Beyond BGK: Prospects for Learning Surrogate Collision Operators
ORAL
Abstract
Kinetic gas dynamics in rarefied regimes exhibit complex behaviors arising from collisional processes,
making accurate descriptions both challenging and computationally expensive.
In this presentation, we explore the potential of employing physics-informed machine learning techniques
to derive novel collision operators for the Lattice Boltzmann Method (LBM).
We present preliminary results in which a neural network is successfully trained
to augment the single relaxation time BGK operator, leveraging on data from
particle-based methods such as molecular dynamics (MD) and direct-simulation Monte Carlo (DSMC).
This work serves as a first step towards the definition of a computationally efficient
framework for studying nonequilibrium gas flows, embedding higher-order effects
within a lower-order representation.
making accurate descriptions both challenging and computationally expensive.
In this presentation, we explore the potential of employing physics-informed machine learning techniques
to derive novel collision operators for the Lattice Boltzmann Method (LBM).
We present preliminary results in which a neural network is successfully trained
to augment the single relaxation time BGK operator, leveraging on data from
particle-based methods such as molecular dynamics (MD) and direct-simulation Monte Carlo (DSMC).
This work serves as a first step towards the definition of a computationally efficient
framework for studying nonequilibrium gas flows, embedding higher-order effects
within a lower-order representation.
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Presenters
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Alessandro Gabbana
Los Alamos National Laboratory (LANL)
Authors
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Alessandro Gabbana
Los Alamos National Laboratory (LANL)
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Kipton Barros
Los Alamos National Lab
-
Gyrya Gyrya
Los Alamos National Laboratory
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Daniel Livescu
Los Alamos National Laboratory (LANL)