Analysis of the HAE activity in the TJ-II stellarator using a Landau closure model

J. Ortiz; J. Varela; L. Herrera Quesada; P. Pons-Villalonga; A. Cappa; U. Losada; F. Papoušek; B. Ph van Milligen; L. Garcia; D. A. Spong; Y. Ghai; M. A. Ochando; C. Hidalgo

doi:10.1063/5.0263300

Analysis of the HAE activity in the TJ-II stellarator using a Landau closure model

J. Ortiz
, J. Varela
, L. Herrera Quesada
, P. Pons-Villalonga
, A. Cappa
, U. Losada
, F. Papoušek
, B. Ph van Milligen
, L. Garcia
, D. A. Spong
, Y. Ghai
, M. A. Ochando
, C. Hidalgo

Fusion Theory and Modeling

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

Abstract

The aim of this study is to analyze the stability of helical Alfvén eigenmodes (HAEs) in TJ-II discharges and the stabilizing effect of the energetic particles generated by the neutral beam injector (NBI) on pressure gradient-driven modes (PGDMs). HAE and PGDM stability is studied using the linear version of the gyro-fluid code FAR3d and the continuous structure by the STELLGAP code. First, Alfvén eigenmode (AE) and PGDM activity observed in the experiments is reproduced by the simulations, identifying unstable m / n = 4 / 7 − 2 / 3 and 7 / 12 − 5 / 8 HAEs triggered around ρ = 0.66 showing a frequency of 209 and 204 kHz, respectively, as well as 5 / 3 PGDM. Next, a parametric study is performed with respect to the thermal ion density and iota profile in the middle-outer plasma region to verify the robustness of the simulation results with respect to the uncertainty of experimental profiles. The analysis confirms that experimental uncertainty does not cause large deviations in the simulation results, showing the destabilization of the same HAEs for all the configurations tested. The simulations also indicate the decay of the 5 / 3 PGDM growth rate as the energetic particle (EP) population in the plasma increases, consistent with the experiment. Stability analysis of the n = 3 , 7 , 11 , n = 5 , 9 , 13 , n = 6 , 10 , 14 , and n = 8 , 12 helical families is performed with respect to the NBI operational regime for different EP energies, β as well as deposition profiles. The most unstable configuration is the radially localized on-axis NBI operation (stiff EP density profile gradients nearby the magnetic axis). Using the simulation model that reproduces the observed Alfvén activity, we extend the study to analyze NBI performance within a theoretical framework. It shows that increasing NBI voltage (which raises EP energy) leads to a degradation in NBI performance for a given power (related to EP β and their density). To achieve better NBI operation, higher voltage must be balanced with lower injection power, ensuring stable AEs while keeping the same EP β .

Original language	English
Article number	072506
Journal	Physics of Plasmas
Volume	32
Issue number	7
DOIs	https://doi.org/10.1063/5.0263300
State	Published - Jul 1 2025

Funding

This research has been partially supported by the Spanish National Research Project No. PID2022-137869OB-I00, by Project No. NIFS07KLPH004 as well as by Project No. 2019-T1/AMB-13648 funded by the Comunidad de Madrid. Additional support was provided by the U.S. Department of Energy under Grant No. DE-FG02-04ER54742 and by the AIM4EP Project (ANR-21-CE30-0018), funded by the French National Research Agency (ANR). Computational resources were provided by the Uranus supercomputing cluster at Universidad Carlos III de Madrid (Spain), funded jointly by EU FEDER funds and the Spanish Government through national Project Nos. UNC313-4E-23612, ENE2009-12213-C03-03, ENE2012-33219, ENE2012-31753, and ENE2015-68265. We also thank David Zarzoso Fernández for valuable discussions regarding key aspects of the work.

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10.1063/5.0263300

Cite this

@article{81f0920081224696a800cd5c0d4004b6,

title = "Analysis of the HAE activity in the TJ-II stellarator using a Landau closure model",

abstract = "The aim of this study is to analyze the stability of helical Alfv{\'e}n eigenmodes (HAEs) in TJ-II discharges and the stabilizing effect of the energetic particles generated by the neutral beam injector (NBI) on pressure gradient-driven modes (PGDMs). HAE and PGDM stability is studied using the linear version of the gyro-fluid code FAR3d and the continuous structure by the STELLGAP code. First, Alfv{\'e}n eigenmode (AE) and PGDM activity observed in the experiments is reproduced by the simulations, identifying unstable m / n = 4 / 7 − 2 / 3 and 7 / 12 − 5 / 8 HAEs triggered around ρ = 0.66 showing a frequency of 209 and 204 kHz, respectively, as well as 5 / 3 PGDM. Next, a parametric study is performed with respect to the thermal ion density and iota profile in the middle-outer plasma region to verify the robustness of the simulation results with respect to the uncertainty of experimental profiles. The analysis confirms that experimental uncertainty does not cause large deviations in the simulation results, showing the destabilization of the same HAEs for all the configurations tested. The simulations also indicate the decay of the 5 / 3 PGDM growth rate as the energetic particle (EP) population in the plasma increases, consistent with the experiment. Stability analysis of the n = 3 , 7 , 11 , n = 5 , 9 , 13 , n = 6 , 10 , 14 , and n = 8 , 12 helical families is performed with respect to the NBI operational regime for different EP energies, β as well as deposition profiles. The most unstable configuration is the radially localized on-axis NBI operation (stiff EP density profile gradients nearby the magnetic axis). Using the simulation model that reproduces the observed Alfv{\'e}n activity, we extend the study to analyze NBI performance within a theoretical framework. It shows that increasing NBI voltage (which raises EP energy) leads to a degradation in NBI performance for a given power (related to EP β and their density). To achieve better NBI operation, higher voltage must be balanced with lower injection power, ensuring stable AEs while keeping the same EP β .",

author = "J. Ortiz and J. Varela and \{Herrera Quesada\}, L. and P. Pons-Villalonga and A. Cappa and U. Losada and F. Papou{\v s}ek and \{van Milligen\}, \{B. Ph\} and L. Garcia and Spong, \{D. A.\} and Y. Ghai and Ochando, \{M. A.\} and C. Hidalgo",

