Multiscale simulation of plasma flows using active learning

A. Diaw; K. Barros; J. Haack; C. Junghans; B. Keenan; Y. W. Li; D. Livescu; N. Lubbers; M. McKerns; R. S. Pavel; D. Rosenberger; I. Sagert; T. C. Germann

doi:10.1103/PhysRevE.102.023310

Multiscale simulation of plasma flows using active learning

A. Diaw
, K. Barros
, J. Haack
, C. Junghans
, B. Keenan
, Y. W. Li
, D. Livescu
, N. Lubbers
, M. McKerns
, R. S. Pavel
, D. Rosenberger
, I. Sagert
, T. C. Germann

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

Plasma flows encountered in high-energy-density experiments display features that differ from those of equilibrium systems. Nonequilibrium approaches such as kinetic theory (KT) capture many, if not all, of these phenomena. However, KT requires closure information, which can be computed from microscale simulations and communicated to KT. We present a concurrent heterogeneous multiscale approach that couples molecular dynamics (MD) with KT in the limit of near-equilibrium flows. To reduce the cost of gathering information from MD, we use active learning to train neural networks on MD data obtained by randomly sampling a small subset of the parameter space. We apply this method to a plasma interfacial mixing problem relevant to warm dense matter, showing considerable computational gains when compared with the full kinetic-MD approach. We find that our approach enables the probing of Coulomb coupling physics across a broad range of temperatures and densities that are inaccessible with current theoretical models.

Original language	English
Article number	023310
Journal	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
Volume	102
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevE.102.023310
State	Published - Aug 2020
Externally published	Yes

Funding

Research presented in this article was supported by the Laboratory Directed Research and Development program of Los Alamos National Laboratory (LANL) under project number 20190005DR and used resources provided by the LANL Institutional Computing Program. LANL is operated by Triad National Security, LLC, for the National Nuclear Security Administration of U.S. Department of Energy (Contract No. 89233218CNA000001). This document is LA-UR-20-23628.

Access to Document

10.1103/PhysRevE.102.023310

Cite this

Diaw, A., Barros, K., Haack, J., Junghans, C., Keenan, B., Li, Y. W., Livescu, D., Lubbers, N., McKerns, M., Pavel, R. S., Rosenberger, D., Sagert, I., & Germann, T. C. (2020). Multiscale simulation of plasma flows using active learning. Physical Review E - Statistical, Nonlinear, and Soft Matter Physics, 102(2), Article 023310. https://doi.org/10.1103/PhysRevE.102.023310

@article{77d607dd14b1446ca78724581c3d5cba,

title = "Multiscale simulation of plasma flows using active learning",

abstract = "Plasma flows encountered in high-energy-density experiments display features that differ from those of equilibrium systems. Nonequilibrium approaches such as kinetic theory (KT) capture many, if not all, of these phenomena. However, KT requires closure information, which can be computed from microscale simulations and communicated to KT. We present a concurrent heterogeneous multiscale approach that couples molecular dynamics (MD) with KT in the limit of near-equilibrium flows. To reduce the cost of gathering information from MD, we use active learning to train neural networks on MD data obtained by randomly sampling a small subset of the parameter space. We apply this method to a plasma interfacial mixing problem relevant to warm dense matter, showing considerable computational gains when compared with the full kinetic-MD approach. We find that our approach enables the probing of Coulomb coupling physics across a broad range of temperatures and densities that are inaccessible with current theoretical models.",

author = "A. Diaw and K. Barros and J. Haack and C. Junghans and B. Keenan and Li, \{Y. W.\} and D. Livescu and N. Lubbers and M. McKerns and Pavel, \{R. S.\} and D. Rosenberger and I. Sagert and Germann, \{T. C.\}",

note = "Publisher Copyright: {\textcopyright} 2020 American Physical Society.",

year = "2020",

month = aug,

doi = "10.1103/PhysRevE.102.023310",

language = "English",

volume = "102",

journal = "Physical Review E - Statistical, Nonlinear, and Soft Matter Physics",

issn = "2470-0045",

publisher = "American Physical Society",

number = "2",

}

TY - JOUR

T1 - Multiscale simulation of plasma flows using active learning

AU - Diaw, A.

AU - Barros, K.

AU - Haack, J.

AU - Junghans, C.

AU - Keenan, B.

AU - Li, Y. W.

AU - Livescu, D.

AU - Lubbers, N.

AU - McKerns, M.

AU - Pavel, R. S.

AU - Rosenberger, D.

AU - Sagert, I.

AU - Germann, T. C.

PY - 2020/8

Y1 - 2020/8

N2 - Plasma flows encountered in high-energy-density experiments display features that differ from those of equilibrium systems. Nonequilibrium approaches such as kinetic theory (KT) capture many, if not all, of these phenomena. However, KT requires closure information, which can be computed from microscale simulations and communicated to KT. We present a concurrent heterogeneous multiscale approach that couples molecular dynamics (MD) with KT in the limit of near-equilibrium flows. To reduce the cost of gathering information from MD, we use active learning to train neural networks on MD data obtained by randomly sampling a small subset of the parameter space. We apply this method to a plasma interfacial mixing problem relevant to warm dense matter, showing considerable computational gains when compared with the full kinetic-MD approach. We find that our approach enables the probing of Coulomb coupling physics across a broad range of temperatures and densities that are inaccessible with current theoretical models.

AB - Plasma flows encountered in high-energy-density experiments display features that differ from those of equilibrium systems. Nonequilibrium approaches such as kinetic theory (KT) capture many, if not all, of these phenomena. However, KT requires closure information, which can be computed from microscale simulations and communicated to KT. We present a concurrent heterogeneous multiscale approach that couples molecular dynamics (MD) with KT in the limit of near-equilibrium flows. To reduce the cost of gathering information from MD, we use active learning to train neural networks on MD data obtained by randomly sampling a small subset of the parameter space. We apply this method to a plasma interfacial mixing problem relevant to warm dense matter, showing considerable computational gains when compared with the full kinetic-MD approach. We find that our approach enables the probing of Coulomb coupling physics across a broad range of temperatures and densities that are inaccessible with current theoretical models.

UR - https://www.scopus.com/pages/publications/85091192667

U2 - 10.1103/PhysRevE.102.023310

DO - 10.1103/PhysRevE.102.023310

M3 - Article

C2 - 32942385

AN - SCOPUS:85091192667

SN - 2470-0045

VL - 102

JO - Physical Review E - Statistical, Nonlinear, and Soft Matter Physics

JF - Physical Review E - Statistical, Nonlinear, and Soft Matter Physics

IS - 2

M1 - 023310

ER -

Multiscale simulation of plasma flows using active learning

Abstract

Funding

Access to Document

Other files and links

Fingerprint

Cite this