Litcius/Paper detail

Monte Carlo simulation of a lattice model for the dynamics of randomly branching double-folded ring polymers

Elham Ghobadpour, Max Kolb, Mohammad Reza Ejtehadi, Ralf Everaers

2021Physical review. E22 citationsDOI

Abstract

Supercoiled DNA, crumpled interphase chromosomes, and topologically constrained ring polymers often adopt treelike, double-folded, randomly branching configurations. Here we study an elastic lattice model for tightly double-folded ring polymers, which allows for the spontaneous creation and deletion of side branches coupled to a diffusive mass transport, which is local both in space and on the connectivity graph of the tree. We use Monte Carlo simulations to study systems falling into three different universality classes: ideal double-folded rings without excluded volume interactions, self-avoiding double-folded rings, and double-folded rings in the melt state. The observed static properties are in good agreement with exact results, simulations, and predictions of Flory theory for randomly branching polymers. For example, in the melt state rings adopt compact configurations and exhibit territorial behavior. In particular, we show that the emergent dynamics is in excellent agreement with a recent scaling theory and illustrate the qualitative differences with the familiar reptation dynamics of linear chains.

Topics & Concepts

Monte Carlo methodStatistical physicsExcluded volumeBranching (polymer chemistry)ReptationScalingPhysicsPolymerLattice (music)Materials scienceMathematicsGeometryAcousticsStatisticsComposite materialNuclear magnetic resonanceBlock Copolymer Self-AssemblyStochastic processes and statistical mechanicsTheoretical and Computational Physics