Nuclear Fusion (Jan 2023)

Experiments on excitation of Alfvén eigenmodes by alpha-particles with bump-on-tail distribution in JET DTE2 plasmas

  • S.E. Sharapov,
  • H.J.C. Oliver,
  • J. Garcia,
  • D.L. Keeling,
  • M. Dreval,
  • V. Goloborod’Ko,
  • Ye.O. Kazakov,
  • V.G. Kiptily,
  • Ž. Štancar,
  • P.J. Bonofiglo,
  • R. Coelho,
  • T. Craciunescu,
  • J. Ferreira,
  • A. Figueiredo,
  • N. Fil,
  • M. Fitzgerald,
  • F. Nabais,
  • M. Nocente,
  • P.G. Puglia,
  • J. Rivero-Rodriguez,
  • P. Rodrigues,
  • M. Salewski,
  • R.A. Tinguely,
  • L.E. Zakharov,
  • JET Contributors

DOI
https://doi.org/10.1088/1741-4326/acee10
Journal volume & issue
Vol. 63, no. 11
p. 112007

Abstract

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Dedicated experiments were performed in JET DTE2 plasmas for obtaining an α -particle bump-on-tail (BOT) distribution aiming at exciting Alfvén eigenmodes (AEs). Neutral beam injection-only heating with modulated power was used so that fusion-born α -particles were the only ions present in the MeV energy range in these DT plasmas. The beam power modulation on a time scale shorter than the α -particle slowing down time was chosen for modulating the α -particle source and thus sustaining a BOT in the α -particle distribution. High-frequency modes in the toroidicity-induced Alfven eigenmode (TAE) frequency range and multiple short-lived modes in a wider frequency range have been detected in these DT discharges with interferometry, soft x-ray cameras, and reflectometry. The modes observed were localised close to the magnetic axis, and were not seen in the Mirnov coils. Analysis with the TRANSP and Fokker-Planck FIDIT codes confirms that α -particle distributions with BOT in energy were achieved during some time intervals in these discharges though no clear correlation was found between the times of the high-frequency mode excitation and the BOT time intervals. The combined magneto-hydrodynamic (MHD) and kinetic modelling studies show that the high-frequency mode in the TAE frequency range is best fitted with a TAE of toroidal mode number n = 9. This mode is driven mostly by the on-axis beam ions while the smaller drive due to the pressure gradient of α -particles allows overcoming the marginal stability and exciting the mode (Oliver et al 2023 Nucl. Fusion submitted). The observed multiple short-lived modes in a wider frequency range are identified as the on-axis kinetic AEs predicted in Rosenbluth and Rutherford (1975 Phys. Rev. Lett. 34 1428).

Keywords