Physics of toroidal gap heat loading on castellated plasma-facing components

0509927 - ÚFP 2020 RIV US eng J - Journal Article
Dejarnac, Renaud - Gunn, J. P. - Vondráček, Petr - Komm, Michael - Pánek, Radomír - Pitts, R.A.
Physics of toroidal gap heat loading on castellated plasma-facing components.
Nuclear Materials and Energy. Roč. 19, May (2019), s. 19-27. E-ISSN 2352-1791
R&D Projects: GA ČR(CZ) GA16-14228S; GA MŠMT(CZ) 8D15001; GA MŠMT(CZ) LM2015045
EU Projects: European Commission(XE) 633053 - EUROfusion
Institutional support: RVO:61389021
Keywords : castellated plasma-facing components * toroidal gap heat
OECD category: Fluids and plasma physics (including surface physics)
Impact factor: 2.213, year: 2019
Method of publishing: Open access
https://www.sciencedirect.com/science/article/pii/S2352179118301844?via%3Dihub

Because the gaps between plasma-facing components in fusion devices are comparable in size to the ion Larmor radius (of the order of 1 mm), magnetic field line tracing, the so-called optical approximation, cannot accurately predict the fine scale heat load distribution around the gap edges. Finite Larmor radius effects dominate ion deposition. The poloidal component of the ion flux striking the surface is always in the diamagnetic/EXB drift direction, meaning that ions preferentially load one side of the gap. Usually electrons can be described optically due to their smaller Larmor radius. Depending on the local inclination of magnetic flux surfaces, it is possible that ions and electrons wet the same side of the gap, or opposite sides. Two-dimensional particle-in-cell simulations and dedicated experiments performed in the COMPASS tokamak are used to better understand processes responsible for plasma deposition on the sides of toroidal gaps between castellated plasma-facing components in tokamaks. The different contributions of the total incoming flux along a toroidal gap have been observed experimentally for the first time in COMPASS. These experimental results confirm the model predictions, demonstrating that in specific cases the heat deposition does not necessarily follow the optical approximation. The role played by electric fields in the deposition pattern is marginal, contrary to local non-ambipolarity that can change the asymmetrical plasma deposition from one side of the toroidal gap to the other.
Permanent Link: http://hdl.handle.net/11104/0300517