Alpha particle driven Alfvénic instabilities in ITER post-disruption plasmas

Lier, A.; Papp, G.; Lauber, P.; Embréus, Ola; Wilkie, George; Braun, Stefanie

doi:10.1088/1741-4326/ac054c

Cited by 4 publications

(12 citation statements)

References 74 publications

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“…CODION [57] is a numerical Fokker-Planck solver able to calculate an ion distribution under the influence of an external electric field and small-angle collisions with thermal background populations. It has been equipped with a fusion alpha source [9] and is therefore a good fit to validate our model and test the isotropy assumption. With its ability to resolve the ion distribution in pitch-angle, the influence of electric fields can be studied.…”

Section: Validation Of the Reduced Energetic Tail Modelmentioning

confidence: 99%

“…Theoretical predictions [47] show that the instability drive coming from alpha particles in an ITER plasma are on par with background damping in the hot D-T phase. The damping however originates from the bulk plasma and its efficiency drops dramatically during the TQ [9]. Together with the knowledge that alpha particles resist the thermalization for a significant amount of time (see section 2), there is an opportunity for modes to be driven unstable during the TQ of a disrupting plasma.…”

Section: Alpha Particle Interaction With Alfvénic Modes In Mitigated ...mentioning

confidence: 99%

“…A plasma equilibrium can be described by magnetic flux surfaces of constant pressure and calculated via the Grad-Shafranov equation [11], requiring the input of profiles of current density and pressure. A plasma equilibrium valid for the TQ was reconstructed (using VMEC [66]) for the preceding study on unmitigated disruptions [9]. The pressure-profile used for the reconstruction consists of a thermal background pressure p 1 = 2n e0 T 1 (r, t N = 3) and an alpha particle pressure obtained from CODION.…”

Section: The Spectrum Of Weakly Damped Taesmentioning

confidence: 99%

“…In this paper we discuss an inherent mechanism, which could aid disruption mitigation efforts, but my also aggravate the issue. The phenomenon was originally introduced and investigated in a previous proof-of-principle study [9] and is followed up in this paper.…”

Section: Introductionmentioning

confidence: 99%

“…The destabilizing effect is counteracted by Landau damping effects coming from the bulk plasma. In the initial phase of a disruption-the thermal quench (TQ)the temperature-sensitive ion Landau damping [49] strongly decreases and was shown [9] to allow the resonant alpha particle drive to destabilize Toroidicity-induced Alfvén Eigenmodes [49] (TAEs) in the weakly damped plasma. The perturbations reach amplitudes significant for RE suppression [5,21,50] and occur during the formation of the RE beam [9].…”

Section: Introductionmentioning

confidence: 99%

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The impact of fusion-born alpha particles on runaway electron dynamics in ITER disruptions

et al. 2023

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In the event of a tokamak disruption in a D-T plasma, fusion-born alpha particles take several milliseconds longer to thermalise than the background. As the damping rates drop drastically following the several orders of magnitudes drop of temperature, Toroidal Alfvén Eigenmodes (TAEs) can be driven by alpha particles in the collapsing plasma before the onset of the current quench. We employ kinetic simulations of the alpha particle distribution and show that the TAEs can reach sufficiently strong saturation amplitudes to cause significant core runaway electron (RE) transport in unmitigated ITER disruptions. As the eigenmodes do not extend to the plasma edge, this effect leads to an increase of the RE plateau current. Mitigation via massive material injection however changes the Alfvén frequency and can lead to mode suppression. A combination of the TAE-caused core RE transport with other perturbation sources could lead to a drop of runaway current in unmitigated disruptions.

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Section: Validation Of the Reduced Energetic Tail Modelmentioning

confidence: 99%

Section: Alpha Particle Interaction With Alfvénic Modes In Mitigated ...mentioning

confidence: 99%

Section: The Spectrum Of Weakly Damped Taesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The impact of fusion-born alpha particles on runaway electron dynamics in ITER disruptions

et al. 2023

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Parametric study of Alfvénic instabilities driven by runaway electrons during the current quench in DIII-D

et al. 2023

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To avoid or mitigate runaway electron (RE) beams in ITER, RE-driven instabilities are actively studied as a complimentary technique to massive material injection. In this work we report experimental dependencies of Alfvénic instabilities driven by REs during the current quench in DIII-D on plasma and material injection parameters. These instabilities, observed in the frequency range of 0.1–3 MHz, correlate with increased RE loss and thus may play a role in non-sustained RE beams. It was found that as the toroidal magnetic field (BT) decreases, the RE population becomes more energetic, the energy of instabilities increases, and no RE beam is observed when the maximum energy of REs exceeds 15 MeV (or when BT is below 1.8 T). Analysis of disruptions at plasma core temperature (Te) of 1 keV and 8 keV shows that the RE population is much less energetic (with the maximum energy of only about 3 MeV) when Te is high, and no instabilities are observed in this case. Besides disruptions above caused by Ar injection, cases with Ne and D2 injections were also studied. Both Ne and D2 injections cause no sustained RE beams, however, by different reasons. Measurements of the instability polarization indicates that it is of predominantly compressional nature at the edge which is consistent with modeling suggesting excitation of compressional Alfvén eigenmodes. However, drive of global Alfvén eigenmodes is also possible at low frequencies.

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Characteristics of the Alfvénic activity during the current quench in ASDEX Upgrade

Heinrich,

Papp,

Lauber

et al. 2024

Nucl. Fusion

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ASDEX Upgrade has developed multiple massive gas injection (MGI) scenarios to investigate runaway electron (RE) dynamics. During the current quench of the MGI induced disruptions, Alfvénic activity is observed in the 300–800 kHz range. With the help of a mode tracing algorithm based on Fourier spectrograms, mode behaviour was classified for 180 discharges. The modes have been identified as global Alfvén eigenmodes using linear gyrokinetic MHD simulations. Changes in the Alfvén continuum during the quench are proposed as explanation for the strong frequency sweep observed. A systematic statistical analysis shows no significant connection of the mode characteristics to the dynamics of the subsequent runaway electron beams. In our studies, the appearance and amplitude of the modes does not seem to affect the potential subsequent runaway beam. Beyond the scope of the 180 investigated dedicated RE experiments, the Alfvénic activity is also observed in natural disruptions with no RE beam forming.

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Alpha particle driven Alfvénic instabilities in ITER post-disruption plasmas

Cited by 4 publications

References 74 publications

The impact of fusion-born alpha particles on runaway electron dynamics in ITER disruptions

The impact of fusion-born alpha particles on runaway electron dynamics in ITER disruptions

Parametric study of Alfvénic instabilities driven by runaway electrons during the current quench in DIII-D

Characteristics of the Alfvénic activity during the current quench in ASDEX Upgrade

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