Recent DIII-D progress toward validating models of tungsten erosion, re-deposition, and migration for application to next-step fusion devices

Abrams, T; Guterl, J G; Abe, S; Donovan, D C; Bykov, I; Johnson, C A; Nichols, J H; Elder, J D; Ennis, D A; Loch, S D; Rudakov, D L; Sinclair, G; Skinner, C H; Stangeby, P C; Thomas, D M; Unterberg, E A; Wampler, W R

doi:10.1088/2053-1591/ad0f43

Cited by 4 publications

(3 citation statements)

References 51 publications

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“…Prompt redeposition of sputtered W atoms in DIVIMP is necessary when considering absolute magnitudes of W density within the SOL. The probability of a W ion not promptly redepositing is described by the ERO scaling in [23] and experimental validation in [24]:…”

Section: Prompt Re-depositionmentioning

confidence: 99%

“…This is consistent with ERO simulations, which indicate that for DIII-D divertor conditions the re-deposition fraction is expected to be particularly large (see figures 9 and 10 in [23]). For core-edge integration, it is thus desirable to keep x = λ iz /λ sheath as as possible by using wall materials with a short λ iz or scenarios in which λ sheath is maximized [24].…”

Section: Prompt Re-deposition Of Tungstenmentioning

confidence: 99%

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Modeling turbulent impurity transport in the SOL of DIII-D with a reduced model

Zamperini,

Nichols,

Odstrcil

et al. 2024

Plasma Phys. Control. Fusion

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A novel impurity transport model that approximates SOL turbulence as a fluctuating poloidal electric field is shown to be an acceptable replacement for the traditional approach of assigning an arbitrary radial diffusion coefficient to the impurity ions. The model is implemented in the DIVIMP impurity transport code and applied to an L-Mode tungsten divertor experiment on DIII-D. The poloidal electric field is represented as fluctuating between ±1,000 V/m based on previous measurements. The resulting intermittent vr = Eθ × BT transport causes ions to transport both into the core as well as into the far-SOL. Simultaneous agreement with estimates of the W density just inside the separatrix as well as in the far-SOL is obtained (nW~1014 m-3 and nW ~ 1012 m-3, respectively). Prompt re-deposition of the W ions was necessary to obtain agreement (fredep ~ 99%). We conclude that simulating impurity transport using a physics-based approximation for turbulence in the SOL, versus arbitrarily assigning diffusion coefficients, may enable better reactor scale predictions of core impurity contamination.

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Section: Prompt Re-depositionmentioning

confidence: 99%

Section: Prompt Re-deposition Of Tungstenmentioning

confidence: 99%

Modeling turbulent impurity transport in the SOL of DIII-D with a reduced model

Zamperini,

Nichols,

Odstrcil

et al. 2024

Plasma Phys. Control. Fusion

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“…While the materials science community has a long history of conducting fundamental and applied research on plasma-materials interactions [6][7][8], this collection focuses on the same type of physics with respect to a nuclear fusion environment. The topics covered are unique to 'Plasma-Facing Materials in Nuclear Fusion Reactors' such as: deuterium and tritium retention in PFCs [9][10][11][12][13]; fundamental processes at the plasma-surface interface [10,[14][15][16][17][18][19][20]; evolution of structure and properties under fusion-reactor-relevant heat loads [21]; material degradation under ion exposure [15,16,19]; material degradation under neutron irradiation [9,21]; material erosion, migration, and deposition [14,15,18,20,22]; plasma fueling [12]; and diagnostics for plasmamaterials interactions [23]. Although the details of the underlying mechanisms that govern the above phenomena remain largely unresolved, the results presented here will drive the emergence of engineering solutions to the amelioration of plasma-facing materials degradation.…”

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confidence: 99%

Focus on plasma-facing materials in nuclear fusion reactors

Dasgupta,

Bernard,

Zhou

et al. 2024

Mater. Res. Express

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Fusion energy is a promising, safe, and reliable green energy solution to the increasing energy demand. However, there are several materials challenges that need to be overcome to increase the technical readiness to a level that enables a fusion pilot plant on the grid. This focus issue aims to identify and address a set of such key impediments for realizing deuterium-tritium (D–T) fusion power in a tokamak reactor and highlight the most recent progress on those research frontiers. The main emphasis of this collection is on materials development challenges resulting from helium irradiation, neutron-induced degradation, thermomechanical loading, and the corrosive environment faced by the divertor and first-wall materials, commonly known as plasma-facing components, and blanket systems for tokamak fusion reactors.

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