State of the art of gyrokinetic and hybrid MHD-kinetic codes through non-linear benchmarking to study reactor relevant burning plasmas

Gregorio Vlad; Xin Wang; Francesco Vannini; Hinrich Lütjens; Sergio Briguglio; Nakia Carlevaro; Matteo V. Falessi; Giuliana Fogaccia; Valeria Fusco; Fulvio Zonca; Alessandro Biancalani; Alberto Bottino; Thomas Hayward-Schneider; Philipp Lauber; Baruch Rofman; Laurent Villard

doi:10.1007/s41614-025-00199-2

State of the art of gyrokinetic and hybrid MHD-kinetic codes through non-linear benchmarking to study reactor relevant burning plasmas

Gregorio Vlad
, Xin Wang
, Francesco Vannini
, Hinrich Lütjens
, Sergio Briguglio
, Nakia Carlevaro
, Matteo V. Falessi
, Giuliana Fogaccia
, Valeria Fusco
, Fulvio Zonca
, Alessandro Biancalani
, Alberto Bottino
, Thomas Hayward-Schneider
, Philipp Lauber
, Baruch Rofman
, Laurent Villard

ENEA Centro Ricerche Frascati
Max-Planck-Institut für Plasmaphysik
Sezione di Roma
Institute for Fusion Theory and Simulation
Research Center
ENAC-IIC-GEL

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

Abstract

After a brief introduction on present day simulation and modeling of burning plasmas in magnetically confined devices, the results of a non-linear benchmark are presented, undertaken among several state-of-the-art codes available to study the self-consistent interaction of an Energetic Particle (EP) population with shear Alfvén waves: HYMAGYC, MEGA, ORB5 and XTOR-K. The first two codes, HYMAGYC and MEGA, are hybrid codes: HYMAGYC is a MHD-Gyrokinetic code (the bulk plasma is represented by MHD equations, while the EP species is treated using the gyrokinetic formalism), while MEGA is an MHD-Drift-Kinetic code (the bulk plasma is represented by MHD equations, while the EP species is treated using the drift-kinetic formalism, with the possibility of an ad-hoc gyroaveraging); ORB5 is a global electromagnetic gyrokinetic code (both bulk and EP species are treated using the gyrokinetic formalism); XTOR-K is a non-linear kinetic-MHD code (the bulk plasma is described by a set of non-linear resistive two-fluid MHD equations, extended to include kinetic effects of multiple ion species with a fully kinetic PIC module). The equilibrium of the so-called NLED-AUG reference case, in its version with peaked off-axis EP density profile, has been used, while considering a |n|=1 perturbation. This non-linear benchmark is the natural continuation of the linear benchmark already considered in the recent past, and represent a first-ever code comparison in the deep non-linear stage. In the present study fluid non-linearities are omitted, and the focus will be on comparing wave-particle interactions effects across codes. Characteristics of the non-linear saturation of the mode, self-consistent modification to the EP density profile and other features are compared among the considered codes. This brief review presents the state of the art of gyrokinetic and hybrid MHD-kinetic codes emerging as tools for studying reactor-relevant burning plasmas in realistic conditions.

Original language	English
Article number	27
Journal	Reviews of Modern Plasma Physics
Volume	9
Issue number	1
DOIs	https://doi.org/10.1007/s41614-025-00199-2
Publication status	Published - 1 Dec 2025

Keywords

Alfvénic modes
Energetic particles
Gyrokinetic simulation
Hybrid MHD-gyrokinetic simulation
Ideal and resistive MHD modes
Kinetic-MHD simulation
Non-linear simulation
Numerical simulations
Particle-in-cell method

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10.1007/s41614-025-00199-2

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Vlad, G., Wang, X., Vannini, F., Lütjens, H., Briguglio, S., Carlevaro, N., Falessi, M. V., Fogaccia, G., Fusco, V., Zonca, F., Biancalani, A., Bottino, A., Hayward-Schneider, T., Lauber, P., Rofman, B., & Villard, L. (2025). State of the art of gyrokinetic and hybrid MHD-kinetic codes through non-linear benchmarking to study reactor relevant burning plasmas. Reviews of Modern Plasma Physics, 9(1), Article 27. https://doi.org/10.1007/s41614-025-00199-2

