Transition of poloidal viscosity by electrode biasing in the Large Helical Device

Sumio Kitajima; H. Takahashi; Keizo Ishii; Y. Sato; M. Kanno; J. Tachibana; Atsushi Okamoto; M. Sasao; S. Inagaki; M. Takayama; S. Masuzaki; M. Shoji; N. Ashikawa; M. Tokitani; M. Yokoyama; Y. Suzuki; S. Satake; T. Ido; A. Shimizu; C. Suzuki; Y. Nagayama; T. Tokuzawa; K. Nishimura; T. Morisaki

doi:10.1088/0029-5515/53/7/073014

Transition of poloidal viscosity by electrode biasing in the Large Helical Device

Sumio Kitajima, H. Takahashi, Keizo Ishii, Y. Sato, M. Kanno, J. Tachibana, Atsushi Okamoto, M. Sasao, S. Inagaki, M. Takayama, S. Masuzaki, M. Shoji, N. Ashikawa, M. Tokitani, M. Yokoyama, Y. Suzuki, S. Satake, T. Ido, A. Shimizu, C. SuzukiY. Nagayama, T. Tokuzawa, K. Nishimura, T. Morisaki

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Abstract

Electrode biasing experiments were carried out in various magnetic configurations on the Large Helical Device (LHD). The transitions of poloidal viscosity, which were accompanied with bifurcation phenomena characterized by a negative resistance in an electrode characteristic, were clearly observed on LHD by the electrode biasing. The critical external driving force required for transition was compared with the local maximum in ion viscosity, and the radial resistivity before the transition also compared with the expected value from a neoclassical theory. The critical driving force increased and the radial resistivity decreased with the major radius of the magnetic axis R_ax going outwards. The configuration dependence of the transition condition and the radial resistivity qualitatively agreed with neoclassical theories. The radial electric field and the viscosity were also evaluated by the neoclassical transport code for a non-axisymmetric system, and estimated electrode voltage required for the transition, which was consistent with the experimental results.

Original language	English
Article number	073014
Journal	Nuclear Fusion
Volume	53
Issue number	7
DOIs	https://doi.org/10.1088/0029-5515/53/7/073014
Publication status	Published - 2013 Jul

ASJC Scopus subject areas

Nuclear and High Energy Physics
Condensed Matter Physics

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Kitajima, S., Takahashi, H., Ishii, K., Sato, Y., Kanno, M., Tachibana, J., Okamoto, A., Sasao, M., Inagaki, S., Takayama, M., Masuzaki, S., Shoji, M., Ashikawa, N., Tokitani, M., Yokoyama, M., Suzuki, Y., Satake, S., Ido, T., Shimizu, A., ... Morisaki, T. (2013). Transition of poloidal viscosity by electrode biasing in the Large Helical Device. Nuclear Fusion, 53(7), [073014]. https://doi.org/10.1088/0029-5515/53/7/073014

Kitajima, S, Takahashi, H, Ishii, K, Sato, Y, Kanno, M, Tachibana, J, Okamoto, A, Sasao, M, Inagaki, S, Takayama, M, Masuzaki, S, Shoji, M, Ashikawa, N, Tokitani, M, Yokoyama, M, Suzuki, Y, Satake, S, Ido, T, Shimizu, A, Suzuki, C, Nagayama, Y, Tokuzawa, T, Nishimura, K & Morisaki, T 2013, 'Transition of poloidal viscosity by electrode biasing in the Large Helical Device', Nuclear Fusion, vol. 53, no. 7, 073014. https://doi.org/10.1088/0029-5515/53/7/073014

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abstract = "Electrode biasing experiments were carried out in various magnetic configurations on the Large Helical Device (LHD). The transitions of poloidal viscosity, which were accompanied with bifurcation phenomena characterized by a negative resistance in an electrode characteristic, were clearly observed on LHD by the electrode biasing. The critical external driving force required for transition was compared with the local maximum in ion viscosity, and the radial resistivity before the transition also compared with the expected value from a neoclassical theory. The critical driving force increased and the radial resistivity decreased with the major radius of the magnetic axis Rax going outwards. The configuration dependence of the transition condition and the radial resistivity qualitatively agreed with neoclassical theories. The radial electric field and the viscosity were also evaluated by the neoclassical transport code for a non-axisymmetric system, and estimated electrode voltage required for the transition, which was consistent with the experimental results.",

author = "Sumio Kitajima and H. Takahashi and Keizo Ishii and Y. Sato and M. Kanno and J. Tachibana and Atsushi Okamoto and M. Sasao and S. Inagaki and M. Takayama and S. Masuzaki and M. Shoji and N. Ashikawa and M. Tokitani and M. Yokoyama and Y. Suzuki and S. Satake and T. Ido and A. Shimizu and C. Suzuki and Y. Nagayama and T. Tokuzawa and K. Nishimura and T. Morisaki",

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AU - Kitajima, Sumio

AU - Takahashi, H.

AU - Ishii, Keizo

AU - Sato, Y.

AU - Kanno, M.

AU - Tachibana, J.

AU - Okamoto, Atsushi

AU - Sasao, M.

AU - Inagaki, S.

AU - Takayama, M.

AU - Masuzaki, S.

AU - Shoji, M.

AU - Ashikawa, N.

AU - Tokitani, M.

AU - Yokoyama, M.

AU - Suzuki, Y.

AU - Satake, S.

AU - Ido, T.

AU - Shimizu, A.

AU - Suzuki, C.

AU - Nagayama, Y.

AU - Tokuzawa, T.

AU - Nishimura, K.

AU - Morisaki, T.

PY - 2013/7

Y1 - 2013/7

N2 - Electrode biasing experiments were carried out in various magnetic configurations on the Large Helical Device (LHD). The transitions of poloidal viscosity, which were accompanied with bifurcation phenomena characterized by a negative resistance in an electrode characteristic, were clearly observed on LHD by the electrode biasing. The critical external driving force required for transition was compared with the local maximum in ion viscosity, and the radial resistivity before the transition also compared with the expected value from a neoclassical theory. The critical driving force increased and the radial resistivity decreased with the major radius of the magnetic axis Rax going outwards. The configuration dependence of the transition condition and the radial resistivity qualitatively agreed with neoclassical theories. The radial electric field and the viscosity were also evaluated by the neoclassical transport code for a non-axisymmetric system, and estimated electrode voltage required for the transition, which was consistent with the experimental results.

AB - Electrode biasing experiments were carried out in various magnetic configurations on the Large Helical Device (LHD). The transitions of poloidal viscosity, which were accompanied with bifurcation phenomena characterized by a negative resistance in an electrode characteristic, were clearly observed on LHD by the electrode biasing. The critical external driving force required for transition was compared with the local maximum in ion viscosity, and the radial resistivity before the transition also compared with the expected value from a neoclassical theory. The critical driving force increased and the radial resistivity decreased with the major radius of the magnetic axis Rax going outwards. The configuration dependence of the transition condition and the radial resistivity qualitatively agreed with neoclassical theories. The radial electric field and the viscosity were also evaluated by the neoclassical transport code for a non-axisymmetric system, and estimated electrode voltage required for the transition, which was consistent with the experimental results.

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Transition of poloidal viscosity by electrode biasing in the Large Helical Device

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