Formation of edge pressure pedestal and reversed magnetic shear due to toroidal rotation in a tokamak equilibrium

Li, Haolong; Zhu, Ping

doi:10.1063/5.0043424

Physics of Plasmas

2021

DOI: 10.1063/5.0043424

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Formation of edge pressure pedestal and reversed magnetic shear due to toroidal rotation in a tokamak equilibrium

Haolong Li

Ping Zhu

Abstract: Toroidal rotation is well known to play significant roles in the edge transport and L–H transition dynamics of tokamaks. Our recent calculation finds that a sufficiently strong localized toroidal rotation can directly bring out the formation of edge pressure pedestal with reversed magnetic shear that is reminiscent of an H-mode plasma, purely through the effects of toroidal rotation on the tokamak MHD equilibrium itself. In particular, the enhanced edge toroidal rotation enables a substantial peaking of the pa… Show more

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Neural network tokamak equilibria with incompressible flows

Kaltsas

Throumoulopoulos

2022

Physics of Plasmas

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We present several numerical solutions to a generalized Grad–Shafranov equation (GGSE), which governs axisymmetric plasma equilibria with incompressible flows of arbitrary direction, using fully connected, feed-forward, deep neural networks, also known as multi-layer perceptrons. Such artificial neural networks (ANNs) are trained to approximate tokamak-relevant equilibria upon minimizing the GGSE mean squared residual in the plasma volume and the poloidal flux function on the plasma boundary. Solutions for the Solovev and the general linearizing ansatz for the free functions involved in the GGSE are obtained and benchmarked against known analytic solutions. We also construct a nonlinear equilibrium incorporating characteristics relevant to the high confinement mode. In our numerical experiments, it was observed that changing the radial distribution of the training points has a surprisingly small effect on the accuracy of the trained solution. In particular, it is shown that localizing the training points at the plasma edge results in ANN solutions that describe quite accurately the entire magnetic configuration, thus demonstrating the interpolation capabilities of the ANNs.

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Neural network tokamak equilibria with incompressible flows

Kaltsas

Throumoulopoulos

2022

Physics of Plasmas

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Invariant regimes of Spencer scaling law for magnetic compression of rotating FRC plasma

Ma,

Zhu,

Rao

et al. 2024

Nucl. Fusion

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The scaling laws for the magnetic compression of a toroidally rotating field reversed configuration (FRC) have been investigated in this work. The magnetohydrodynamics (MHD) simulations of the magnetic compression on rotating FRCs employing the NIMROD code [C. R. Sovinec et al., J. Comput. Phys. 195, 355 (2004)], are compared with the Spencer’s one-dimensional (1D) theory [R. L. Spencer et al., Phys. Fluids 26, 1564 (1983)] for a wide range of initial flow speeds and profiles. The toroidal flow can influence the scalings directly through the alteration of the compressional work as also evidenced in the 1D adiabatic model, and indirectly by reshaping the initial equilibrium. However, in comparison to the static initial FRC equilibrium cases, the pressure and the radius scalings remain invariant for the magnetic compression ratio Bw2/Bw1 up to 6 in presence of the initial equilibrium flow, suggesting a broader applicable regime of the Spencer scaling law for FRC magnetic compression. The invariant scaling has been proven a natural consequence of the conservation of angular momentum of both fluid and magnetic field during the dynamic compression process.

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Formation of edge pressure pedestal and reversed magnetic shear due to toroidal rotation in a tokamak equilibrium

Cited by 2 publications

References 42 publications

Neural network tokamak equilibria with incompressible flows

Neural network tokamak equilibria with incompressible flows

Invariant regimes of Spencer scaling law for magnetic compression of rotating FRC plasma

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