Your search keyword '"Stechow, A. v."' showing total 6 results

1. Suppression of core turbulence by profile shaping in Wendelstein 7-X

Author

Stechow, A. v., Grulke, O., Wegner, Th., Proll, J. H. E., Alcusón, J. A., Smith, H. M., Baldzuhn, J., Beidler, C. D., Beurskens, M. N. A., Bozhenkov, S. A., Edlund, E., Geiger, B., Huang, Z., Ford, O. P., Fuchert, G., Langenberg, A., Pablant, N., Pasch, E., Porkolab, M., Rahbarnia, K., Schilling, J., Scott, E. R., Thomsen, H., Vanó, L., Weir, G., and Team, The W7-X

Subjects

Physics - Plasma Physics

Abstract

In the Wendelstein 7-X magnetic confinement experiment, a reduction of turbulent density fluctuations as well as anomalous impurity diffusion is associated with a peaking of the plasma density profile. These effects correlate with improved confinement and appear largely due to a reduction of anomalous transport as the change in neoclassical transport is small. The observed decrease of turbulent heat flux with increased density gradients is in agreement with nonlinear gyrokinetic simulations, and has been attributed to the unique geometry of W7-X that limits the severity of trapped electron modes.

Published

2020

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

Author

Wegner, Th., Alcusón, J.A., Geiger, B., Stechow, A. v., 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., and Kunkel, F.

Subjects

ELECTRON temperature, ION temperature, PLASMA flow, ELECTRON density, TEMPERATURE, DIFFUSION

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. [ABSTRACT FROM AUTHOR]

Published

2020

3. Electromagnetic fluctuations during guide field reconnection in a laboratory plasma

Author

Stechow, A. v., primary, Fox, W., additional, Jara-Almonte, J., additional, Yoo, J., additional, Ji, H., additional, and Yamada, M., additional

Published

2018

4. Heat transport and core turbulence measurements on the optimized stellarator Wendelstein 7-X

Author

Weir, G., Josefine Henriette Elise Proll, Windisch, T., Stechow, A. V., Bozhenkov, S., Dinklage, A., Edlund, E., Estrada, T., Fuchert, G., Grulke, O., Hirsch, M., Hoefel, U., Kwak, S., Langenberg, A., Pablant, N., Pasch, E., Porkolab, M., Scott, E., Smoniewski, J., Stange, T., Felix Warmer, Xanthopoulos, P., Zhang, D., Huang, Z., Klinger, T., Turbulence in Fusion Plasmas, and Science and Technology of Nuclear Fusion

Subjects

Physics::Plasma Physics

Abstract

The optimized stellarator Wendelstein 7-X (W7-X) is designed to have an approximately quasi-isodynamic (QI) magnetic configuration with reduced neoclassical transport compared to a classical stellarator, and turbulent transport is expected to be a significant source of heat transport across the plasma minor radius. The Ion Temperature Gradient (ITG) and Trapped Electron Mode (TEM) are the dominant turbulence channels in low beta W7-X plasmas, and gyrokinetic modelling indicates two major differences between ITG/TEMs in W7-X and previous tokamak and stellarator experiments. The ITG mode is predicted to be highly localized along a helical band in W7-X, causing a reduction of the associated turbulence, and the nearly QI configuration of W7-X is predicted to be resilient to collisionless TEMs. In this contribution, the electron heat transport is compared to neoclassical predictions, and the stiffness in the electron heat transport is compared to TEM/ITG mode driven turbulence in two magnetic configurations of W7-X: one nearly QI configuration as well as a configuration with deliberately reduced QI. Additionally, electron temperature and plasma density fluctuations are compared to linear and nonlinear gyrokinetic calculations to assess the stabilization of TEM turbulence in W7-X.

5. Experimental Verification of the Role of Electron Pressure in Fast Magnetic Reconnection with a Guide Field.

Author

Fox, W., Sciortino, F., Stechow, A. v., Jara-Almonte, J., Yoo, J., Ji, H., and Yamada, M.

Subjects

*ELECTRONS, *DIAMAGNETIC materials

Abstract

We report detailed laboratory observations of the structure of a reconnection current sheet in a two-fluid plasma regime with a guide magnetic field. We observe and quantitatively analyze the quadrupolar electron pressure variation in the ion-diffusion region, as originally predicted by extended magnetohydrodynamics simulations. The projection of the electron pressure gradient parallel to the magnetic field contributes significantly to balancing the parallel electric field, and the resulting cross-field electron jets in the reconnection layer are diamagnetic in origin. These results demonstrate how parallel and perpendicular force balance are coupled in guide field reconnection and confirm basic theoretical models of the importance of electron pressure gradients for obtaining fast magnetic reconnection. [ABSTRACT FROM AUTHOR]

Published

2017

6. Impact of Magnetic Field Configuration on Heat Transport in Stellarators and Heliotrons.

Author

Warmer F, Tanaka K, Xanthopoulos P, Nunami M, Nakata M, Beidler CD, Bozhenkov SA, Beurskens MNA, Brunner KJ, Ford OP, Fuchert G, Funaba H, Geiger J, Gradic D, Ida K, Igami H, Kubo S, Langenberg A, Laqua HP, Lazerson S, Morisaki T, Osakabe M, Pablant N, Pasch E, Peterson B, Satake S, Seki R, Shimozuma T, Smith HM, Stange T, Stechow AV, Sugama H, Suzuki Y, Takahashi H, Tokuzawa T, Tsujimura T, Turkin Y, Wolf RC, Yamada I, Yanai R, Yasuhara R, Yokoyama M, Yoshimura Y, Yoshinuma M, Zhang D, W-X Team, and Lhd Experimental Group

Abstract

We assess the magnetic field configuration in modern fusion devices by comparing experiments with the same heating power, between a stellarator and a heliotron. The key role of turbulence is evident in the optimized stellarator, while neoclassical processes largely determine the transport in the heliotron device. Gyrokinetic simulations elucidate the underlying mechanisms promoting stronger ion scale turbulence in the stellarator. Similar plasma performances in these experiments suggests that neoclassical and turbulent transport should both be optimized in next step reactor designs.

Published

2021