English

Turbulence suppression by energetic particles: A sensitivity-driven dimension-adaptive sparse grid framework for discharge optimization

Plasma Physics 2021-05-26 v2

Abstract

A newly developed sensitivity-driven approach is employed to study the role of energetic particles in suppressing turbulence-inducing micro-instabilities for a set of realistic JET-like cases with NBI deuterium and ICRH 3^3He fast ions. First, the efficiency of the sensitivity-driven approach is showcased for scans in a 2121-dimensional parameter space, for which only 250250 simulations are necessary. The same scan performed with traditional Cartesian grids with only two points in each of the 2121 dimensions would require 221=2,097,1522^{21} = 2,097,152 simulations. Then, a 1414-dimensional parameter subspace is considered, using the sensitivity-driven approach to find an approximation of the parameter-to-growth rate map averaged over nine bi-normal wave-numbers, indicating pathways towards turbulence suppression. The respective turbulent fluxes, obtained via nonlinear simulations for the optimized set of parameters, are reduced by more than two order of magnitude compared to the reference results.

Keywords

Cite

@article{arxiv.2101.03636,
  title  = {Turbulence suppression by energetic particles: A sensitivity-driven dimension-adaptive sparse grid framework for discharge optimization},
  author = {Ionut-Gabriel Farcas and Alessandro Di Siena and Frank Jenko},
  journal= {arXiv preprint arXiv:2101.03636},
  year   = {2021}
}

Comments

18 pages, 7 figures

R2 v1 2026-06-23T21:58:13.980Z