Your search keyword '"Kazumichi, NARIHARA"' showing total 18 results

1. Confinement improvement in high-ion temperature plasmas heated with high-energy negative-ion-based neutral beam injection in the Large Helical Device

Author

Masayuki Yokoyama, Motoshi Goto, Katsuyoshi Tsumori, Yasuhiko Takeiri, Yoshihide Oka, Kenji Tanaka, Takashi Shimozuma, Hisamichi Funaba, Osamu Kaneko, Kazumichi Narihara, K. Nagaoka, Katsumi Ida, Osamu Motojima, Katsunori Ikeda, Shin Kubo, Akio Komori, Mikiro Yoshinuma, Masaki Osakabe, S. Morita, and Shigeru Inagaki

Subjects

Nuclear and High Energy Physics, Large Helical Device, Materials science, Physics::Plasma Physics, Electric field, Electron temperature, Plasma, Electron, Atomic physics, Condensed Matter Physics, Ion transporter, Neutral beam injection, Ion

Abstract

An increase in the ion temperature due to transport improvement has been observed in plasmas heated with high-energy negative-ion-based neutral beam injection (NBI), in which the electrons are dominantly heated, in the Large Helical Device. When centrally focused electron-cyclotron-resonance heating is superposed on the NBI plasma, the ion temperature is observed to rise, accompanied by the formation of the electron internal transport barrier (electron-ITB). In the electron-ITB plasmas, an increase in a positive radial electric field is observed, and the transport analysis indicates that the ion transport in the half-radius region is improved with a reduction of the anomalous transport. Thus, this ion temperature rise is ascribed to the ion transport improvement by the transition to the neoclassical electron root. In high-Z plasmas, the ion temperature is increased with an increase in the ion heating power and reaches 13.5 keV. The central ion temperature increases with an increase in a gradient of the electron temperature in an outer plasma region of ρ = 0.8, suggesting the ion transport improvement in the outer plasma region induced by the neoclassical electron root. These results indicate the effectiveness of the electron-root scenario for obtaining high-ion temperature plasmas in helical systems.

Published

2007

2. Experimental study on ion temperature behaviours in ECH, ICRF and NBI H2, He and Ne discharges of the Large Helical Device

Author

J. Miyazawa, Hisamichi Funaba, Osamu Motojima, M. Fujiwara, H. Nozato, Nobuyoshi Ohyabu, Hajime Suzuki, Keisuke Matsuoka, Tsuyoshi Akiyama, Kazuo Kawahata, Hideya Nakanishi, Masahiko Emoto, Atsushi J. Nishizawa, Masayuki Yokoyama, Hiroshi Yamada, T. Yamamoto, Kenji Tanaka, Mamiko Sasao, Naoko Ashikawa, H. Kawazome, Shigeru Sudo, Yasuo Yoshimura, Kazuo Toi, K. Yamazaki, Takashi Satow, Mitsutaka Isobe, N. Takeuchi, Takeshi Ido, A. Kostrioukov, N. Noda, Yunfeng Liang, T. Kobuchi, Hiroshi Idei, Takashi Minami, Naoki Tamura, Tetsuo Seki, T. Uda, S. Yamamoto, Yasuhiko Takeiri, Kunizo Ohkubo, T. Ozaki, P. Goncharov, T. Saida, Masaki Osakabe, Y. Nakamura, Byron J. Peterson, Yuki Torii, Takashi Notake, Shigeru Inagaki, Ryuichi Sakamoto, Osamu Kaneko, Katsuyoshi Tsumori, Kuninori Sato, Akio Sagara, K. Nishimura, Y. Xu, Takashi Shimozuma, Kazumichi Narihara, Yasuji Hamada, Ryuhei Kumazawa, Katsunori Ikeda, Tokihiko Tokuzawa, Takashi Mutoh, Shin Kubo, Tomohiro Morisaki, Akio Komori, S. Murakami, Mikiro Yoshinuma, M. Sato, Mamoru Shoji, Katsumi Ida, S. Morita, K.Y. Watanabe, Satoshi Ohdachi, Kimitaka Itoh, Sadatsugu Muto, Motoshi Goto, Satoru Sakakibara, Suguru Masuzaki, Yoshio Nagayama, K. Saito, Ichihiro Yamada, T. Watari, K. V. Khlopenkov, Yoshiro Narushima, and Yoshihide Oka

Subjects

Nuclear and High Energy Physics, Range (particle radiation), Materials science, chemistry.chemical_element, Magnetic confinement fusion, Condensed Matter Physics, Ion, Large Helical Device, chemistry, Plasma diagnostics, Atomic physics, Helium, Beam (structure), Doppler broadening

