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Entanglement Length Scale Separates Threading from Branching of Unknotted and Non-concatenated Ring Polymers in Melts

Mattia Alberto Ubertini, Jan Smrek, Angelo Rosa

2022Macromolecules25 citationsDOIOpen Access PDF

Abstract

. The different theories disagree on the details of the tree structure, i.e., the fractal dimension of the backbone of the tree. In the stiffer melts we find an indication of a self-avoiding scaling of the backbone, while more flexible chains do not exhibit such a regime. Moreover, the theories commonly neglect threadings and assign different importance to the impact of the progressive constraint release (tube dilation) on single ring relaxation due to the motion of other rings. Despite that each threading creates only a small opening in the double-folded structure, the threading loops can be numerous and their length can exceed substantially the entanglement scale. We link the threading constraints to the divergence of the relaxation time of a ring, if the tube dilation is hindered by pinning a fraction of other rings in space. Current theories do not predict such divergence and predict faster than measured diffusion of rings, pointing at the relevance of the threading constraints in unpinned systems as well. Revision of the theories with explicit threading constraints might elucidate the validity of the conjectured existence of topological glass.

Topics & Concepts

Quantum entanglementScalingThreading (protein sequence)PhysicsStatistical physicsLength scaleCrystallographyChemical physicsMolecular physicsMathematicsChemistryMechanicsQuantum mechanicsGeometryProtein structureQuantumNuclear magnetic resonanceMusic Technology and Sound StudiesMaterial Dynamics and PropertiesComputer Graphics and Visualization Techniques
Entanglement Length Scale Separates Threading from Branching of Unknotted and Non-concatenated Ring Polymers in Melts | Litcius