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abstract = "After a brief introduction on present day simulation and modeling of burning plasmas in magnetically confined devices, the results of a non-linear benchmark are presented, undertaken among several state-of-the-art codes available to study the self-consistent interaction of an Energetic Particle (EP) population with shear Alfv{\'e}n waves: HYMAGYC, MEGA, ORB5 and XTOR-K. The first two codes, HYMAGYC and MEGA, are hybrid codes: HYMAGYC is a MHD-Gyrokinetic code (the bulk plasma is represented by MHD equations, while the EP species is treated using the gyrokinetic formalism), while MEGA is an MHD-Drift-Kinetic code (the bulk plasma is represented by MHD equations, while the EP species is treated using the drift-kinetic formalism, with the possibility of an ad-hoc gyroaveraging); ORB5 is a global electromagnetic gyrokinetic code (both bulk and EP species are treated using the gyrokinetic formalism); XTOR-K is a non-linear kinetic-MHD code (the bulk plasma is described by a set of non-linear resistive two-fluid MHD equations, extended to include kinetic effects of multiple ion species with a fully kinetic PIC module). The equilibrium of the so-called NLED-AUG reference case, in its version with peaked off-axis EP density profile, has been used, while considering a |n|=1 perturbation. This non-linear benchmark is the natural continuation of the linear benchmark already considered in the recent past, and represent a first-ever code comparison in the deep non-linear stage. In the present study fluid non-linearities are omitted, and the focus will be on comparing wave-particle interactions effects across codes. Characteristics of the non-linear saturation of the mode, self-consistent modification to the EP density profile and other features are compared among the considered codes. This brief review presents the state of the art of gyrokinetic and hybrid MHD-kinetic codes emerging as tools for studying reactor-relevant burning plasmas in realistic conditions.",

keywords = "Alfv{\'e}nic modes, Energetic particles, Gyrokinetic simulation, Hybrid MHD-gyrokinetic simulation, Ideal and resistive MHD modes, Kinetic-MHD simulation, Non-linear simulation, Numerical simulations, Particle-in-cell method",

author = "Gregorio Vlad and Xin Wang and Francesco Vannini and Hinrich L{\"u}tjens and Sergio Briguglio and Nakia Carlevaro and Falessi, \{Matteo V.\} and Giuliana Fogaccia and Valeria Fusco and Fulvio Zonca and Alessandro Biancalani and Alberto Bottino and Thomas Hayward-Schneider and Philipp Lauber and Baruch Rofman and Laurent Villard",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = dec,

day = "1",

doi = "10.1007/s41614-025-00199-2",

language = "English",

volume = "9",

journal = "Reviews of Modern Plasma Physics",

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Vlad, G, Wang, X, Vannini, F, Lütjens, H, Briguglio, S, Carlevaro, N, Falessi, MV, Fogaccia, G, Fusco, V, Zonca, F, Biancalani, A, Bottino, A, Hayward-Schneider, T, Lauber, P, Rofman, B & Villard, L 2025, 'State of the art of gyrokinetic and hybrid MHD-kinetic codes through non-linear benchmarking to study reactor relevant burning plasmas', Reviews of Modern Plasma Physics, vol. 9, no. 1, 27. https://doi.org/10.1007/s41614-025-00199-2

TY - JOUR

T1 - State of the art of gyrokinetic and hybrid MHD-kinetic codes through non-linear benchmarking to study reactor relevant burning plasmas

AU - Vlad, Gregorio

AU - Wang, Xin

AU - Vannini, Francesco

AU - Lütjens, Hinrich

AU - Briguglio, Sergio

AU - Carlevaro, Nakia

AU - Falessi, Matteo V.

