Exploring glassy dynamics with Markov state models from graph dynamical neural networks
Siavash Soltani, Chad W. Sinclair, Jörg Rottler
Abstract
Using machine learning techniques, we introduce a Markov state model (MSM) for a model glass former that reveals structural heterogeneities and their slow dynamics by coarse-graining the molecular dynamics into a low-dimensional feature space. The transition timescale between states is larger than the conventional structural relaxation time τ_{α}, but can be obtained from trajectories much shorter than τ_{α}. The learned map of states assigned to the particles corresponds to local excess Voronoi volume. These results resonate with classic free volume theories of the glass transition, singling out local packing fluctuations as one of the dominant slowly relaxing features.
Topics & Concepts
Statistical physicsMarkov chainVoronoi diagramRelaxation (psychology)State spaceGranularityFeature (linguistics)Dynamics (music)GraphState (computer science)Computer sciencePhysicsMathematicsAlgorithmTheoretical computer scienceMachine learningGeometryAcousticsLinguisticsPsychologyStatisticsPhilosophyOperating systemSocial psychologyMaterial Dynamics and PropertiesTheoretical and Computational PhysicsLiquid Crystal Research Advancements