FEM-BEM coupling methods for Tokamak plasma axisymmetric free-boundary equilibrium computations in unbounded domains

Faugeras, Blaise; Heumann, Holger

doi:10.1016/j.jcp.2017.04.047

Cited by 17 publications

(25 citation statements)

References 27 publications

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“…We refer to [9,Chapter 2.4] for the details of the derivation. Alternative approaches, that incorporate the boundary conditions at infinity were recently presented in [7]. Quadrature rules.…”

Section: Methodsmentioning

confidence: 99%

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Automating the design of tokamak experiment scenarios

Blum

Heumann

Nardon

et al. 2019

Journal of Computational Physics

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The real-time control of plasma position, shape and current in a tokamak has to be ensured by a number of electrical circuits consisting of voltage suppliers and axisymmetric coils. Finding good target voltages/currents for the control systems is a very laborious, non-trivial task due to non-linear effects of plasma evolution. We introduce here an optimal control formulation to tackle this task and present in detail the main ingredients for finding numerical solutions: the finite element discretization, accurate linearizations and Sequential Quadratic Programming. Case studies for the tokamaks WEST and HL-2M highlight the flexibility and broad scope of the proposed optimal control formulation.Abstract. The real-time control of plasma position, shape and current in a tokamak has to be ensured by a number of electrical circuits consisting of voltage suppliers and axisymmetric coils. Finding good target voltages/currents for the control systems is a very laborious, non-trivial task due to non-linear e↵ects of plasma evolution. We introduce here an optimal control formulation to tackle this task and present in detail the main ingredients for finding numerical solutions: the finite element discretization, accurate linearizations and Sequential Quadratic Programming. Case studies for the tokamaks WEST and HL-2M highlight the flexibility and broad scope of the proposed optimal control formulation.Date: December 18, 2018.

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Section: Methodsmentioning

confidence: 99%

“…In the beginning (first three pictures) the plasma touches the limiter and becomes more and more elongated (limiter configuration) while finally, it moves into the divertor configuration, where the plasma boundary contains an X-point of the poloidal flux. with (7) µ[ ](r, z) = µ f (|r (r, z)| 2 r 2 )…”

Section: Free-boundary Plasma Equilibrium Evolutionmentioning

confidence: 99%

Automating the design of tokamak experiment scenarios

Blum

Heumann

Nardon

et al. 2019

Journal of Computational Physics

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“…The current density in these structures is then computed as a function of the input voltages in the PF circuits and/or of the time derivative of the poloidal ux (dened below) as shown in Eqs. (11) and (12) below. We refer to standard text books (e.g.…”

Section: Modelizationmentioning

confidence: 99%

An overview of the numerical methods for tokamak plasma equilibrium computation implemented in the NICE code

Faugeras

2020

Fusion Engineering and Design

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The code NICE (Newton direct and Inverse Computation for Equilibrium) enables to solve numerically several problems of plasma free-boundary equilibrium computations in a tokamak: plasma free-boundary only reconstruction and magnetic measurements interpolation, full free-boundary equilibrium reconstruction from magnetic measurements and possibly internal measurements (interferometry, classical linear approximation polarimetry or Stokes model polarimety, Motional Stark Eect and pressure), direct and inverse, static and quasi-static free-boundary equilibrium computations. NICE unies and upgrades 3 former codes VacTH [9], EQUINOX [4] and CEDRES++ [19]. The strength of NICE is to gather in a single nite element framework dierent equilibrium computation modes. It makes intensive use of Newton method and Sequential Quadratic Programming method to solve non linear problems. NICE is used routinely for WEST tokamak operation. It is also adapted to the IMAS (ITER Modelling and Analysis Suite) format which makes it usable on many dierent fusion tokamak reactors. In this document we give a general overview of the numerical methods implemented in NICE as well as a number of computation examples.

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“…The bilinear form c(•, •) [2,11,18] takes into account the boundary conditions at infinity using Greens functions of the operator -∇ • ( 1 μx r ∇(•)). It is defined as follows…”

Section: Mem-m Galerkin Formulation For the Equilibrium Problemmentioning

confidence: 99%

“…The elements of P2-Q3 are not only continuous on in h and ex h but have also continuous gradients on in h . We focus on the overlapping MEM-M (10) which uses the modified mortar mappings and is equivalent to (11). We also analyze the influence on the error curves of using either L 2 projections or interpolation to realize the gluing across γ ex and γ in for the MEM-M. We start with the case where in h has minimal overlap with ex h (see Fig.…”

Section: Experimental Validationmentioning

confidence: 99%

Finite element methods on composite meshes for tuning plasma equilibria in tokamaks

2018

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The fundamental concept of magnetically confined nuclear fusion devices is the magnetohydrodynamic (MHD) equilibrium: the pressure gradient due to highly energetic charged particles is balanced by the Lorenz force due to strong magnetic fields. Hence, numerical methods for MHD equilibria are also fundamental for fusion engineering applications. We rely here on a finite element method on composite meshes for the simulation of axisymmetric equilibria in tokamaks, torus-shaped nuclear fusion devices. One mesh with Cartesian quadrilaterals covers the domain accessible by the plasma and one mesh with triangles discretizes the region outside the chamber. The two meshes overlap in a narrow region. This approach gives the flexibility to achieve easily and at low cost higher order regularity for the approximation of the principal unknown, the poloidal magnetic flux, while preserving accurate meshing of the geometric details in the exterior. We show that higher order regularity allows to formulate appropriate optimal control problems that help to find a special type of equilibria, called snowflake equilibria, that are a very promising concept to mitigate high heat loads due to plasma escaping particles.

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FEM-BEM coupling methods for Tokamak plasma axisymmetric free-boundary equilibrium computations in unbounded domains

Cited by 17 publications

References 27 publications

Automating the design of tokamak experiment scenarios

Automating the design of tokamak experiment scenarios

An overview of the numerical methods for tokamak plasma equilibrium computation implemented in the NICE code

Finite element methods on composite meshes for tuning plasma equilibria in tokamaks

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