Deuterium retention in re-solidified tungsten and beryllium
Autor: | M.J. Baldwin, J.H. Yu, R.P. Doerner, M. J. Simmonds |
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Rok vydání: | 2019 |
Předmět: |
010302 applied physics
Nuclear and High Energy Physics Materials science Thermal desorption spectroscopy Materials Science (miscellaneous) Divertor Nucleation Analytical chemistry Thermal desorption chemistry.chemical_element Plasma Tungsten lcsh:TK9001-9401 01 natural sciences 010305 fluids & plasmas Nuclear Energy and Engineering chemistry Deuterium 0103 physical sciences lcsh:Nuclear engineering. Atomic power Beryllium |
Zdroj: | Nuclear Materials and Energy, Vol 18, Iss, Pp 297-306 (2019) |
ISSN: | 2352-1791 |
DOI: | 10.1016/j.nme.2019.01.011 |
Popis: | Leading edges of the ITER tungsten (W) divertor are expected to melt due to transient heat loads from edge localized modes (ELMs), and melting of the entire divertor surface will occur during vertical displacement events (VDEs) and disruptions. In addition, understanding tritium retention in plasma facing materials is critical for the successful operation of ITER due to safety reasons. Thus, the question of how melting affects hydrogenic retention is highly relevant for fusion devices. Here we use an Nd:YAG laser to melt tungsten and beryllium in vacuo, and the samples are subsequently exposed to deuterium plasma with sample temperatures ranging from 370 to 750 K. The deuterium content in re-solidified and reference (no laser) samples is measured using thermal desorption spectroscopy and modeled using TMAP-7. In all cases, the re-solidified samples have lower retention compared to the reference samples. For re-solidified tungsten, the most significant effect is in the 1.8 eV trap with peak thermal desorption temperature of ∼750 K, which had a 77% reduction in the peak release rate compared with the reference sample. SEM imaging indicates that laser melting and re-solidification of tungsten anneals intrinsic defects that act as nucleation sites for larger-scale defects that develop during plasma exposure. However, melting does not significantly affect traps with lower de-trapping energies of 1.0 eV and 1.4 eV. In beryllium, melting and cracking results in lower retention compared to the reference sample by 40%, and thermal desorption profiles indicate that the diffusion depth of deuterium into re-solidified beryllium is lower than that of the reference sample. Keywords: Tokamak plasma-material interactions, Transient heating, Laser melting, Hydrogen retention |
Databáze: | OpenAIRE |
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