Turbulent field fluctuations in gyrokinetic and fluid plasmas

Author(s)

Mathews, Abhilash; Mandell, N.; Francisquez, M.; Hughes, Jerry W.; Hakim, A.

Abstract

A key uncertainty in the design and development of magnetic confinement fusion energy reactors is predicting edge plasma turbulence. An essential step in overcoming this uncertainty is the validation in accuracy of reduced turbulent transport models. Drift-reduced Braginskii two-fluid theory is one such set of reduced equations that has for decades simulated boundary plasmas in experiment, but significant questions exist regarding its predictive ability. To this end, using a novel physics-informed deep learning framework, we demonstrate the first ever direct quantitative comparisons of turbulent field fluctuations between electrostatic two-fluid theory and electromagnetic gyrokinetic modelling with good overall agreement found in magnetized helical plasmas at low normalized pressure. This framework is readily adaptable to experimental and astrophysical environments, and presents a new technique for the numerical validation and discovery of reduced global plasma turbulence models.

Description

Submitted for publication in Physics of Plasmas

Date issued

2021-07

URI

https://hdl.handle.net/1721.1/158647

Department

Massachusetts Institute of Technology. Plasma Science and Fusion Center

Journal

Physics of Plasmas

Publisher

AIP

Other identifiers

21ja015