entanglements the "natural," unraveling, and flow-induced chain motions. Moreover, the steady-state polymer length and polymer-induced stress values are smaller in knotted chains than in topologically trivial chains. We indicate the molecular processes via which the rate of knot tightening affects the rheology of the solution.
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| http://dx.doi.org/10.1103/PhysRevE.80.041808 | DOI Listing |
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