Nuclear Materials and Energy (Sep 2023)

Pisces-RF: A helicon-plasma based linear-device for the study of fusion relevant plasma-materials-interactions

  • M.J. Baldwin,
  • D. Nishijima,
  • M.I. Patino,
  • G. Gunner,
  • T. Lynch,
  • F. Chang,
  • M.J. Simmonds,
  • A. Založnik,
  • S. Moore,
  • B. Schwendeman,
  • R. Ciamacco,
  • R.P. Doerner,
  • G.R. Tynan

Journal volume & issue
Vol. 36
p. 101477

Abstract

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The helicon-plasma based-linear plasma-materials-interaction device, Pisces-RF is introduced. Steady-state plasma parameters in the target region are electron density up to ∼1019 m−3, electron temperature up to ∼10 eV, and ion flux up to ∼1023 m−2s−1 in D2 and He, with an associated maximum peak target heat flux of ∼1 MWm−2 and a few MWm−2 when accelerating ions with an electrical bias. Attached and detached target plasma regimes with both gaseous species can be achieved, as characterized by high and low Te (<1eV) plasmas with high fractions of singly ionized atomic ions. The downstream target plasma is inferred to have a low concentration of condensing or sticking impurity ions (< 0.1 ppb), as confirmed by accumulation experiments on electrically-floating targets in deposition-dominated low Te plasma conditions. The validation of Pisces-RF target PMI on W is confirmed by the observation of D retention values and W fuzz-layer thicknesses, obtained in D2 and He plasmas, that are in good agreement with prior literature. Lastly, the integration of Pisces-RF with a tandem ion-accelerator, to study the synergistic effects of simultaneous displacement damage and plasma irradiation, which we refer to as burning-plasma-material-interaction (BPMI), is discussed.

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