Litcius/Paper detail

Physics-informed Machine Learning for Modeling Turbulence in Supernovae

Platon Karpov, Chengkun Huang, Iskandar Sitdikov, Chris L. Fryer, S. E. Woosley, Ghanshyam Pilania

2022The Astrophysical Journal12 citationsDOIOpen Access PDF

Abstract

Abstract Turbulence plays an important role in astrophysical phenomena, including core-collapse supernovae (CCSNe), but current simulations must rely on subgrid models, since direct numerical simulation is too expensive. Unfortunately, existing subgrid models are not sufficiently accurate. Recently, machine learning (ML) has shown an impressive predictive capability for calculating turbulence closure. We have developed a physics-informed convolutional neural network to preserve the realizability condition of the Reynolds stress that is necessary for accurate turbulent pressure prediction. The applicability of the ML subgrid model is tested here for magnetohydrodynamic turbulence in both the stationary and dynamic regimes. Our future goal is to utilize this ML methodology (available on GitHub) in the CCSN framework to investigate the effects of accurately modeled turbulence on the explosion of these stars.

Topics & Concepts

PhysicsTurbulenceRealizabilityStatistical physicsClosure (psychology)SupernovaTurbulence modelingReynolds stressK-omega turbulence modelK-epsilon turbulence modelMagnetohydrodynamic turbulenceClassical mechanicsTheoretical physicsMechanicsAstrophysicsMagnetohydrodynamicsAlgorithmComputer scienceMagnetic fieldMarket economyQuantum mechanicsEconomicsGamma-ray bursts and supernovaePulsars and Gravitational Waves ResearchStellar, planetary, and galactic studies