Abstract

Ion heating experiments have been carried out in the large helical device using ECH (82.5, 84.0, 168 GHz, ≤1 MW), ICRF (38.5 MHz, ≤2.7 MW) and NBI (H° beam: 160 keV, ≤9 MW). The central ion temperature has been observed from the Doppler broadening of Ti XXI (2.61 A) and Ar XVII (3.95 A) x-ray lines, which are measured using a newly installed crystal spectrometer with a charge-coupled device. Recently, in ECH discharges, on-axis heating became possible. As a result, a high Te(0) of 6–10 keV and a high ion temperature of 2.2 keV were obtained at ne = 0.6×1013 cm−3. A clear increment of Ti was also observed with the enhancement of the electron–ion energy flow when the ECH pulse was added to the NBI discharge. These results demonstrate the feasibility towards ECH ignition. A clear Ti increment was observed also in ICRF discharges at low density ranges of (0.4–0.6)×1013 cm−3 with appearance of a new operational range of Ti(0) = 2.8 keV > Te(0) = 1.9 keV. In low power ICRF heating (1 MW), the fraction of bulk ion heating is estimated to be 60% of the total ICRF input power, which means Pi>Pe. Higher Ti(0), up to 3.5 keV, was obtained for a combined heating of NBI ( Te(0), whereas the Ti(0) remained at relatively low values of 2 keV in H2 and He NBI discharges due to less Pi. The main reasons for the high Ti achievement in the Ne discharges are: (1) 30% increment of deposition power, (2) increase in Pi/ni (five times, Pi/niPe/ne, Pi

Published

2003

3. Plasma performance and impurity behaviour in long pulse discharges on LHD

Author

M. Fujiwara, Kazuo Kawahata, Takashi Shimozuma, Ichihiro Yamada, T. Watari, Ryuhei Kumazawa, J. Miyazawa, Osamu Motojima, Shigeru Inagaki, T. Kobuchi, Nobuyoshi Ohyabu, K. Saito, Byron J. Peterson, Takashi Notake, Katsunori Ikeda, T. Uda, Suguru Masuzaki, S. Morita, T. Saida, Yasuo Yoshimura, Tsuyoshi Akiyama, Sadatsugu Muto, Hiroshi Idei, N. Noda, T. Yamamoto, Takashi Satow, Hisamichi Funaba, Satoshi Ohdachi, Takashi Minami, I. Ohtake, S. Okamura, Shigeru Sudo, Mamoru Shoji, Katsumi Ida, A. Kostrioukov, Mitsutaka Isobe, Masayuki Yokoyama, S. Yamamoto, Kimitaka Itoh, Y. Nakamura, Keisuke Matsuoka, Ryuichi Sakamoto, Y. Xu, Osamu Kaneko, Akio Komori, Toshiyuki Mito, Hideya Nakanishi, K. V. Khlopenkov, Mikiro Yoshinuma, Yoshiro Narushima, M. Sato, Masahiko Emoto, Naoki Tamura, Shinji Yoshimura, T. Ozaki, Satoru Sakakibara, Yuki Torii, Hajime Suzuki, Tetsuo Seki, H. Nozato, K.Y. Watanabe, K. Nishimura, Masaki Osakabe, Kuninori Sato, M. Y. Tanaka, Akio Sagara, K. Nagaoka, S. Murakami, Yoshihide Oka, Kazumichi Narihara, Yasuji Hamada, Shinsaku Imagawa, Tomohiro Morisaki, Yunfeng Liang, Yoshio Nagayama, Mamiko Sasao, K. Yamazaki, Yasuhiko Takeiri, P. R. Goncharov, Shin Kubo, Motoshi Goto, Hiroshi Yamada, Naoko Ashikawa, Kazuo Toi, Kunizo Ohkubo, Katsuyoshi Tsumori, Kenji Tanaka, H. Kawazome, N. Takeuchi, Tokihiko Tokuzawa, and Takashi Mutoh

Subjects

Convection, Superconductivity, Nuclear and High Energy Physics, Long pulse, Materials science, Hydrogen, chemistry.chemical_element, Plasma, Condensed Matter Physics, Neon, chemistry, Physics::Plasma Physics, Impurity, Condensed Matter::Superconductivity, Electric field, Atomic physics

Abstract

The superconducting machine LHD has conducted long pulse experiments for four years to achieve long-duration plasmas with high performance. The operational regime was largely extended in discharge duration and plasma density. In this paper, the plasma characteristics, in particular, plasma performance and impurity behaviour in long pulse discharges are described. Confinement studies show that global energy confinement times are comparable to those in short pulse discharges. Long sustainment of high performance plasma, which is equivalent to the previous achievement in other devices, was demonstrated. Long pulse discharges enabled us to investigate impurity behaviour in a long timescale. Intrinsic metallic impurity accumulation was observed in a narrow density window (2–3×1019 m−3) only for hydrogen discharges. Impurity transport study by using active impurity pellet injection shows a long impurity confinement time and an inward convection in the impurity accumulation window, which is consistent with the intrinsic impurity behaviour. The pulsed neon gas injection experiment shows that the neon penetration into the plasma core is caused by the inward convection due to radial electric field. Finally, impurity accumulation control with an externally induced magnetic island at the plasma edge was demonstrated.

