Simulation of Erosion and Redeposition of Plasma Facing Materials Under Transient Plasma Instabilities

Deposition of plasma energy during off-normal fusion reactor operational events delivers a transient heat flux of up to 100 MJ/m 2 to the plasma-facing materials (PFMs). Understanding the exact material response to the extreme energy loading conditions plays a key role in establishing a realistic co...

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Bibliographic Details
Published in:IEEE transactions on plasma science 2020-06, Vol.48 (6), p.1512-1518
Main Authors: Almousa, Nouf M., Bourham, Mohamed
Format: Article
Language:English
Subjects:
Computer simulation
Deposition
Erosion and redeposition
Erosion mechanisms
Heat flux
Heat transfer
Heating systems
high energy plasma
Magnetohydrodynamic stability
Mathematical model
melt layer splashing
Melting
Plasma
Plasma sources
Plasma temperature
plasma-facing materials (PFMs)
plasma–material interaction (PMI)
Sirens
Software
Solidification
Spallation
Surface treatment
Tungsten
Vaporization
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Summary:Deposition of plasma energy during off-normal fusion reactor operational events delivers a transient heat flux of up to 100 MJ/m 2 to the plasma-facing materials (PFMs). Understanding the exact material response to the extreme energy loading conditions plays a key role in establishing a realistic computational tool that simulates the fusion plasma-material interaction. Surface damage can occur due to vaporization, melting, spallation, and liquid splatter. However, splashing mechanisms such as boiling and splattering, which result from various liquid instabilities, appear to be the main mechanism contributing to the melt layer erosion. The primary focus of this article is melting and resolidification and the effect of redeposition of the eroded material on surface erosion. A set of selected PFMs was exposed to a plasma heat flux of up to 40 GW/m 2 over a deposition duration of 200~\mu \text{s} . The source of the high energy plasma used in this article is the Surface InteRaction Experiment at North Carolina State (SIRENS) plasma source, which used to simulate disrupted plasma conditions. The underlying erosion mechanisms involved in the formation, ejection, and solidification of molten droplets are investigated using the basic plasma equations and a plasma fluid model implemented in the simulation code. The net erosion and redeposition thickness due to erosion of the vapor and melt layer have been evaluated post-plasma exposure and compared to the experimental measurements.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2020.2963844