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Main Authors: Singh, L., De Bastiani, M., Bonifetto, R., Subba, F., Borgogno, D.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.20502
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author Singh, L.
De Bastiani, M.
Bonifetto, R.
Subba, F.
Borgogno, D.
author_facet Singh, L.
De Bastiani, M.
Bonifetto, R.
Subba, F.
Borgogno, D.
contents The study assessed the damage caused by Runaway Electrons (RE) on First Wall tiles, comparing the effects on Beryllium and Tungsten. This was done by using realistic RE energy distribution functions to replicate RE impacts through the FLUKA code. These energy distribution functions are based on the ASDEX Upgrade experiment # 39012. The parametric analysis carried out with FLUKA in the presence of magnetic fields indicated a clear relationship between the beam impact angle and the material deposited energy, demonstrating that higher impact angles lead to deeper electron penetration and greater deposited energies. A finite element model based on apparent heat capacity formulation in FreeFem++ was developed to analyze the material thermal response to such thermal loads using volumetric energy density profiles from FLUKA simulations as input. Different RE current values were simulated to show its influence on the evolution of the material temperature and melting thickness
format Preprint
id arxiv_https___arxiv_org_abs_2508_20502
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Assessment of the Runaway Electrons induced damage to the Tokamak First Wall
Singh, L.
De Bastiani, M.
Bonifetto, R.
Subba, F.
Borgogno, D.
Plasma Physics
The study assessed the damage caused by Runaway Electrons (RE) on First Wall tiles, comparing the effects on Beryllium and Tungsten. This was done by using realistic RE energy distribution functions to replicate RE impacts through the FLUKA code. These energy distribution functions are based on the ASDEX Upgrade experiment # 39012. The parametric analysis carried out with FLUKA in the presence of magnetic fields indicated a clear relationship between the beam impact angle and the material deposited energy, demonstrating that higher impact angles lead to deeper electron penetration and greater deposited energies. A finite element model based on apparent heat capacity formulation in FreeFem++ was developed to analyze the material thermal response to such thermal loads using volumetric energy density profiles from FLUKA simulations as input. Different RE current values were simulated to show its influence on the evolution of the material temperature and melting thickness
title Assessment of the Runaway Electrons induced damage to the Tokamak First Wall
topic Plasma Physics
url https://arxiv.org/abs/2508.20502