Drift effects on W7-X divertor heat and particle fluxes

G. A. Wurden; K. C. Hammond; Y. Gao; M. Jakubowski; C. Killer; H. Niemann; L. Rudischhauser; A. Ali; T. Andreeva; B. D. Blackwell; K. J. Brunner; B. Cannas; P. Drewelow; P. Drews; M. Endler; Y. Feng; J. Geiger; O. Grulke; J. Knauer; S. Klose; S. Lazerson; M. Otte; F. Pisano; U. Neuner; A. Puig Sitjes; K. Rahbarnia; J. Schilling; H. Thomsen

doi:10.1088/1361-6587/ab4825

Drift effects on W7-X divertor heat and particle fluxes

G. A. Wurden, K. C. Hammond, Y. Gao, M. Jakubowski, C. Killer, H. Niemann, L. Rudischhauser, A. Ali, T. Andreeva, B. D. Blackwell, K. J. Brunner, B. Cannas, P. Drewelow, P. Drews, M. Endler, Y. Feng, J. Geiger, O. Grulke, J. Knauer, S. KloseS. Lazerson, M. Otte, F. Pisano, U. Neuner, A. Puig Sitjes, K. Rahbarnia, J. Schilling, H. Thomsen

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Abstract

Classical particle drifts are known to have substantial impacts on fluxes of particles and heat through the edge plasmas in both tokamaks and stellarators. Here we present results from the first dedicated investigation of drift effects in the W7-X stellarator. By comparing similar plasma discharges conducted with a forward- and reverse-directed magnetic field, the impacts of drifts could be isolated through the observation of up-down asymmetries in flux profiles on the divertor targets. In low-density plasmas, the radial locations of the strike lines (i.e. peaks in the target heat flux profiles) exhibited discrepancies of up to 3 cm that reversed upon magnetic field reversal. In addition, asymmetric heat loads were observed in regions of the target that are shadowed by other targets from parallel flux from the core plasma. A comparison of these asymmetric features with the footprints of key topological regions of the edge magnetic field on the divertor suggests that the main driver of the asymmetries at low density is poloidal E B drift due to radial electric fields in the scrape-off layer and private flux region. In higher-density plasmas, upper and lower targets collected non-ambipolar currents with opposite signs that also inverted upon field reversal. Overall, in these experiments, almost all up-down asymmetry could be attributed to the field reversal and, therefore, field-dependent drifts.

Original language	English (US)
Article number	125001
Journal	Plasma Physics and Controlled Fusion
Volume	61
Issue number	12
DOIs	https://doi.org/10.1088/1361-6587/ab4825
State	Published - Oct 23 2019

All Science Journal Classification (ASJC) codes

Nuclear Energy and Engineering
Condensed Matter Physics

Keywords

W7-X
divertor
drift
edge plasma
stellarator
up-down asymmetry

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10.1088/1361-6587/ab4825

Cite this

Wurden, G. A., Hammond, K. C., Gao, Y., Jakubowski, M., Killer, C., Niemann, H., Rudischhauser, L., Ali, A., Andreeva, T., Blackwell, B. D., Brunner, K. J., Cannas, B., Drewelow, P., Drews, P., Endler, M., Feng, Y., Geiger, J., Grulke, O., Knauer, J., ... Thomsen, H. (2019). Drift effects on W7-X divertor heat and particle fluxes. Plasma Physics and Controlled Fusion, 61(12), Article 125001. https://doi.org/10.1088/1361-6587/ab4825

@article{bc2682c7a6f545709f779c9b90cdec2c,

title = "Drift effects on W7-X divertor heat and particle fluxes",

abstract = "Classical particle drifts are known to have substantial impacts on fluxes of particles and heat through the edge plasmas in both tokamaks and stellarators. Here we present results from the first dedicated investigation of drift effects in the W7-X stellarator. By comparing similar plasma discharges conducted with a forward- and reverse-directed magnetic field, the impacts of drifts could be isolated through the observation of up-down asymmetries in flux profiles on the divertor targets. In low-density plasmas, the radial locations of the strike lines (i.e. peaks in the target heat flux profiles) exhibited discrepancies of up to 3 cm that reversed upon magnetic field reversal. In addition, asymmetric heat loads were observed in regions of the target that are shadowed by other targets from parallel flux from the core plasma. A comparison of these asymmetric features with the footprints of key topological regions of the edge magnetic field on the divertor suggests that the main driver of the asymmetries at low density is poloidal E B drift due to radial electric fields in the scrape-off layer and private flux region. In higher-density plasmas, upper and lower targets collected non-ambipolar currents with opposite signs that also inverted upon field reversal. Overall, in these experiments, almost all up-down asymmetry could be attributed to the field reversal and, therefore, field-dependent drifts.",

keywords = "W7-X, divertor, drift, edge plasma, stellarator, up-down asymmetry",

author = "Wurden, \{G. A.\} and Hammond, \{K. C.\} and Y. Gao and M. Jakubowski and C. Killer and H. Niemann and L. Rudischhauser and A. Ali and T. Andreeva and Blackwell, \{B. D.\} and Brunner, \{K. J.\} and B. Cannas and P. Drewelow and P. Drews and M. Endler and Y. Feng and J. Geiger and O. Grulke and J. Knauer and S. Klose and S. Lazerson and M. Otte and F. Pisano and U. Neuner and Sitjes, \{A. Puig\} and K. Rahbarnia and J. Schilling and H. Thomsen",

