6533b830fe1ef96bd1297d6e
RESEARCH PRODUCT
Adversarial reverse mapping of equilibrated condensed-phase molecular structures
Michael WandTristan BereauTristan BereauMarc Stieffenhofersubject
Chemical Physics (physics.chem-ph)Structure (mathematical logic)Artificial neural networkComputer sciencePhase (waves)FOS: Physical sciencesLink (geometry)Condensed Matter - Soft Condensed MatterComputational Physics (physics.comp-ph)Energy minimizationMultiscale modelingBoltzmann distributionHuman-Computer InteractionMolecular dynamicsArtificial IntelligencePhysics - Chemical PhysicsSoft Condensed Matter (cond-mat.soft)Physics - Computational PhysicsAlgorithmSoftwaredescription
A tight and consistent link between resolutions is crucial to further expand the impact of multiscale modeling for complex materials. We herein tackle the generation of condensed molecular structures as a refinement -- backmapping -- of a coarse-grained structure. Traditional schemes start from a rough coarse-to-fine mapping and perform further energy minimization and molecular dynamics simulations to equilibrate the system. In this study we introduce DeepBackmap: A deep neural network based approach to directly predict equilibrated molecular structures for condensed-phase systems. We use generative adversarial networks to learn the Boltzmann distribution from training data and realize reverse mapping by using the coarse-grained structure as a conditional input. We apply our method to a challenging condensed-phase polymeric system. We observe that the model trained in a melt has remarkable transferability to the crystalline phase. The combination of data-driven and physics-based aspects of our architecture help reach temperature transferability with only limited training data.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-12-01 | Machine Learning: Science and Technology |