TY - JOUR
T1 - Performance of tungsten plasma facing components in the stellarator experiment W7-X
T2 - Recent results from the first OP2 campaign
AU - the W7-X Team
AU - Naujoks, Dirk
AU - Dhard, Chandra Prakash
AU - Feng, Yuhe
AU - Gao, Yu
AU - Stange, Torsten
AU - Buttenschön, Birger
AU - Bozhenkov, Sergey A.
AU - Brezinsek, Sebastijan
AU - Brunner, Kai Jakob
AU - Cseh, Gábor
AU - Dinklage, Andreas
AU - Ennis, David
AU - Fellinger, Joris
AU - Flom, Eric
AU - Gradic, Dorothea
AU - Grigore, Eduard
AU - Hartmann, Dirk
AU - Henke, Frederik
AU - Jakubowski, Marcin
AU - Kharwandikar, Amit
AU - Khokhlov, Mikhail
AU - Knauer, Jens
AU - Kocsis, Gábor
AU - Kornejew, Petra
AU - Krychowiak, Maciej
AU - Mayer, Matej
AU - McNeely, Paul
AU - Medina, Daniel
AU - Neu, Rudolf
AU - Rahbarnia, Kian
AU - Ruset, Cristian
AU - Rust, Norbert
AU - Scholz, Peter
AU - Sieber, Thomas
AU - Stepanov, Ivan
AU - Tamura, Naoki
AU - Wang, Erhui
AU - Wegner, Thomas
AU - Zhang, Daihong
N1 - Publisher Copyright:
© 2023 The Authors
PY - 2023/12
Y1 - 2023/12
N2 - The transition to reactor-relevant materials for the plasma facing components (PFCs) is an important and necessary step to provide a proof of principle that the stellarator concept can meet the requirements of a future fusion reactor by demonstrating high performance steady-state operation. As a first step to gain experience with tungsten as plasma-facing material in the Wendelstein 7-X (W7-X) stellarator, graphite tiles coated with an approximately 10 µm MedC tungsten layer (NILPRP Bucharest) were installed to complete the ECRH beam dump area in two of the five plasma vessel modules over an area of approximately one square meter each. In addition, tungsten baffle tiles are installed (40 tiles in total) with either bulk tungsten as part of NBI shine-through target or with a tungsten heavy alloy (W95-Ni3.5-Cu1.5) to replace the graphite tiles that were previously thermally overloaded. Based on an advanced diffusive field line tracing method and EMC3-Eirene simulations, the overloaded baffle tiles were redesigned by making the tiles thinner (i.e. moving the plasma-facing surface (PFS) away from the hot plasma region) and by reducing the local angle of incidence through toroidal displacement of the watershed. Significant erosion of the tungsten tiles can only be expected if sputtering by impurity ions such as carbon or oxygen ions contributes. However, the resulting central concentration of tungsten and the corresponding radiation losses are expected to be marginal. The expected deposition of carbon on the tungsten surfaces in the baffle regions mitigates further the possible tungsten enrichment in the core plasma. In OP2.1, no adverse effects of the installed tungsten PFCs on the plasma performance were observed during normal plasma operation. With the design changes made in the baffle area, the predicted heat load reductions could be experimentally confirmed.
AB - The transition to reactor-relevant materials for the plasma facing components (PFCs) is an important and necessary step to provide a proof of principle that the stellarator concept can meet the requirements of a future fusion reactor by demonstrating high performance steady-state operation. As a first step to gain experience with tungsten as plasma-facing material in the Wendelstein 7-X (W7-X) stellarator, graphite tiles coated with an approximately 10 µm MedC tungsten layer (NILPRP Bucharest) were installed to complete the ECRH beam dump area in two of the five plasma vessel modules over an area of approximately one square meter each. In addition, tungsten baffle tiles are installed (40 tiles in total) with either bulk tungsten as part of NBI shine-through target or with a tungsten heavy alloy (W95-Ni3.5-Cu1.5) to replace the graphite tiles that were previously thermally overloaded. Based on an advanced diffusive field line tracing method and EMC3-Eirene simulations, the overloaded baffle tiles were redesigned by making the tiles thinner (i.e. moving the plasma-facing surface (PFS) away from the hot plasma region) and by reducing the local angle of incidence through toroidal displacement of the watershed. Significant erosion of the tungsten tiles can only be expected if sputtering by impurity ions such as carbon or oxygen ions contributes. However, the resulting central concentration of tungsten and the corresponding radiation losses are expected to be marginal. The expected deposition of carbon on the tungsten surfaces in the baffle regions mitigates further the possible tungsten enrichment in the core plasma. In OP2.1, no adverse effects of the installed tungsten PFCs on the plasma performance were observed during normal plasma operation. With the design changes made in the baffle area, the predicted heat load reductions could be experimentally confirmed.
KW - Plasma facing components
KW - Stellarator W7-X
KW - Tungsten materials
UR - http://www.scopus.com/inward/record.url?scp=85172378753&partnerID=8YFLogxK
U2 - 10.1016/j.nme.2023.101514
DO - 10.1016/j.nme.2023.101514
M3 - Article
AN - SCOPUS:85172378753
SN - 2352-1791
VL - 37
JO - Nuclear Materials and Energy
JF - Nuclear Materials and Energy
M1 - 101514
ER -