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doi = "10.1063/5.0263300",

language = "English",

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T1 - Analysis of the HAE activity in the TJ-II stellarator using a Landau closure model

AU - Ortiz, J.

AU - Varela, J.

AU - Herrera Quesada, L.

AU - Pons-Villalonga, P.

AU - Cappa, A.

AU - Losada, U.

AU - Papoušek, F.

AU - van Milligen, B. Ph

AU - Garcia, L.

AU - Spong, D. A.

AU - Ghai, Y.

AU - Ochando, M. A.

AU - Hidalgo, C.

PY - 2025/7/1

Y1 - 2025/7/1

N2 - The aim of this study is to analyze the stability of helical Alfvén eigenmodes (HAEs) in TJ-II discharges and the stabilizing effect of the energetic particles generated by the neutral beam injector (NBI) on pressure gradient-driven modes (PGDMs). HAE and PGDM stability is studied using the linear version of the gyro-fluid code FAR3d and the continuous structure by the STELLGAP code. First, Alfvén eigenmode (AE) and PGDM activity observed in the experiments is reproduced by the simulations, identifying unstable m / n = 4 / 7 − 2 / 3 and 7 / 12 − 5 / 8 HAEs triggered around ρ = 0.66 showing a frequency of 209 and 204 kHz, respectively, as well as 5 / 3 PGDM. Next, a parametric study is performed with respect to the thermal ion density and iota profile in the middle-outer plasma region to verify the robustness of the simulation results with respect to the uncertainty of experimental profiles. The analysis confirms that experimental uncertainty does not cause large deviations in the simulation results, showing the destabilization of the same HAEs for all the configurations tested. The simulations also indicate the decay of the 5 / 3 PGDM growth rate as the energetic particle (EP) population in the plasma increases, consistent with the experiment. Stability analysis of the n = 3 , 7 , 11 , n = 5 , 9 , 13 , n = 6 , 10 , 14 , and n = 8 , 12 helical families is performed with respect to the NBI operational regime for different EP energies, β as well as deposition profiles. The most unstable configuration is the radially localized on-axis NBI operation (stiff EP density profile gradients nearby the magnetic axis). Using the simulation model that reproduces the observed Alfvén activity, we extend the study to analyze NBI performance within a theoretical framework. It shows that increasing NBI voltage (which raises EP energy) leads to a degradation in NBI performance for a given power (related to EP β and their density). To achieve better NBI operation, higher voltage must be balanced with lower injection power, ensuring stable AEs while keeping the same EP β .

AB - The aim of this study is to analyze the stability of helical Alfvén eigenmodes (HAEs) in TJ-II discharges and the stabilizing effect of the energetic particles generated by the neutral beam injector (NBI) on pressure gradient-driven modes (PGDMs). HAE and PGDM stability is studied using the linear version of the gyro-fluid code FAR3d and the continuous structure by the STELLGAP code. First, Alfvén eigenmode (AE) and PGDM activity observed in the experiments is reproduced by the simulations, identifying unstable m / n = 4 / 7 − 2 / 3 and 7 / 12 − 5 / 8 HAEs triggered around ρ = 0.66 showing a frequency of 209 and 204 kHz, respectively, as well as 5 / 3 PGDM. Next, a parametric study is performed with respect to the thermal ion density and iota profile in the middle-outer plasma region to verify the robustness of the simulation results with respect to the uncertainty of experimental profiles. The analysis confirms that experimental uncertainty does not cause large deviations in the simulation results, showing the destabilization of the same HAEs for all the configurations tested. The simulations also indicate the decay of the 5 / 3 PGDM growth rate as the energetic particle (EP) population in the plasma increases, consistent with the experiment. Stability analysis of the n = 3 , 7 , 11 , n = 5 , 9 , 13 , n = 6 , 10 , 14 , and n = 8 , 12 helical families is performed with respect to the NBI operational regime for different EP energies, β as well as deposition profiles. The most unstable configuration is the radially localized on-axis NBI operation (stiff EP density profile gradients nearby the magnetic axis). Using the simulation model that reproduces the observed Alfvén activity, we extend the study to analyze NBI performance within a theoretical framework. It shows that increasing NBI voltage (which raises EP energy) leads to a degradation in NBI performance for a given power (related to EP β and their density). To achieve better NBI operation, higher voltage must be balanced with lower injection power, ensuring stable AEs while keeping the same EP β .

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U2 - 10.1063/5.0263300

DO - 10.1063/5.0263300

M3 - Article

AN - SCOPUS:105011098687

SN - 1070-664X

VL - 32

JO - Physics of Plasmas

JF - Physics of Plasmas

IS - 7

M1 - 072506

ER -

Analysis of the HAE activity in the TJ-II stellarator using a Landau closure model

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