Nuclear Fusion (Jan 2024)

Orbit tomography in constants-of-motion phase-space

  • M. Rud,
  • D. Moseev,
  • F. Jaulmes,
  • K. Bogar,
  • Y. Dong,
  • P.C. Hansen,
  • J. Eriksson,
  • H. Järleblad,
  • M. Nocente,
  • G. Prechel,
  • B.C.G. Reman,
  • B.S. Schmidt,
  • A. Snicker,
  • L. Stagner,
  • A. Valentini,
  • M. Salewski

DOI
https://doi.org/10.1088/1741-4326/ad4bf4
Journal volume & issue
Vol. 64, no. 7
p. 076018

Abstract

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Tomographic reconstructions of a 3D fast-ion constants-of-motion phase-space distribution function are computed by inverting synthetic signals based on projected velocities of the fast ions along the diagnostic lines of sight. A spectrum of projected velocities is a key element of the spectrum formation in fast-ion D-alpha spectroscopy, collective Thomson scattering, and gamma-ray and neutron emission spectroscopy, and it can hence serve as a proxy for any of these. The fast-ion distribution functions are parameterised by three constants of motion, the kinetic energy, the magnetic moment and the toroidal canonical angular momentum. The reconstructions are computed using both zeroth-order and first-order Tikhonov regularisation expressed in terms of Bayesian inference to allow uncertainty quantification. In addition to this, a discontinuity appears to be present in the solution across the trapped-passing boundary surface in the three-dimensional phase space due to a singularity in the Jacobian of the transformation from position and velocity space to phase space. A method to allow for this apparent discontinuity while simultaneously penalising large gradients in the solution is demonstrated. Finally, we use our new methods to optimise the diagnostic performance of a set of six fans of sightlines by finding where the detectors contribute most complementary diagnostic information for the future COMPASS-Upgrade tokamak.

Keywords