Nuclear Materials and Energy (Aug 2017)

High-Z material erosion and its control in DIII-D carbon divertor

  • R. Ding,
  • D.L. Rudakov,
  • P.C. Stangeby,
  • W.R. Wampler,
  • T. Abrams,
  • S. Brezinsek,
  • A. Briesemeister,
  • I. Bykov,
  • V.S. Chan,
  • C.P. Chrobak,
  • J.D. Elder,
  • H.Y. Guo,
  • J. Guterl,
  • A. Kirschner,
  • C.J. Lasnier,
  • A.W. Leonard,
  • M.A. Makowski,
  • A.G. McLean,
  • P.B. Snyder,
  • D.M. Thomas,
  • D. Tskhakaya,
  • E.A. Unterberg,
  • H.Q. Wang,
  • J.G. Watkins

Journal volume & issue
Vol. 12
pp. 247 – 252

Abstract

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As High-Z materials will likely be used as plasma-facing components (PFCs) in future fusion devices, the erosion of high-Z materials is a key issue for high-power, long pulse operation. High-Z material erosion and redeposition have been studied using tungsten and molybdenum coated samples exposed in well-diagnosed DIII-D divertor plasma discharges. By coupling dedicated experiments and modelling using the 3D Monte Carlo code ERO, the roles of sheath potential and background carbon impurities in determining high-Z material erosion are identified. Different methods suggested by modelling have been investigated to control high-Z material erosion in DIII-D experiments. The erosion of Mo and W is found to be strongly suppressed by local injection of methane and deuterium gases. The 13C deposition resulting from local 13CH4 injection also provides information on radial transport due to E ×B drifts and cross field diffusion. Finally, D2 gas puffing is found to cause local plasma perturbation, suppressing W erosion because of the lower effective sputtering yield of W at lower plasma temperature and for higher carbon concentration in the mixed surface layer.