Published

2003

4. Ion and electron heating in ICRF heating experiments on LHD

Author

Hideya Nakanishi, Masahiko Emoto, K.Y. Watanabe, N. Inoue, Ryuichi Sakamoto, Shin Kubo, S. Murakami, Tomo-Hiko Watanabe, Y. Zhao, Masayuki Yokoyama, Osamu Kaneko, Kenya Akaishi, Shinichiro Kado, Dirk Hartmann, Yuki Torii, Mamoru Shoji, Motoshi Goto, Hisamichi Funaba, Hiroshi Yamada, T. Kobuchi, Ryuhei Kumazawa, K. Nishimura, Katsumi Ida, M. Fujiwara, Ichihiro Yamada, T. Watari, Akio Komori, Shigeru Inagaki, Kazuo Toi, Katsunori Ikeda, Akio Sagara, J. Miyazawa, Hiroshi Idei, Osamu Motojima, M. Sato, T. Ozaki, Kazumichi Narihara, Yasuji Hamada, Kazuo Kawahata, A. V. Krasilnikov, Yasuo Yoshimura, Nobuyoshi Ohyabu, Yoshio Nagayama, N. Noda, Tomohiro Morisaki, Byron J. Peterson, Takashi Minami, Hajime Suzuki, S. Morita, N. Ashikawa, H. Sasao, Y. Nakamura, Kuninori Sato, Soichiro Yamaguchi, Satoshi Ohdachi, Kimitaka Itoh, P.C. De Vries, Mamiko Sasao, S. Yamamoto, Yasuhiko Takeiri, Satoru Sakakibara, Yoshihide Oka, Sadatsugu Muto, Masaki Osakabe, Shigeru Sudo, Mitsutaka Isobe, Kenji Saito, Tetsuo Seki, K. Yamazaki, Suguru Masuzaki, Fujio Shimpo, Tokihiko Tokuzawa, Takashi Mutoh, Kunizo Ohkubo, Katsuyoshi Tsumori, Kenji Tanaka, Goro Nomura, Atsushi Fukuyama, Mitsuhiro Yokota, and Takashi Shimozuma

Subjects

Nuclear and High Energy Physics, Materials science, Power absorption, Electron heating, Atomic physics, Condensed Matter Physics, Heating efficiency, Ion, Magnetic field

Abstract

The ICRF heating experiments conducted in 1999 in the third experimental campaign on LHD are reported, with an emphasis on the optimization of the heating regime. Specifically, an exhaustive study of seven different heating regimes was carried out by changing the radiofrequency relative to the magnetic field intensity, and the dependence of the heating efficiency on H minority concentration was investigated. It was found in the experiment that both ion and electron heating are attainable with the same experimental set-up by properly choosing the frequency relative to the magnetic field intensity. In the cases of both electron heating and ion heating, the power absorption efficiency depends on the minority ion concentration. An optimum minority concentration exists in the ion heating case while, in the electron heating case, the efficiency increases with concentration monotonically. A simple model calculation is introduced to provide a heuristic understanding of these experimental results. Among the heating regimes examined in this experiment, one of the ion heating regimes was finally chosen as the optimized heating regime and various high performance discharges were realized with it.

Published

2001

5. Role of core radiation during slow oscillations in LHD

Author

Byron J. Peterson, Takashi Notake, Suguru Masuzaki, Hajime Suzuki, Naoki Tamura, Shin Kubo, Kazuo Toi, Kazuo Kawahata, Mamiko Sasao, M. Takechi, Kenji Saito, Ryuhei Kumazawa, Ichihiro Yamada, Shinichiro Kado, T. Watari, Kazumichi Narihara, Kenji Tanaka, Hisamichi Funaba, Katsunori Ikeda, Masaki Osakabe, Soichiro Yamaguchi, Akio Komori, N. Ashikawa, Satoshi Ohdachi, M. Sato, Takashi Minami, Tetsuo Seki, Yasuhiko Takeiri, Katsuyoshi Tsumori, Masayuki Yokoyama, Ryuichi Sakamoto, Tomohiro Morisaki, Motoshi Goto, Y. Xu, Yuki Torii, K.Y. Watanabe, Tokihiko Tokuzawa, Takashi Mutoh, Satoru Sakakibara, K. Yamazaki, Y. Nakamura, Shigeru Sudo, Osamu Kaneko, Mitsutaka Isobe, Mamoru Shoji, T. Kobuchi, J. Miyazawa, Hiroshi Idei, Osamu Motojima, Katsumi Ida, Nobuyoshi Ohyabu, Akio Sagara, P.C. De Vries, S. Murakami, S. Yamamoto, Sadatsugu Muto, T. Ozaki, Kuninori Sato, Hideya Nakanishi, Masahiko Emoto, R. O. Pavlichenko, Yoshihide Oka, Takashi Shimozuma, Shigeru Inagaki, N. Noda, Yasuo Yoshimura, H. Sasao, Y. Liang, K. V. Khlopenkov, John Rice, N. Inoue, K. Nishimura, Yoshio Nagayama, and Hiroshi Yamada

Subjects

Nuclear and High Energy Physics, Electron density, Materials science, Physics::Plasma Physics, Sputtering, Impurity, Oscillation, Plasma parameters, Divertor, Electron temperature, Plasma, Atomic physics, Condensed Matter Physics

Abstract

During experiments in LHD using stainless steel divertor plates, a slow (~1 s) cyclic oscillation in the plasma parameters known as `breathing' plasma was observed during NBI heated long pulse discharges. Using an average ion, corona equilibrium model for the iron impurity cooling rate, the iron impurity density profile is calculated for 0.0

