Investigation of radial distribution of atomic hydrogen flux to the plasma facing components in steady state discharges in QUEST tokamak

Abstract One of the major challenges for the GW-class Chinese Fusion Engineering Testing Reactor (CFETR) is to efficiently handle huge power fluxes on plasma-facing components (PFCs), especially the divertor targets. This work investigates the effects of two candidate radiation impurity species, argon (Ar) and neon (Ne), with two different divertor geometries (baseline and long leg divertor geometry) on the reduction of steady-state power load to divertor targets in CFETR by using the SOLPS-ITER code package with full drifts and kinetic description of neutrals. The modeling results show clearly that increasing the seeding rate of Ar or Ne with fixed fueling gas D2 injection rate reduces the target electron temperature and heat flux density for the baseline divertor geometry, which can be reduced further by higher D2 injection rate. With a high impurity seeding rate, partial detachment with steady-state power load at the divertor target below the engineering limit of 10 MWm-2 is demonstrated. In addition, the radiation efficiency for Ar is better than that for Ne. Increasing the divertor leg length reduces the electron temperature and heat load at the targets. This modeling, therefore, suggests that a long leg divertor design with Ar seeding impurity is appropriate to meet the CFETR divertor requirements.

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Atomic hydrogen flux density measured using thin metal films

Technical Physics Letters ◽

10.1134/1.1631357 ◽

2003 ◽

Vol 29 (11) ◽

pp. 897-900 ◽

Cited By ~ 1

Author(s):

V. A. Kagadei ◽

E. V. Nefyodtsev ◽

D. I. Proskurovsky ◽

S. V. Romanenko

Keyword(s):

Flux Density ◽

Atomic Hydrogen ◽

Metal Films ◽

Thin Metal ◽

Thin Metal Films ◽

Hydrogen Flux

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Surface structure and morphology of InAs(111)B with/without gold nanoparticles annealed under arsenic or atomic hydrogen flux

Surface Science ◽

10.1016/j.susc.2009.11.029 ◽

2010 ◽

Vol 604 (3-4) ◽

pp. 354-360 ◽

Cited By ~ 15

Author(s):

E. Hilner ◽

E. Lundgren ◽

A. Mikkelsen

Keyword(s):

Gold Nanoparticles ◽

Surface Structure ◽

Atomic Hydrogen ◽

Hydrogen Flux ◽

Structure And Morphology

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The Effect of the Partial Pressure of H2S and CO2 on the Permeation of Hydrogen in Carbon Steel by Using Pressure Buildup Techniques

CORROSION ◽

10.5006/3128 ◽

2019 ◽

Vol 75 (10) ◽

pp. 1207-1215

Author(s):

Nayef M. Alanazi ◽

Abdullah A. Al-Enezi

Keyword(s):

Steady State ◽

Carbon Steel ◽

Corrosion Rate ◽

Partial Pressure ◽

Hydrogen Permeation ◽

Measurement Techniques ◽

Permeation Rate ◽

Pressure Buildup ◽

Hydrogen Flux ◽

The Relationship

There are concerns in the industry about using an electrochemical technique for actual hydrogen permeation measurements where charging current is not a field condition. The objective of this work is to use pressure buildup techniques to study the influence of H2S and CO2 partial pressure on the relationship between hydrogen permeation and corrosion rate measured by different techniques. Sulfide films formed on carbon steel in a solution containing 5 wt% NaCl and 0.5 wt% acidic acid at various H2S and CO2 partial pressures were characterized, and the effect of the film on hydrogen permeation was also investigated. Field conditions were included in this study for comparison purposes. The relationship was modeled at the steady state of both hydrogen flux and corrosion rate. The results confirmed by use of two hydrogen flux measurement techniques (eudiometer and high-pressure buildup probe) and two corrosion measurement methods (weight loss coupons and coupled multiarray electrode system), that there is no direct correlation between hydrogen flux and corrosion rate. Therefore, the hydrogen permeation rate in H2S and CO2 environments was found to be more controlled by partial pressure of H2S than corrosion rate. The amount of descent in hydrogen flux, after reaching maximum of hydrogen permeation rate and before reaching a steady state, depends on the morphology and structure of corrosion films which are mainly controlled by concentration of H2S.

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The radial distribution of radiation belt protons: Approximate solution of the steady state transport equation at arbitrary pitch angle

Journal of Geophysical Research Atmospheres ◽

10.1029/ja089ia03p01527 ◽

1984 ◽

Vol 89 (A3) ◽

pp. 1527 ◽

Cited By ~ 12

Author(s):

V. Jentsch

Keyword(s):

Approximate Solution ◽

Steady State ◽

Transport Equation ◽

Radial Distribution ◽

Pitch Angle ◽

Radiation Belt

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A mechanism of CVD diamond film growth deduced from the sequential deposition from sputtered carbon and atomic hydrogen

Journal of Materials Research ◽

10.1557/jmr.1994.1546 ◽

1994 ◽

Vol 9 (6) ◽

pp. 1546-1551 ◽

Cited By ~ 20

Author(s):

Darin S. Olson ◽

Michael A. Kelly ◽

Sanjiv Kapoor ◽

Stig B. Hagstrom

Keyword(s):

Growth Mechanism ◽

Atomic Hydrogen ◽

Film Growth ◽

Deposition Process ◽

Cvd Diamond ◽

Surface Growth ◽

Diamond Surface ◽

Hydrogen Flux ◽

Sequential Deposition ◽

Disordered Carbon

We describe a growth mechanism of CVD diamond films consisting of a series of surface reactions. It is derived from experimental observations of a sequential deposition process in which incident carbon flux and atomic hydrogen flux were independently varied. In this sequential process, film growth rate increased with atomic hydrogen exposure, and a saturation in the utilization of carbon was observed. These features are consistent with a surface growth process consisting of the following steps: (i) the carburization of the diamond surface, (ii) the deposition of highly disordered carbon on top of this surface, (iii) the etching of disordered carbon by atomic hydrogen, (iv) the conversion of the carburized diamond surface to diamond at growth sites by atomic hydrogen, and (v) the carburization of newly grown diamond surface. The nature of the growth sites on the diamond surface has not been determined experimentally, and the existence of the carburized surface layer has not been demonstrated experimentally. The surface growth mechanism is the only one consistent with the growth observed in conventional diamond reactors and the sequential reactor, while precluding the necessity of gas phase precursors.

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