Your search keyword '"Kwon, Seulki"' showing total 2 results

1. The non-classical kinetics and the mutual information of polymer loop formation.

Author

Lee, Young-Ro, Kwon, Seulki, and Sung, Bong June

Subjects

*CHEMICAL processes, *ANALYTICAL mechanics, *THERMAL equilibrium, *POLYMERS, *BIOLOGICAL systems

Abstract

The loop formation of a single polymer chain has served as a model system for various biological and chemical processes. Theories based on the Smoluchowski equation proposed that the rate constant (kloop) of the loop formation would be inversely proportional to viscosity (η), i.e., kloop ∼ η−1. Experiments and simulations showed, however, that kloop showed the fractional viscosity dependence of kloop ∼ η−β with β < 1 either in glasses or in low-viscosity solutions. The origin of the fractional viscosity dependence remains elusive and has been attributed to phenomenological aspects. In this paper, we illustrate that the well-known failure of classical kinetics of the loop formation results from the breakdown of the local thermal equilibrium (LTE) approximation and that the mutual information can quantify the breakdown of the LTE successfully. [ABSTRACT FROM AUTHOR]

Published

2020

2. The breakdown of the local thermal equilibrium approximation for a polymer chain during packaging.

Author

Kwon, Seulki, Lee, Seulgi, Cho, Hyun Woo, Kim, Jeongmin, Kim, Jun Soo, and Sung, Bong June

Subjects

*THERMAL equilibrium, *POLYMERS, *BIOENGINEERING, *PRODUCTION engineering

Abstract

The conformational relaxation of a polymer chain often slows down in various biological and engineering processes. The polymer, then, may stay in nonequilibrium states throughout the process such that one may not invoke the local thermal equilibrium (LTE) approximation, which has been usually employed to describe the kinetics of various processes. In this work, motivated by recent single-molecule experiments on DNA packaging into a viral capsid, we investigate how the nonequilibrium conformations and the LTE approximation would affect the packaging of a polymer chain into small confinement. We employ a simple but generic coarse-grained model and Langevin dynamics simulations to investigate the packaging kinetics. The polymer segments (both inside and outside the confinement) stay away from equilibrium under strong external force. We devise a simulation scheme to invoke the LTE approximation during packaging and find that the relaxation of nonequilibrium conformations plays a critical role in regulating the packaging rate. [ABSTRACT FROM AUTHOR]

Published

2019