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Numerical studies of plasma edge in W7-X with 3D FINDIF code

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EN
Abstrakty
EN
Modelling of the plasma transport for inherently three-dimensional (3D) problems as in stellarators requires dedicated complex codes. FINDIF is a 3D multifl uid plasma edge transport code that has been previously successfully used for the analysis of energy transport in the TEXTOR-DED tokamak [1], where 3D perturbations led to an ergodic structure of fi eld lines in the plasma edge. The ongoing efforts to apply it meaningfully to Wendelstein 7-X (W7-X) plasma problems resulted in advancements in the main model and accompanying tools for mesh generation and post-processing. In order to verify the applicability of the code and to compare with the reported simulation (EMC3-EIRENE) and experimental (OP1.1) results, a series of simulations for varying plasma density, temperature and anomalous transport coeffi cients as well as for fi xed input power were performed. The connection length pattern of FINDIF traced magnetic fi eld lines on the limiter was reproduced and its impact on heat loads was confi rmed. An increase in the peak heat load on the limiter with a rise in plasma density, temperature and anomalous plasma transport coeffi cients was observed. The decay lengths of density, electron temperature and heat fl ux did not change with density, and were decreasing with temperature and increasing with anomalous plasma transport coeffi cient, which was compared to the simple scrape-off layer (SOL) model.
Słowa kluczowe
Czasopismo
Rocznik
Strony
83--90
Opis fizyczny
Bibliogr. 17 poz., rys.
Twórcy
  • Institute of Plasma Physics and Laser Microfusion Hery 23 St., 01-497 Warsaw, Poland
  • Institute of Plasma Physics and Laser Microfusion Hery 23 St., 01-497 Warsaw, Poland
  • Max-Planck-Institut für Plasmaphysik Greifswald, Germany
  • Institute of Physics, University of Szczecin Szczecin, Poland
Bibliografia
  • 1. Zagórski, R., Jakubowski, M. W., Kalentev, A., Schmitz, O., Schneider, R., & Stępniewski, W. (2008).D numerical simulations of energy transport in the stochastic boundary of TEXTOR-DED with a finite difference method. Nucl. Fusion, 48(2), 024013.
  • 2. Feng, Y., Sardei, F., Kisslinger, J., & Grigull, P. (1997). A 3D Monte Carlo code for plasma transport in Island divertors. J. Nucl. Mater., 241, 930–934.
  • 3. Effenberg, F., Feng, Y., Schmitz, O., Frerichs, H., Bozhenkov, S. A., Hölbe, H., König, R., Krychowiak,M., Sunn Pedersen, T., Reiter, D., Stephey, L., & W7-XTeam. (2017). Numerical investigation of plasma Edge transport and limiter heat fluxes in Wendelstein 7-X start-up plasmas with EMC3-EIRENE. Nucl. Fusion, 57(3), 036021.
  • 4. Niemann, H., Jakubowski, M. W., Effenberg, F., Bozhenkov, S. A., Cannas, B., Carralero, D., Langenberg, A., Pisano, F., Rahbarnia, K., Rudischhauser, L., Stange, T., Warmer, F., Wurden, G. A., & W7-X Team. (2019). Features of near and far scrape-off layer heat fluxes on the Wendelstein 7-X inboard limiters. Nucl. Fusion, 60(1), 016014.
  • 5. Kalentev, O. (2008). A finite difference code for 3D plasma edge modelling. Doctoral dissertation, ErnstMoritz-Arndt-Universität Greifswald, Greifswald.
  • 6. Braginskii, S. I., & Leontovich, M. A. (1965). Transport processes in a plasma. In M. A. Leontovich (Ed.), Reviews of plasma physics (Vol. 1, pp. 205–311). NewYork: Consultants Bureau.
  • 7. Schneider, R., Bonnin, X., Borrass, K., Coster, D., Kastelewicz, H., Reiter, D., Rozhansky, V., & Braams, B. (2006). Plasma edge physics with B2-EIRENE. Contrib. Plasma Phys., 46(1/2), 3–191.
  • 8. Zagórski, R., Stępniewski, W., Jakubowski, M., McTaggart, N., Schneider, R., & Xanthopoulos, P. (2006). Application of the 3D finite difference scheme to the TEXTOR-DED geometry. Contrib. Plasma Phys., 46(7/9), 563–569.
  • 9. Pełka, G., Stępniewski, W., & Zagórski, R. (2017). Automated mesh production for limiter Wendelstein-7X configuration. Probl. Atom. Sci. Tech., 23(1), 25–27.
  • 10. Pełka, G., Stępniewski, W., & Zagórski, R. (2019). FINDIF code simulations of OP-1.1 Wendelstein 7-X discharges. Probl. Atom. Sci. Tech., 119(1), 27–29.
  • 11. McTaggart, N., Zagórski, R., Bonnin, X., Runov, A., Schneider, R., Kaiser, T., Rognlien, T., & Umansky, M. (2005). 3D edge energy transport in stellarator configurations. J. Nucl. Mater., 337, 221–226.
  • 12. McTaggart, N., Zagórski, R., Bonnin, X., Runov, A., & Schneider, R. (2004). Finite difference scheme for solving general 3D convection–diffusion equation. Comp. Phys. Commun., 164(1/3), 318–329.
  • 13. Pedersen, T. S., Andreeva, T., Bosch, H. S., Bozhenkov, S., Effenberg, F., Endler, M., Feng, Y., Gates, D. A., Geiger, J., Hartmann, D., Holbe, H., Jakubowski, M., König, R., Laqua, H. P., Lazerson, S., Otte, M., Preynas, M., Schmitz, O., Stange, T., & Turkin, Y. (2015). Plans for the fi rst plasma operation of Wendelstein 7-X. Nucl. Fusion, 55(12), 126001.
  • 14. Bozhenkov, S., Effenberg, F., Feng, Y., Geiger, J., Hartmann, D. A., Hölbe, H., Pedersen, T. S., & Wolf, R. C. (2014). Limiter for the early operation phase of W7-X. In 41st EPS Conference on Plasma Physics, Berlin.
  • 15. Klinger, T., Alonso, A., Bozhenkov, S., Burhenn, R., Dinklage, A., Fuchert, G., Geiger, J., Grulke, O., Langenberg, A., Hirsch, M., Kocsis, G., Knauer, J., Kramer-Flecken, A., Laqua, H., Lazerson, S., Landreman,M., Maassberg, H., Marsen, S., Otte, M., Pablant, N., Pasch, E., Rahbarnia, K., Stange, T., Szepesi, T., Thomsen, H., Traverso, P., Velasco, J. L., Wauters, T., Weir, G., Windisch, T., & W7-X Team. (2016). Performance and properties of the fi rst plasmas of Wendelstein 7-X. Plasma Phys. Contr. F., 59(1), 014018.
  • 16. Chmielewski, P., Zagórski, R., Telesca, G., Brix, M., Huber, A., Ivanova-Stanik, I., Kowalska-Strzeciwilk, E., Pereira, T., Refy, D. I., Tamain, P., Vecsei, M., Vianello, N., & the JET Contributors. (2021). TECXY simulations of Ne seeding in JET high power scenarios. Nuclear Materials and Energy, 27, 100962.
  • 17. Stangeby, P. C. (2000). The plasma boundary of magnetic fusion devices. (Plasma Physics Series, Vol. 224). Philadelphia, Pennsylvania: IOP Publishing.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
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bwmeta1.element.baztech-1d11149f-1994-4df8-93b0-a8a6efa2af3c
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