Dynamic Monte Carlo scaling method for polymers

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A brief review is given of applications of Monte Carlo simulations to study the dynamical properties of coarse-grained models of polymer melts, emphasizing the crossover from the Rouse model toward reptation, and the glass transition. The extent to which Monte Carlo algorithms can mimic the actual c

## Abstract A detailed analysis of the efficiency of a Monte‐Carlo (MC) method employing non‐local moves for simple lattice ring polymers is presented. While the introduction of kink‐translocation moves for linear chains results in the expected speedup by a factor of the order of the number of site

## Abstract End‐grafted polymer chains exposed to strong shear solvent flow in the __x__‐direction are investigated by a non‐equilibrium Monte Carlo method using the bond‐fluctuating model. The solvent flow is modelled by an enhanced jump rate of monomers in the flow direction. Under strong enough

## Abstract A uniform star‐branched polymer model with __f__ = 3 arms based on a simple cubic lattice was studied by means of the dynamic Monte Carlo method. The model chain is athermal with excluded‐volume interactions and it is flexible. A new type of local micromodification was introduced to mak