Uncovering turbulent plasma dynamics via deep learning from partial observations

A. Mathews; M. Francisquez; J. W. Hughes; D. R. Hatch; B. Zhu; B. N. Rogers

doi:10.1103/PhysRevE.104.025205

Uncovering turbulent plasma dynamics via deep learning from partial observations

A. Mathews
, M. Francisquez
, J. W. Hughes
, D. R. Hatch
, B. Zhu
, B. N. Rogers

PPPL Computational Science

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

78 Scopus citations

Abstract

One of the most intensely studied aspects of magnetic confinement fusion is edge plasma turbulence which is critical to reactor performance and operation. Drift-reduced Braginskii two-fluid theory has for decades been widely applied to model boundary plasmas with varying success. Towards better understanding edge turbulence in both theory and experiment, we demonstrate that a physics-informed deep learning framework constrained by partial differential equations can accurately learn turbulent fields consistent with the two-fluid theory from partial observations of electron pressure which is not otherwise possible using conventional equilibrium models. This technique presents a paradigm for the advanced design of plasma diagnostics and validation of magnetized plasma turbulence theories in challenging thermonuclear environments.

Original language	English (US)
Article number	025205
Journal	Physical Review E
Volume	104
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevE.104.025205
State	Published - Aug 2021

All Science Journal Classification (ASJC) codes

Statistical and Nonlinear Physics
Statistics and Probability
Condensed Matter Physics

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10.1103/PhysRevE.104.025205

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title = "Uncovering turbulent plasma dynamics via deep learning from partial observations",

abstract = "One of the most intensely studied aspects of magnetic confinement fusion is edge plasma turbulence which is critical to reactor performance and operation. Drift-reduced Braginskii two-fluid theory has for decades been widely applied to model boundary plasmas with varying success. Towards better understanding edge turbulence in both theory and experiment, we demonstrate that a physics-informed deep learning framework constrained by partial differential equations can accurately learn turbulent fields consistent with the two-fluid theory from partial observations of electron pressure which is not otherwise possible using conventional equilibrium models. This technique presents a paradigm for the advanced design of plasma diagnostics and validation of magnetized plasma turbulence theories in challenging thermonuclear environments.",

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AU - Francisquez, M.

AU - Hughes, J. W.

AU - Hatch, D. R.

AU - Zhu, B.

AU - Rogers, B. N.

PY - 2021/8

Y1 - 2021/8

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AB - One of the most intensely studied aspects of magnetic confinement fusion is edge plasma turbulence which is critical to reactor performance and operation. Drift-reduced Braginskii two-fluid theory has for decades been widely applied to model boundary plasmas with varying success. Towards better understanding edge turbulence in both theory and experiment, we demonstrate that a physics-informed deep learning framework constrained by partial differential equations can accurately learn turbulent fields consistent with the two-fluid theory from partial observations of electron pressure which is not otherwise possible using conventional equilibrium models. This technique presents a paradigm for the advanced design of plasma diagnostics and validation of magnetized plasma turbulence theories in challenging thermonuclear environments.

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JO - Physical Review E

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ER -

Uncovering turbulent plasma dynamics via deep learning from partial observations

Abstract

All Science Journal Classification (ASJC) codes

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