Numerical tools for burning plasmas

The software stack under development within a European coordinated effort on tools for burning plasma modelling is presented. The project is organised as a Task (TSVV Task 10) under the new E-TASC initiative (Litaudon et al 2022 Plasma Phys. Control. Fusion 64 034005). This is a continued effort wit...

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Veröffentlicht in:	Plasma physics and controlled fusion 2023-06, Vol.65 (6), p.64001
Hauptverfasser:	Mishchenko, A, Biancalani, A, Borchardt, M, Bottino, A, Briguglio, S, Dumont, R, Ferreira, J, Graves, J P, Hayward-Schneider, T, Kleiber, R, Könies, A, Lanti, E, Lauber, Ph, Leyh, H, Lu, Z X, Lütjens, H, McMillan, B, Campos Pinto, M, Poli, E, Rettino, B, Rofman, B, Sama, J N, Slaby, C, Vannini, F, Villard, L, Vlad, G, Wang, X, Widmer, F, Zonca, F
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Sprache:	eng
Schlagworte:	burning plasma energetic particles Physics Plasma Physics simulations
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creator	Mishchenko, A Biancalani, A Borchardt, M Bottino, A Briguglio, S Dumont, R Ferreira, J Graves, J P Hayward-Schneider, T Kleiber, R Könies, A Lanti, E Lauber, Ph Leyh, H Lu, Z X Lütjens, H McMillan, B Campos Pinto, M Poli, E Rettino, B Rofman, B Sama, J N Slaby, C Vannini, F Villard, L Vlad, G Wang, X Widmer, F Zonca, F
description	The software stack under development within a European coordinated effort on tools for burning plasma modelling is presented. The project is organised as a Task (TSVV Task 10) under the new E-TASC initiative (Litaudon et al 2022 Plasma Phys. Control. Fusion 64 034005). This is a continued effort within the EUROfusion inheriting from the earlier European coordination projects as well as research projects based at various European laboratories. The ongoing work of the TSVV Tasks is supported by the Advanced Computing Hubs. Major projects requiring the high performance computing (HPC) resources are global gyrokinetic codes and global hybrid particle-magnetohydrodynamics (MHD) codes. Also applications using the integrated modelling tools, such as the Energetic-Particle Workflow, based on the ITER Integrated Modelling & Analysis Suite (IMAS), or the code package for modelling radio-frequency heating and fast-ion generation may require intensive computation and a substantial memory footprint. The continual development of these codes both on the physics side and on the HPC side allows us to tackle frontier problems, such as the interaction of turbulence with MHD-type modes in the presence of fast particles. One of the important mandated outcomes of the E-TASC project is the IMAS-enabling of EUROfusion codes and release of the software stack to the EUROfusion community.
doi_str_mv	10.1088/1361-6587/acce68
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subjects	burning plasma energetic particles Physics Plasma Physics simulations
title	Numerical tools for burning plasmas
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