A data-driven analysis of non-equilibrium transport in the magnetized Kelvin-Helmholtz instability
POSTER
Abstract
Collisional kinetic equations such as the Boltzmann equation provide a detailed
description of plasma physics, but their numerical solution can present a
challenge. Particle methods suffer from stochastic noise, and the direct
solution of kinetic equations in 6D phase space is out of reach computationally.
A common class of reduced models are the moment methods, which
integrate the kinetic equation over velocity space to obtain an infinite coupled
hierarchy of unknowns, requiring an ansatz for the distribution function to
close the hierarchy. Near local thermodynamic equilibrium (LTE), the Boltzmann
H-Theorem indicates that the natural choice of ansatz is a Maxwellian. However,
in regimes far from LTE, the available choices of ansatz are less satisfactory.
This work applies a data-driven approach to the analysis of the moment closure
problem. Full particle distribution data from a continuum kinetic simulation of
the magnetized Kelvin-Helmholtz instability are analyzed using the Sparse
Identification of Nonlinear Dynamics (SINDy) method. It is verified that mass,
momentum and energy conservation are witnessed by the SINDy analysis. SINDy is
then applied to derive approximate higher-order transport relations, and the
regimes of applicability of these relations are discussed. Finally, we explore
the departure from LTE, as measured by the dynamics of the 1-norm of deviation
from the local Maxwellian, χ.
description of plasma physics, but their numerical solution can present a
challenge. Particle methods suffer from stochastic noise, and the direct
solution of kinetic equations in 6D phase space is out of reach computationally.
A common class of reduced models are the moment methods, which
integrate the kinetic equation over velocity space to obtain an infinite coupled
hierarchy of unknowns, requiring an ansatz for the distribution function to
close the hierarchy. Near local thermodynamic equilibrium (LTE), the Boltzmann
H-Theorem indicates that the natural choice of ansatz is a Maxwellian. However,
in regimes far from LTE, the available choices of ansatz are less satisfactory.
This work applies a data-driven approach to the analysis of the moment closure
problem. Full particle distribution data from a continuum kinetic simulation of
the magnetized Kelvin-Helmholtz instability are analyzed using the Sparse
Identification of Nonlinear Dynamics (SINDy) method. It is verified that mass,
momentum and energy conservation are witnessed by the SINDy analysis. SINDy is
then applied to derive approximate higher-order transport relations, and the
regimes of applicability of these relations are discussed. Finally, we explore
the departure from LTE, as measured by the dynamics of the 1-norm of deviation
from the local Maxwellian, χ.
Presenters
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Jack Coughlin
University of Washington
Authors
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Jack Coughlin
University of Washington
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Uri Shumlak
University of Washington, Univ of Washington, Zap Energy Inc., Zap Energy Inc. and University of Washington