Journal article
A machine learning enabled hybrid optimization framework for efficient coarse-graining of a model polymer
Z Shireen, H Weeratunge, A Menzel, AW Phillips, RG Larson, K Smith-Miles, E Hajizadeh
Npj Computational Materials | NATURE PORTFOLIO | Published : 2022
Abstract
This work presents a framework governing the development of an efficient, accurate, and transferable coarse-grained (CG) model of a polyether material. The framework combines bottom-up and top-down approaches of coarse-grained model parameters by integrating machine learning (ML) with optimization algorithms. In the bottom-up approach, bonded interactions of the CG model are optimized using deep neural networks (DNN), where atomistic bonded distributions are matched. In the top-down approach, optimization of nonbonded parameters is accomplished by reproducing the temperature-dependent experimental density. We demonstrate that developed framework addresses the thermodynamic consistency and tr..
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Funding Acknowledgements
This research is supported by the Commonwealth of Australia as represented by the Defence Science and Technology Group of the Department of Defence. We acknowledge Spartan-HPC, Argali-HPC, and Melbourne Research Cloud at the Faculty of Engineering and Information Technology, and the University of Melbourne for providing us with the computing facility.