Published

2001

6. The performance of ICRF heated plasmas in LHD

Author

Hiroshi Yamada, Naoki Tamura, Masaki Osakabe, Byron J. Peterson, R. O. Pavlichenko, K. V. Khlopenkov, Hisamichi Funaba, Yasuo Yoshimura, Tokihiko Tokuzawa, Takashi Mutoh, Kazuo Toi, Takashi Satow, Yasuhiko Takeiri, T. Kobuchi, Suguru Masuzaki, S. Tanahashi, A.T. Notake, S. Yamamoto, J. Miyazawa, Keisuke Matsuoka, Kunizo Ohkubo, K. Nishimura, Dirk Hartmann, Kazumichi Narihara, Yasuji Hamada, Shigeru Inagaki, Tetsuo Seki, N. Ashikawa, Sadatsugu Muto, Osamu Motojima, Katsuyoshi Tsumori, Sadao Satoh, Takashi Minami, Hiroshi Idei, Nobuyoshi Ohyabu, Mamoru Shoji, Kenji Tanaka, Tomo-Hiko Watanabe, Yan Ping Zhao, Y. Liang, Katsumi Ida, M. Sasao, Satoshi Ohdachi, Takashi Shimozuma, K. Yamazaki, A. V. Krasilnikov, Kimitaka Itoh, Yuki Torii, Hideya Nakanishi, Atsushi Fukuyama, Yoshihide Oka, Hiroyuki Okada, Kenji Saito, Masahiko Emoto, Yoshio Nagayama, N. Inoue, Shin Kubo, N. Noda, Shinichiro Kado, Motoshi Goto, T. Ozaki, Soichiro Yamaguchi, Akio Sagara, S. Murakami, Tomohiro Morisaki, H. Sasao, Ryuhei Kumazawa, Akio Komori, Masayuki Yokoyama, Satoru Sakakibara, M. Fujiwara, M. Sato, Katsunori Ikeda, Osamu Kaneko, Y. Nakamura, Kuninori Sato, Kazuo Kawahata, K.Y. Watanabe, Ryuichi Sakamoto, S. Morita, Masao Okamoto, Shigeru Sudo, Mitsutaka Isobe, Ichihiro Yamada, T. Watari, P.C. De Vries, Hajime Suzuki, and M. Takechi

Subjects

Nuclear and High Energy Physics, Materials science, Plasma parameters, Divertor, Cyclotron, Pulse duration, Plasma, Condensed Matter Physics, Magnetic field, law.invention, Ion, law, Atomic physics, Stellarator

Abstract

An ion cyclotron range of frequency (ICRF) heating experiment was conducted in the third campaign of LHD in 1999. 1.35 MW of ICRF power were injected into the plasma and 200 kJ of stored energy were obtained, which was maintained for 5 s by ICRF power only after the termination of ECH. The impurity problem was so completely overcome that the pulse length was easily extended to 68 s at a power level of 0.7 MW. The utility of a liquid stub tuner in steady state plasma heating was demonstrated in this discharge. The energy confinement time of the ICRF heated plasma has the same dependences on plasma parameters as those of the ISS95 stellarator scaling with a multiplication factor of 1.5, which is a high efficiency comparable to that of NBI. Such an improvement in performance was obtained by various means, including: (a) scanning of the magnetic field intensity and minority concentration, (b) improvement of particle orbits due to a shift of magnetic axis and (c) reduction of the number of impurity ions by means of titanium gettering and the use of carbon divertor plates. In the optimized heating regime, ion heating turned out to be the dominant heating mechanism, unlike in CHS and W7-AS. Owing to the high quality of the heating and the parameter range being extended far beyond that of previous experiments, the experiment can be regarded as the first complete demonstration of ICRF heating in stellarators.

Published

2001

7. Energetic ion driven MHD instabilities observed in the heliotron/torsatron devices Compact Helical System and Large Helical Device

Author

Yasuo Yoshimura, Osamu Motojima, Nobuyoshi Ohyabu, Hiroshi Idei, Mamiko Sasao, Masaki Osakabe, Kuninori Sato, Hiroshi Yamada, M. Takechi, Kazuo Toi, D. S. Darrow, S. Morita, T. Kondo, G. Matsunaga, S. Okamura, Yasuhiko Takeiri, Akihide Fujisawa, H. Iguchi, Motoyasu Sato, Mitsutaka Isobe, K. Ohkuni, Shoji Takagi, Satoru Sakakibara, Lhd Experimental Groups, Satoshi Ohdachi, Motoshi Goto, Shin Kubo, A. Shimizu, Kazumichi Narihara, Keisuke Matsuoka, Kiyomasa Watanabe, Noriyoshi Nakajima, T. Ozaki, Takashi Minami, Osamu Kaneko, Yoshihide Oka, Seiya Nishimura, Ichihiro Yamada, S. Yamamoto, Kazuo Kawahata, Shinichiro Kado, S. Lee, Katsumi Ida, Takashi Shimozuma, Kenji Tanaka, Katsuyoshi Tsumori, and Tokihiko Tokuzawa

