Impact of the temperature ratio on turbulent impurity transport in Wendelstein 7-X

Wegner, Th.; Alcusón, J.A.; Geiger, B.; v. Stechow, A.; Xanthopoulos, P.; Angioni, C.; Beurskens, M.N.A.; Böttger, L.-G.; Bozhenkov, S.A.; Brunner, K.J.; Burhenn, R.; Buttenschön, B.; Damm, H.; Edlund, E.; Ford, O.P.; Fuchert, G.; Grulke, O.; Huang, Z.; Knauer, J.; Kunkel, F.; Langenberg, A.; Pablant, N.A.; Pasch, E.; Rahbarnia, K.; Schilling, J.; Thomsen, H.; Vanó, L.

View/Open

Última versión antes de la publicación. (521.7Kb)

Author

Wegner, Th.

Alcusón, J.A.

Geiger, B.

v. Stechow, A.

Xanthopoulos, P.

Angioni, C.

Beurskens, M.N.A.

Böttger, L.-G.

Bozhenkov, S.A.

Brunner, K.J.

Burhenn, R.

Buttenschön, B.

Damm, H.

Edlund, E.

Ford, O.P.

Fuchert, G.

Grulke, O.

Huang, Z.

Knauer, J.

Kunkel, F.

Langenberg, A.

Pablant, N.A.

Pasch, E.

Rahbarnia, K.

Schilling, J.

Thomsen, H.

Vanó, L.

Publisher

IOP Publishing

Date

2020

Subject

impurity transport, turbulence, ion temperature gradient instability, stellarator, laser blow-off

Abstract

First experimental observations in the Wendelstein 7-X stellarator indicate that the impurity confinement can be explained by turbulent processes. In particular, plasma discharges with increased ion to electron temperature ratio are accompanied by reduced electron density fluctuation amplitudes and anomalous impurity diffusion, suggesting a lower turbulent transport. Employing gyro-kinetic numerical simulations, we argue that the temperature ratio plays a key role for reducing the ion temperature gradient instability in Wendelstein 7-X, leading to an enhanced impurity confinement.

URI

http://hdl.handle.net/10396/30794

Fuente

Th. Wegner et al 2020 Nucl. Fusion 60 124004

Versión del Editor

https://doi.org/10.1088/1741-4326/abb869