AU - Fogaccia, Giuliana

AU - Fusco, Valeria

AU - Zonca, Fulvio

AU - Biancalani, Alessandro

AU - Bottino, Alberto

AU - Hayward-Schneider, Thomas

AU - Lauber, Philipp

AU - Rofman, Baruch

AU - Villard, Laurent

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/12/1

Y1 - 2025/12/1

N2 - After a brief introduction on present day simulation and modeling of burning plasmas in magnetically confined devices, the results of a non-linear benchmark are presented, undertaken among several state-of-the-art codes available to study the self-consistent interaction of an Energetic Particle (EP) population with shear Alfvén waves: HYMAGYC, MEGA, ORB5 and XTOR-K. The first two codes, HYMAGYC and MEGA, are hybrid codes: HYMAGYC is a MHD-Gyrokinetic code (the bulk plasma is represented by MHD equations, while the EP species is treated using the gyrokinetic formalism), while MEGA is an MHD-Drift-Kinetic code (the bulk plasma is represented by MHD equations, while the EP species is treated using the drift-kinetic formalism, with the possibility of an ad-hoc gyroaveraging); ORB5 is a global electromagnetic gyrokinetic code (both bulk and EP species are treated using the gyrokinetic formalism); XTOR-K is a non-linear kinetic-MHD code (the bulk plasma is described by a set of non-linear resistive two-fluid MHD equations, extended to include kinetic effects of multiple ion species with a fully kinetic PIC module). The equilibrium of the so-called NLED-AUG reference case, in its version with peaked off-axis EP density profile, has been used, while considering a |n|=1 perturbation. This non-linear benchmark is the natural continuation of the linear benchmark already considered in the recent past, and represent a first-ever code comparison in the deep non-linear stage. In the present study fluid non-linearities are omitted, and the focus will be on comparing wave-particle interactions effects across codes. Characteristics of the non-linear saturation of the mode, self-consistent modification to the EP density profile and other features are compared among the considered codes. This brief review presents the state of the art of gyrokinetic and hybrid MHD-kinetic codes emerging as tools for studying reactor-relevant burning plasmas in realistic conditions.

AB - After a brief introduction on present day simulation and modeling of burning plasmas in magnetically confined devices, the results of a non-linear benchmark are presented, undertaken among several state-of-the-art codes available to study the self-consistent interaction of an Energetic Particle (EP) population with shear Alfvén waves: HYMAGYC, MEGA, ORB5 and XTOR-K. The first two codes, HYMAGYC and MEGA, are hybrid codes: HYMAGYC is a MHD-Gyrokinetic code (the bulk plasma is represented by MHD equations, while the EP species is treated using the gyrokinetic formalism), while MEGA is an MHD-Drift-Kinetic code (the bulk plasma is represented by MHD equations, while the EP species is treated using the drift-kinetic formalism, with the possibility of an ad-hoc gyroaveraging); ORB5 is a global electromagnetic gyrokinetic code (both bulk and EP species are treated using the gyrokinetic formalism); XTOR-K is a non-linear kinetic-MHD code (the bulk plasma is described by a set of non-linear resistive two-fluid MHD equations, extended to include kinetic effects of multiple ion species with a fully kinetic PIC module). The equilibrium of the so-called NLED-AUG reference case, in its version with peaked off-axis EP density profile, has been used, while considering a |n|=1 perturbation. This non-linear benchmark is the natural continuation of the linear benchmark already considered in the recent past, and represent a first-ever code comparison in the deep non-linear stage. In the present study fluid non-linearities are omitted, and the focus will be on comparing wave-particle interactions effects across codes. Characteristics of the non-linear saturation of the mode, self-consistent modification to the EP density profile and other features are compared among the considered codes. This brief review presents the state of the art of gyrokinetic and hybrid MHD-kinetic codes emerging as tools for studying reactor-relevant burning plasmas in realistic conditions.

KW - Alfvénic modes

KW - Energetic particles

KW - Gyrokinetic simulation

KW - Hybrid MHD-gyrokinetic simulation

KW - Ideal and resistive MHD modes

KW - Kinetic-MHD simulation

KW - Non-linear simulation

KW - Numerical simulations

KW - Particle-in-cell method

UR - https://www.scopus.com/pages/publications/105015694662

U2 - 10.1007/s41614-025-00199-2

DO - 10.1007/s41614-025-00199-2

M3 - Article

AN - SCOPUS:105015694662

SN - 2367-3192

VL - 9

JO - Reviews of Modern Plasma Physics

JF - Reviews of Modern Plasma Physics

IS - 1

M1 - 27

ER -

State of the art of gyrokinetic and hybrid MHD-kinetic codes through non-linear benchmarking to study reactor relevant burning plasmas

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