Subjects

Physics, Nuclear and High Energy Physics, Large Helical Device, Toroid, Physics::Plasma Physics, Excited state, Plasma, Atomic physics, Magnetohydrodynamics, Condensed Matter Physics, Beam (structure), Ion, Magnetic field

Abstract

Recent results of energetic ion driven MHD instabilities observed in the heliotron/torsatron devices Compact Helical System (CHS) and Large Helical Device (LHD) are presented. Alfven eigenmodes (AEs) and fishbone-like burst modes (FBs) destabilized by energetic ions were observed in NBI heated plasmas of CHS. The AEs are toroidicity induced Alfven eigenmodes (TAEs) and global Alfven eigenmodes (GAEs), where the identified toroidal mode numbers are n = 1 and 2 for TAEs and n = 0 for GAEs. The frequencies of the FBs are less than, at most, half of the minimum TAE gap frequency and do not exhibit the obvious density dependence related to Alfven velocity. The modes have characteristic features of the energetic particle modes or the resonant TAEs excited by circulating energetic beam ions produced by NBI. Bursting amplitude modulation is observed in TAEs as well as in FBs. Rapid frequency chirping is observed in each burst, by a factor of 2-6 in FBs and about 25% in TAEs. In several shots, the power spectrum of the TAEs is split into multiple peaks having the same toroidal mode number through non-linear evolution of TAEs. A pulsed increase in energetic ion loss towards the wall is induced by m = 3/n = 2 FBs, but so far not by m = 2/n = 1 FBs, TAEs and GAEs, where m is the poloidal mode number. This research has been extended to LHD plasmas heated by neutral hydrogen beams with about 130 keV energy. Similar to CHS, TAEs and FBs were observed in relatively low density plasmas at low toroidal magnetic field (Bt = 1.5 T).

Published

2000

8. Overview of long pulse operation in the Large Helical Device

Author

S. Tanahashi, Hiroshi Yamada, M. Fujiwara, Kazuo Kawahata, K. Saito, Naoko Ashikawa, Kazuo Toi, Kazuya Takahata, Hiroshi Idei, Hisamichi Funaba, Satoshi Ohdachi, Kimitaka Itoh, Kazumichi Narihara, S. Kitagawa, Yasuji Hamada, Y. Kubota, Masaki Osakabe, J. Miyazawa, Tokihiko Tokuzawa, Takashi Mutoh, Osamu Motojima, Ryuichi Sakamoto, Byron J. Peterson, Ichihiro Yamada, T. Watari, Masao Okamoto, Hideo Sugama, Nobuyoshi Ohyabu, Suguru Masuzaki, Shigeru Sudo, Sadao Satoh, Shigeru Inagaki, Shin Kubo, S. Murakami, Mitsutaka Isobe, Akio Sagara, K. Nishimura, Sadatsugu Muto, Y. Nakamura, K. Adachi, Hajime Suzuki, Masayuki Yokoyama, K. Yamazaki, Mamoru Shoji, Kunizo Ohkubo, Katsumi Ida, S. Yamamoto, Mamiko Sasao, Yoshio Nagayama, P. de Vries, S. Morita, Yasuhiko Takeiri, Motoshi Goto, Katsuyoshi Tsumori, A. Nishizawa, T. Kobuchi, Tomohiro Morisaki, Soichiro Yamaguchi, Keisuke Matsuoka, Satoru Sakakibara, Kenji Tanaka, Kenya Akaishi, Shinichiro Kado, Akio Komori, Ryuji Maekawa, M. Sato, K.Y. Watanabe, A. Nishimura, Toshiyuki Mito, T. Ozaki, Hideya Nakanishi, Masahiko Emoto, Masaki Takeuchi, Takashi Shimozuma, Yasuo Yoshimura, S. Yamada, Takashi Satow, A. Iwamoto, Hitoshi Tamura, Osamu Kaneko, Tetsuo Seki, K. Murai, Kuninori Sato, I. Ohtake, A. Iiyoshi, Nagato Yanagi, Tomo-Hiko Watanabe, Hirotaka Chikaraishi, Ryuhei Kumazawa, Katsunori Ikeda, Takashi Minami, Yoshihide Oka, Shinsaku Imagawa, N. Noda, and H. Sasao

Subjects

Nuclear and High Energy Physics, Large Helical Device, Long pulse, Data acquisition, Steady state, Materials science, Nuclear magnetic resonance, Duty cycle, Nuclear engineering, Divertor, Plasma, Condensed Matter Physics, Magnetic field

Abstract

The Large Helical Device is the world's largest heliotron type helical system, with the plasma confining magnetic field being generated by only external superconducting coils. One of the main objectives of the LHD project is to sustain high temperature plasmas for a long time in steady state. The plasma vacuum vessel and the divertor are water cooled, and a heat load of 3 MW can be removed continuously. The NBI, ECH and ICRF heating systems, diagnostic instruments and data acquisition system are designed for long pulse operation. The present status of these systems and the recent experimental results of long pulse operation are reviewed. A steady state discharge with NBI was obtained for 35 s. The ECH discharge duration was extended to 120 s with a duty factor of 95%. Plasma sustainment by ICRF alone was achieved for 2 s. The performance of these long pulse operations is summarized.

