Effects of rational surfaces and magnetic islands on radial electric fields and ion viscosity in Tohoku University Heliac

S. Kitajima; H. Takahashi; Y. Tanaka; H. Utoh; M. Takenaga; M. Yokoyama; S. Inagaki; Y. Suzuki; K. Nishimura; H. Ogawa; J. Shinde; M. Ogawa; H. Aoyama; K. Iwazaki; Atsushi Okamoto; K. Shinto; M. Sasao

doi:10.13182/FST06-A1236

Effects of rational surfaces and magnetic islands on radial electric fields and ion viscosity in Tohoku University Heliac

S. Kitajima, H. Takahashi, Y. Tanaka, H. Utoh, M. Takenaga, M. Yokoyama, S. Inagaki, Y. Suzuki, K. Nishimura, H. Ogawa, J. Shinde, M. Ogawa, H. Aoyama, K. Iwazaki, Atsushi Okamoto, K. Shinto, M. Sasao

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

The influence of the low-order rational surface (n, m) = (5,3) on ion viscosity and radial electric field formation were investigated by electrode current sweep biasing with a hot cathode at the Tohoku University Heliac. In the improved mode, the position of the maximum electric field remained on the n/m = 5/3 rational surface. After the H-L transition, the local maxima shifted outward to the plasma periphery of ρ 0.8. The low-order magnetic islands were formed resonating the magnetic Fourier components of(n, m) = (5, 3) by external perturbation coils. As the widths of the magnetic islands were increased, the biasing electrode current required for the improved mode transition increased. It was suggested that the ion viscosity increased according to the increase in magnetic island width. The increase in the biasing electrode current is equivalent to the increase in the driving force for the poloidal rotation. This suggests the possibility of an active viscosity control assisted by externally controlled island width and magnetic island rotation.

Original language	English
Pages (from-to)	201-206
Number of pages	6
Journal	Fusion Science and Technology
Volume	50
Issue number	2
DOIs	https://doi.org/10.13182/FST06-A1236
Publication status	Published - 2006 Aug

Keywords

Electrode biasing
H-mode
Heliac

ASJC Scopus subject areas

Civil and Structural Engineering
Nuclear and High Energy Physics
Nuclear Energy and Engineering
Materials Science(all)
Mechanical Engineering

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10.13182/FST06-A1236

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Kitajima, S., Takahashi, H., Tanaka, Y., Utoh, H., Takenaga, M., Yokoyama, M., Inagaki, S., Suzuki, Y., Nishimura, K., Ogawa, H., Shinde, J., Ogawa, M., Aoyama, H., Iwazaki, K., Okamoto, A., Shinto, K., & Sasao, M. (2006). Effects of rational surfaces and magnetic islands on radial electric fields and ion viscosity in Tohoku University Heliac. Fusion Science and Technology, 50(2), 201-206. https://doi.org/10.13182/FST06-A1236

Kitajima, S, Takahashi, H, Tanaka, Y, Utoh, H, Takenaga, M, Yokoyama, M, Inagaki, S, Suzuki, Y, Nishimura, K, Ogawa, H, Shinde, J, Ogawa, M, Aoyama, H, Iwazaki, K, Okamoto, A, Shinto, K & Sasao, M 2006, 'Effects of rational surfaces and magnetic islands on radial electric fields and ion viscosity in Tohoku University Heliac', Fusion Science and Technology, vol. 50, no. 2, pp. 201-206. https://doi.org/10.13182/FST06-A1236

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abstract = "The influence of the low-order rational surface (n, m) = (5,3) on ion viscosity and radial electric field formation were investigated by electrode current sweep biasing with a hot cathode at the Tohoku University Heliac. In the improved mode, the position of the maximum electric field remained on the n/m = 5/3 rational surface. After the H-L transition, the local maxima shifted outward to the plasma periphery of ρ 0.8. The low-order magnetic islands were formed resonating the magnetic Fourier components of(n, m) = (5, 3) by external perturbation coils. As the widths of the magnetic islands were increased, the biasing electrode current required for the improved mode transition increased. It was suggested that the ion viscosity increased according to the increase in magnetic island width. The increase in the biasing electrode current is equivalent to the increase in the driving force for the poloidal rotation. This suggests the possibility of an active viscosity control assisted by externally controlled island width and magnetic island rotation.",

keywords = "Electrode biasing, H-mode, Heliac",

author = "S. Kitajima and H. Takahashi and Y. Tanaka and H. Utoh and M. Takenaga and M. Yokoyama and S. Inagaki and Y. Suzuki and K. Nishimura and H. Ogawa and J. Shinde and M. Ogawa and H. Aoyama and K. Iwazaki and Atsushi Okamoto and K. Shinto and M. Sasao",

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AU - Kitajima, S.

AU - Takahashi, H.

AU - Tanaka, Y.

AU - Utoh, H.

AU - Takenaga, M.

AU - Yokoyama, M.

AU - Inagaki, S.

AU - Suzuki, Y.

AU - Nishimura, K.

AU - Ogawa, H.

AU - Shinde, J.

AU - Ogawa, M.

AU - Aoyama, H.

AU - Iwazaki, K.

AU - Okamoto, Atsushi

AU - Shinto, K.

AU - Sasao, M.

PY - 2006/8

Y1 - 2006/8

N2 - The influence of the low-order rational surface (n, m) = (5,3) on ion viscosity and radial electric field formation were investigated by electrode current sweep biasing with a hot cathode at the Tohoku University Heliac. In the improved mode, the position of the maximum electric field remained on the n/m = 5/3 rational surface. After the H-L transition, the local maxima shifted outward to the plasma periphery of ρ 0.8. The low-order magnetic islands were formed resonating the magnetic Fourier components of(n, m) = (5, 3) by external perturbation coils. As the widths of the magnetic islands were increased, the biasing electrode current required for the improved mode transition increased. It was suggested that the ion viscosity increased according to the increase in magnetic island width. The increase in the biasing electrode current is equivalent to the increase in the driving force for the poloidal rotation. This suggests the possibility of an active viscosity control assisted by externally controlled island width and magnetic island rotation.

AB - The influence of the low-order rational surface (n, m) = (5,3) on ion viscosity and radial electric field formation were investigated by electrode current sweep biasing with a hot cathode at the Tohoku University Heliac. In the improved mode, the position of the maximum electric field remained on the n/m = 5/3 rational surface. After the H-L transition, the local maxima shifted outward to the plasma periphery of ρ 0.8. The low-order magnetic islands were formed resonating the magnetic Fourier components of(n, m) = (5, 3) by external perturbation coils. As the widths of the magnetic islands were increased, the biasing electrode current required for the improved mode transition increased. It was suggested that the ion viscosity increased according to the increase in magnetic island width. The increase in the biasing electrode current is equivalent to the increase in the driving force for the poloidal rotation. This suggests the possibility of an active viscosity control assisted by externally controlled island width and magnetic island rotation.

KW - Electrode biasing

KW - H-mode

KW - Heliac

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Effects of rational surfaces and magnetic islands on radial electric fields and ion viscosity in Tohoku University Heliac

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Keywords

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