Integral dielectric kernel implementation to model RF heating in toroidal plasmas

Philippe Lamalle; Jules Zaleski; Christoph Slaby; Dirk Van Eester; Christophe Geuzaine; Fabrice Louche; Ernesto Lerche; Elena Moral Sánchez; Vincent Maquet; Bernard Reman; Bernard Reman

doi:10.1051/epjconf/202634601019

Integral dielectric kernel implementation to model RF heating in toroidal plasmas

Philippe Lamalle
, Jules Zaleski
, Christoph Slaby
, Dirk Van Eester
, Christophe Geuzaine
, Fabrice Louche
, Ernesto Lerche
, Elena Moral Sánchez
, Vincent Maquet
, Bernard Reman
, Bernard Reman

Laboratory for Plasma Physics

Université de Liège
Max-Planck-Institut für Plasmaphysik

Research output: Contribution to journal › Conference article › peer-review

Abstract

As discussed in Ref. [1], recent theoretical and numerical treatments [2, 3] have sought to express the plasma radiofrequency (RF) response as a nonlocal integral operator formulated in configuration space. Analytical expressions of the integral kernels are available for Maxwellian particle species. This approach enables (i) direct use of the finite element method (FEM) to model wave propagation and absorption in hot inhomogeneous fusion plasmas, (ii) local mesh-refinement, (iii) provides RF field representations suited to address tokamak geometry, and (iv) allows straightforward connection between plasma and antenna models. The present contribution focuses on the concrete application of this method, in an incremental way, developing codes and exploiting finite element codes/libraries.

Original language	English
Article number	01019
Journal	EPJ Web of Conferences
Volume	346
DOIs	https://doi.org/10.1051/epjconf/202634601019
Publication status	Published - 7 Jan 2026
Event	25th Topical Conference on Radio-Frequency Power in Plasmas, RFPPC 2025 - Schloss Hohenkammer, Germany Duration: 19 May 2025 → 22 May 2025

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title = "Integral dielectric kernel implementation to model RF heating in toroidal plasmas",

abstract = "As discussed in Ref. [1], recent theoretical and numerical treatments [2, 3] have sought to express the plasma radiofrequency (RF) response as a nonlocal integral operator formulated in configuration space. Analytical expressions of the integral kernels are available for Maxwellian particle species. This approach enables (i) direct use of the finite element method (FEM) to model wave propagation and absorption in hot inhomogeneous fusion plasmas, (ii) local mesh-refinement, (iii) provides RF field representations suited to address tokamak geometry, and (iv) allows straightforward connection between plasma and antenna models. The present contribution focuses on the concrete application of this method, in an incremental way, developing codes and exploiting finite element codes/libraries.",

author = "Philippe Lamalle and Jules Zaleski and Christoph Slaby and \{Van Eester\}, Dirk and Christophe Geuzaine and Fabrice Louche and Ernesto Lerche and S{\'a}nchez, \{Elena Moral\} and Vincent Maquet and Bernard Reman and Bernard Reman",

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year = "2026",

month = jan,

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doi = "10.1051/epjconf/202634601019",

language = "English",

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TY - JOUR

T1 - Integral dielectric kernel implementation to model RF heating in toroidal plasmas

AU - Lamalle, Philippe

AU - Zaleski, Jules

AU - Slaby, Christoph

AU - Van Eester, Dirk

AU - Geuzaine, Christophe

AU - Louche, Fabrice

AU - Lerche, Ernesto

AU - Sánchez, Elena Moral

AU - Maquet, Vincent

AU - Reman, Bernard

PY - 2026/1/7

Y1 - 2026/1/7

N2 - As discussed in Ref. [1], recent theoretical and numerical treatments [2, 3] have sought to express the plasma radiofrequency (RF) response as a nonlocal integral operator formulated in configuration space. Analytical expressions of the integral kernels are available for Maxwellian particle species. This approach enables (i) direct use of the finite element method (FEM) to model wave propagation and absorption in hot inhomogeneous fusion plasmas, (ii) local mesh-refinement, (iii) provides RF field representations suited to address tokamak geometry, and (iv) allows straightforward connection between plasma and antenna models. The present contribution focuses on the concrete application of this method, in an incremental way, developing codes and exploiting finite element codes/libraries.

AB - As discussed in Ref. [1], recent theoretical and numerical treatments [2, 3] have sought to express the plasma radiofrequency (RF) response as a nonlocal integral operator formulated in configuration space. Analytical expressions of the integral kernels are available for Maxwellian particle species. This approach enables (i) direct use of the finite element method (FEM) to model wave propagation and absorption in hot inhomogeneous fusion plasmas, (ii) local mesh-refinement, (iii) provides RF field representations suited to address tokamak geometry, and (iv) allows straightforward connection between plasma and antenna models. The present contribution focuses on the concrete application of this method, in an incremental way, developing codes and exploiting finite element codes/libraries.

UR - https://www.scopus.com/pages/publications/105029875880

U2 - 10.1051/epjconf/202634601019

DO - 10.1051/epjconf/202634601019

M3 - Conference article

AN - SCOPUS:105029875880

SN - 2101-6275

VL - 346

JO - EPJ Web of Conferences

JF - EPJ Web of Conferences

M1 - 01019

T2 - 25th Topical Conference on Radio-Frequency Power in Plasmas, RFPPC 2025

Y2 - 19 May 2025 through 22 May 2025

ER -

Integral dielectric kernel implementation to model RF heating in toroidal plasmas

Abstract

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