Published

2000

9. Density fluctuations in JIPP T-IIU tokamak plasmas measured by a heavy ion beam probe

Author

I. Nomura, Mamiko Sasao, Takeshi Ido, Kuninori Sato, Takashi Minami, H. Kuramoto, Akira Ejiri, Ryuhei Kumazawa, J. Koong, Satoshi Ohdachi, Y. Kawasumi, K. Iwasaki, Kazuo Toi, S. Hirokura, A. Nishizawa, Toshihiro Tsuzuki, Tetsuo Seki, Akihide Fujisawa, Kazuo Kawahata, Ichihiro Yamada, T. Watari, Katsumi Ida, Mamoru Kojima, Kazumichi Narihara, Yasuji Hamada, S. Hidekuma, K. Adachi, H. Iguchi, Kazunobu Sato, Hajime Sakakita, and J. Xu

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Turbulence, Plasma, Low frequency, Condensed Matter Physics, Neutral beam injection, law.invention, Ion, Physics::Plasma Physics, law, Physics::Space Physics, Wavenumber, Diamagnetism, Atomic physics

Abstract

Multiple and small sample volume measurements of the density turbulence and potential profile measurements in tokamak plasmas were conducted using a heavy ion beam probe. The obtained wavenumber-frequency spectrum S(k, omega ) shows that the cross-sections of neutral beam injection (NBI) heated plasmas are divided into three regions of different turbulence characteristics outside the layer where the direction of the density turbulence propagation reverses, a low frequency and low wavenumber mode travelling in the ion diamagnetic drift direction dominates. The region enclosed by this reversal layer is divided into two parts during nearly perpendicular NBI heating: a region where the propagation velocity is near the Etau /Bt poloidal rotation velocity and a bad curvature region of very small wavenumber and high propagation velocity. The region of high propagation velocity, found in NBI plasmas, disappears in the ohmic plasmas. In addition, a small component that propagates in the ion diamagnetic drift direction is observed in NBI plasmas

Published

1997

10. Fast potential change during sawteeth in JIPP T-IIU tokamak plasmas

Author

T. Minami, T. Tsuzuki, Kazuo Kawahata, R. Liang, J. Koong, Mamoru Kojima, Kazumichi Narihara, Ryuhei Kumazawa, Hajime Sakakita, Kazuo Toi, Tetsuo Seki, Kuninori Sato, S. Hidekuma, Kazunobu Sato, A. Nishizawa, Akira Ejiri, Akihide Fujisawa, Ichihiro Yamada, T. Watari, J. Xu, K. Adachi, Katsumi Ida, Kimitaka Itoh, Y. Kawasumi, H. Iguchi, S. Hirokura, H. Kuramoto, Y. Hamada, and Mamiko Sasao

Subjects

Physics, Nuclear and High Energy Physics, Electron density, Tokamak, Plasma, Sawtooth wave, Condensed Matter Physics, law.invention, Physics::Plasma Physics, law, Electron temperature, Plasma diagnostics, Electric potential, Atomic physics, Magnetohydrodynamics

Abstract

Fast changes of electric potential with different polarities are observed during sawtooth oscil- lations in the core region of a tokamak plasma using a heavy ion beam probe. Near the inversion radius the polarity of the observed change of the potential is found to be dependent on the swift movement of the hot core at the crash and is consistent with the prediction of one- fluid MHD theory. Near the magnetic axis the change of the potentials is positive and outside the inversion radius the change is negative. This is in contradiction with the MHD prediction. A periodic crash of the central electron tempera- ture called a sawtooth oscillation is a common fea- ture of tokamak plasmas (l-61. After the crash, a flattening of the pressure throughout the q = 1 sur- face is observed. Kadomtsev proposed a theoretical model of the resistive reconnection (7). The theory predicted the flattening of the q profile as well as the pressure profile inside the q = 1 surface. The predic- tion was, however, found to be in contradiction with recent measurements of the current density in toka- mak plasmas (8). In addition, experiments in large machines such as JET and TFTR showed much faster crashes than those predicted by resistive reconnection (2-61. More refined theories, which take account of the kinetic effect and ergodicity on the reconnections, have now been proposed (9-121. The present Letter reports the first measurement of potential changes during sawtooth oscillations and discusses the impli- cations of the results. The experiment is performed with the JIPP T-IIU tokamak (13). Its major radius is 93 cm and the maximum toroidal field is 3 T. The experiment is conducted at a relatively low electron density of about 2 x 1013 cm3, so that good beam penetra- tion into the centre of the plasma could be obtained. A 450 keV singly ionized thallium beam is injected

Published

1996

11. High frequency ion Bernstein wave heating experiment in the JIPP T-IIU tokamak

Author

Fujio Shimpo, Akira Ando, Katsumi Ida, Y. Kitoh, K. Adati, A. Karita, Ryuhei Kumazawa, S. Morita, Y. Kawasumi, T. Kawamoto, Kazuo Toi, S. Hirokura, Y. Yasaka, Ryuichi Akiyama, Toshihiro Tsuzuki, Osamu Kaneko, S. Okajima, Kuniaki Masai, M. Ono, Tetsuo Seki, Mamiko Sasao, Mamoru Kojima, Yoshihide Oka, Kazumichi Narihara, Yasuji Hamada, S. Hidekuma, Hiroyuki Takahashi, Kunizo Ohkubo, Kazunobu Sato, Kazuo Kawahata, T. Watari, M. Sakamoto, T. Ozaki, Kuninori Sato, Y. Ogawa, and Y. Taniguchi

