Coarse-graining molecular dynamics: stochastic models with non-Gaussian force distributions
Abstract
Incorporating atomistic and molecular information into models of cellular behaviour is challenging because of a vast separation of spatial and temporal scales between processes happening at the atomic and cellular levels. Multiscale or multi-resolution methodologies address this difficulty by using molecular dynamics (MD) and coarse-grained models in different parts of the cell. Their applicability depends on the accuracy and properties of the coarse-grained model which approximates the detailed MD description. A family of stochastic coarse-grained (SCG) models, written as relatively low-dimensional systems of nonlinear stochastic differential equations, is presented. The nonlinear SCG model incorporates the non-Gaussian force distribution which is observed in MD simulations and which cannot be described by linear models. It is shown that the nonlinearities can be chosen in such a way that they do not complicate parametrization of the SCG description by detailed MD simulations. The solution of the SCG model is found in terms of gamma functions.
Cite
@article{arxiv.1908.10211,
title = {Coarse-graining molecular dynamics: stochastic models with non-Gaussian force distributions},
author = {Radek Erban},
journal= {arXiv preprint arXiv:1908.10211},
year = {2019}
}
Comments
submitted to the Journal of Mathematical Biology