note = "Publisher Copyright: {\textcopyright} Max-Planck-Institut fuer Plasmaphysik.",

year = "2019",

month = oct,

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doi = "10.1088/1361-6587/ab4825",

language = "English (US)",

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Wurden, GA, Hammond, KC, Gao, Y, Jakubowski, M, Killer, C, Niemann, H, Rudischhauser, L, Ali, A, Andreeva, T, Blackwell, BD, Brunner, KJ, Cannas, B, Drewelow, P, Drews, P, Endler, M, Feng, Y, Geiger, J, Grulke, O, Knauer, J, Klose, S, Lazerson, S, Otte, M, Pisano, F, Neuner, U, Sitjes, AP, Rahbarnia, K, Schilling, J & Thomsen, H 2019, 'Drift effects on W7-X divertor heat and particle fluxes', Plasma Physics and Controlled Fusion, vol. 61, no. 12, 125001. https://doi.org/10.1088/1361-6587/ab4825

TY - JOUR

T1 - Drift effects on W7-X divertor heat and particle fluxes

AU - Wurden, G. A.

AU - Hammond, K. C.

AU - Gao, Y.

AU - Jakubowski, M.

AU - Killer, C.

AU - Niemann, H.

AU - Rudischhauser, L.

AU - Ali, A.

AU - Andreeva, T.

AU - Blackwell, B. D.

AU - Brunner, K. J.

AU - Cannas, B.

AU - Drewelow, P.

AU - Drews, P.

AU - Endler, M.

AU - Feng, Y.

AU - Geiger, J.

AU - Grulke, O.

AU - Knauer, J.

AU - Klose, S.

AU - Lazerson, S.

AU - Otte, M.

AU - Pisano, F.

AU - Neuner, U.

AU - Sitjes, A. Puig

AU - Rahbarnia, K.

AU - Schilling, J.

AU - Thomsen, H.

PY - 2019/10/23

Y1 - 2019/10/23

N2 - Classical particle drifts are known to have substantial impacts on fluxes of particles and heat through the edge plasmas in both tokamaks and stellarators. Here we present results from the first dedicated investigation of drift effects in the W7-X stellarator. By comparing similar plasma discharges conducted with a forward- and reverse-directed magnetic field, the impacts of drifts could be isolated through the observation of up-down asymmetries in flux profiles on the divertor targets. In low-density plasmas, the radial locations of the strike lines (i.e. peaks in the target heat flux profiles) exhibited discrepancies of up to 3 cm that reversed upon magnetic field reversal. In addition, asymmetric heat loads were observed in regions of the target that are shadowed by other targets from parallel flux from the core plasma. A comparison of these asymmetric features with the footprints of key topological regions of the edge magnetic field on the divertor suggests that the main driver of the asymmetries at low density is poloidal E B drift due to radial electric fields in the scrape-off layer and private flux region. In higher-density plasmas, upper and lower targets collected non-ambipolar currents with opposite signs that also inverted upon field reversal. Overall, in these experiments, almost all up-down asymmetry could be attributed to the field reversal and, therefore, field-dependent drifts.

AB - Classical particle drifts are known to have substantial impacts on fluxes of particles and heat through the edge plasmas in both tokamaks and stellarators. Here we present results from the first dedicated investigation of drift effects in the W7-X stellarator. By comparing similar plasma discharges conducted with a forward- and reverse-directed magnetic field, the impacts of drifts could be isolated through the observation of up-down asymmetries in flux profiles on the divertor targets. In low-density plasmas, the radial locations of the strike lines (i.e. peaks in the target heat flux profiles) exhibited discrepancies of up to 3 cm that reversed upon magnetic field reversal. In addition, asymmetric heat loads were observed in regions of the target that are shadowed by other targets from parallel flux from the core plasma. A comparison of these asymmetric features with the footprints of key topological regions of the edge magnetic field on the divertor suggests that the main driver of the asymmetries at low density is poloidal E B drift due to radial electric fields in the scrape-off layer and private flux region. In higher-density plasmas, upper and lower targets collected non-ambipolar currents with opposite signs that also inverted upon field reversal. Overall, in these experiments, almost all up-down asymmetry could be attributed to the field reversal and, therefore, field-dependent drifts.

KW - W7-X

KW - divertor

KW - drift

KW - edge plasma

KW - stellarator

KW - up-down asymmetry

UR - https://www.scopus.com/pages/publications/85072708079

UR - https://www.scopus.com/inward/citedby.url?scp=85072708079&partnerID=8YFLogxK

U2 - 10.1088/1361-6587/ab4825

DO - 10.1088/1361-6587/ab4825

M3 - Article

AN - SCOPUS:85072708079

SN - 0741-3335

VL - 61

JO - Plasma Physics and Controlled Fusion

JF - Plasma Physics and Controlled Fusion

IS - 12

M1 - 125001

ER -

Drift effects on W7-X divertor heat and particle fluxes

Abstract

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