Subjects

Nuclear and High Energy Physics, Tokamak, Materials science, Cyclotron, Magnetosonic wave, Electron, Plasma, Condensed Matter Physics, Ion, law.invention, Nuclear magnetic resonance, Distribution function, Physics::Plasma Physics, law, Harmonics, Atomic physics

Abstract

An experiment in a new regime of ion Bernstein wave (IBW) heating was carried out using 130 MHz high power transmitters in the JIPP T-IIU tokamak. The heating regime utilized the IBW branch between the 3rd and 4th harmonics of the hydrogen ion cyclotron frequencies. This harmonic number is the highest one used in IBW experiments conducted previously. The net radiofrequency (RF) power injected into the plasma is around 400 kW and is limited by the transmitter output power. Core heating of ions and electrons was confirmed in the experiment and density profile peaking was found to be a special feature of IBW heating. Peaking of the density profile was also found when IBWs were injected into neutral beam heated discharges. An analysis, using a transport code with these experimental data, indicates that particle and energy confinement should be improved in the plasma core region upon application of IBW heating. It is also found that the ion energy distribution function observed during IBW heating has a smaller high energy tail than those observed in conventional fast magnetosonic wave ICRF heating regimes. The ion energy distribution function obtained during IBW heating is in reasonable agreement with that calculated using the quasi-linear RF diffusion/Fokker-Planck model

Published

1992

12. Application of the intermediate frequency range fast wave to the JIPP TII-U plasma

Author

R. Ando, Yuichi Takase, K. Itoh, Kazuo Kawahata, Shigeki Okajima, E. Kako, Ryuichi Akiyama, T. Kawamoto, Osamu Kaneko, T. Watari, Kuniaki Masai, S. Kitagawa, T. Ozaki, Ryuhei Kumazawa, Y. Kitoh, Tetsuo Seki, Hiroyuki Takahashi, Katsumi Ida, Kuninori Sato, M. Sakamoto, S. Tanahashi, Y. Taniguchi, Y. Kawasumi, Toshihiro Tsuzuki, K. Ohkubo, Mamiko Sasao, T. Kuroda, Kazunobu Sato, S. Morita, Atsushi Fukuyama, Mamoru Kojima, Kazumichi Narihara, Yasuji Hamada, S. Hidekuma, S. Hirokura, Y. Ogawa, Kazuo Toi, F. Shimbo, Yoshihide Oka, A. Ando, K. Adati, T. Aoki, A. Karita, and Sanae Inoue Itoh

Subjects

Nuclear and High Energy Physics, Range (particle radiation), Tokamak, Materials science, Cyclotron, Electron, Condensed Matter Physics, Neutral beam injection, law.invention, Intermediate frequency, Physics::Plasma Physics, law, Harmonic, Landau damping, Atomic physics

Abstract

A series of experiments has been conducted on the JIPP TII-U tokamak since 1989, using the newly constructed 130 MHz radiofrequency system. It has been predicted theoretically that the fast wave in this frequency range interacts weakly with particles. Two mechanisms of wave absorption have been identified in the experiment: electron Landau damping/transit time damping and 3rd harmonic ion cyclotron heating. The former mechanism is intimately connected with fast wave current drive and the latter can provide a new regime of plasma heating or a possible method of controlling the transport of alpha particles. It is found that the efficiency of the 3rd harmonic ion cyclotron heating is improved by using it in combination with neutral beam injection and ion cyclotron range of frequency heating. The heating efficiency obtained is as high as that of conventional heating. The experimental results are also analysed on the basis of a global wave theory which takes into account wave-particle interactions. These mechanisms of interaction are competing with each other; this will also be the case under more realistic reactor conditions.

Published

1991

13. Limiter H-mode and other improved confinement regimes with ICRF and NBI heating in JIPP T-IIU

Author

Toshikazu Kawamoto, Y. Taniguchi, Mamoru Kojima, Kazumichi Narihara, Akio Sagara, R. Akiyama, Yoshihide Oka, Akira Ando, F. Shimbo, S. Hirokura, S. Hidekuma, Hiroshi Yamada, Kuniaki Masai, Y. Kawasumi, Tetsuo Seki, K. Adati, K. Toi, Y. Hamada, S. Kitagawa, T. Aoki, Shigeki Okajima, Konosuke Sato, Akihiro Mohri, T. Ozaki, Toshihiro Tsuzuki, E. Kako, H. Ikegami, Mizuki Sakamoto, S. Tanahashi, Kuninori Sato, Tsutomu Kuroda, Yoshihiro Ogawa, A. Karita, T. Watari, Katsumi Ida, S. Morita, K. Kadota, Mamiko Sasao, Kunizo Ohkubo, Teruyuki Sato, Ryuhei Kumazawa, Kazuo Kawahata, Osamu Kaneko, J. Fujita, R. Ando, and Hiroto Takahashi

Subjects

Nuclear and High Energy Physics, Toroid, Materials science, Plasma parameters, Cyclotron, Plasma, Condensed Matter Physics, Neutral beam injection, Magnetic field, Ion, law.invention, Physics::Plasma Physics, law, Limiter, Atomic physics

Abstract

The H-mode, an improved confinement regime, was attained recently in JIPP T-IIU high power heating experiments, in a limiter configuration without any shaping of the plasma cross-section. This H-mode is unusual because it was obtained with heating in the ion cyclotron range of frequencies (ICRF). It was also attained with combined ICRF and neutral beam injection (NBI) heating. The threshold power level obtained with ICRF alone is similar to or less than that obtained in the combined heating case. The dependence of the power threshold of the H-mode on various plasma parameters has been studied. It increases with the plasma current and is insensitive to the plasma density, and there is an optimum value of the toroidal field intensity. The power deposition profile for ICRF heating has been analysed with a ray tracing code and used to explain the observed dependence on the toroidal magnetic field. The paper also discusses a class of discharges with improved confinement observed in the same series of experiments. These discharges had a power level close to the H-mode threshold power and exhibited a marked improvement of confinement. They were, however, different from H-mode discharges in the time evolution of the profiles.

Published

1990

14. Microtearing mode (MTM) turbulence in JIPPT-IIU tokamak plasmas

Author

Atsushi J. Nishizawa, Y. Kawasumi, Kazuo Toi, Mamoru Kojima, Kazumichi Narihara, Takeshi Ido, T. Watari, Katsumi Ida, Y. Hamada, and Osamu Yamagishi

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Scattering, Electron, Plasma, Tore Supra, Condensed Matter Physics, Spectral line, law.invention, Physics::Plasma Physics, law, Dispersion relation, Atomic physics, Microwave

Abstract

Magnetic, density and potential fluctuations up to 500?kHz at several spatial points have been observed in the core region of JIPPT-IIU tokamak plasmas using a heavy ion beam probe. The frequency spectra of the density and magnetic oscillations are found to be similar, whereas there are large differences in the phase, coherence and frequency dependences deduced from signals at adjacent sample volumes. These differences allow us to ascribe the detected magnetic fluctuations to the microtearing mode (MTM) by simple dispersion relations of the MTM in collisionless and intermediate regimes. The frequency-integrated level of magnetic fluctuations around 150?kHz (100?200?kHz) is , a level high enough for the ergodization of the magnetic surface and enhanced electron heat loss as derived by Rechester and Rosenbluth (1978 Phys. Rev. Lett. 40 38). This level is consistent with the measurements performed using cross-polarization scattering of microwaves in the Tore Supra tokamak. Our results are the first direct experimental verification of the MTM in the core region of tokamak plasmas, which has been recently observed in gyrokinetic simulations using a very fine mesh in tokamak and ST plasmas.

Published

2015

15. Extension of operation regimes and investigation of three-dimensional currentless plasmas in the Large Helical Device

Author

P. Drewelow, Tomoaki Hino, Suguru Masuzaki, Yasuhiko Takeiri, Masaru Furukawa, Kiyofumi Mukai, Atsushi Okamoto, B. Wieland, T. Kato, Hisamichi Funaba, Masafumi Itagaki, D. S. Darrow, K. Nagaoka, Takeshi Ido, S. Morita, Xiaodi Du, Chihiro Suzuki, Tsuyoshi Akiyama, Nobuaki Yoshida, Shin Kajita, Noriyoshi Nakajima, M. Tingfeng, Daisuke Kuwahara, Hideo Sugama, M. W. Jakubowski, Satoshi Ohdachi, Kimitaka Itoh, Ryo Yasuhara, Naohiro Kasuya, Naoki Tamura, Ichihiro Yamada, T. Fukuda, Keiji Sawada, Kenji Tanaka, K. Saito, Kazutoshi Tokunaga, Samuel Lazerson, Masayuki Yokoyama, Tsuyoshi Imai, Shinji Yoshimura, H. Lee, Mikiro Yoshinuma, Masaki Osakabe, J. Miyazawa, Shin Kubo, M. Sato, Hiroaki Nakamura, N. A. Pablant, T. Oishi, Akinobu Matsuyama, Tomokazu Yoshinaga, K. Nishimura, Satoru Sakakibara, Hiroyuki Takahashi, Hiroshi Kasahara, Tomohiro Morisaki, Naomichi Ezumi, Y. Takemura, Yasuhisa Oya, T. Nakano, Hirohiko Tanaka, Shigeru Inagaki, Hiroshi Yamada, Nobuyoshi Ohyabu, Kazumichi Narihara, Shigeru Sudo, Hiroe Igami, Kazunori Koga, Takuya Goto, Hiroto Matsuura, Kazunobu Nagasaki, Yoshio Nagayama, Kazuya Takahata, Yoshio Ueda, Osamu Mitarai, A. Komori, I. A. Sharov, Hiroshi Idei, Mitsutaka Isobe, Yoshiro Narushima, Takeo Muroga, Akio Sagara, Naoko Ashikawa, Ryosuke Seki, Kensaku Kamiya, Tsuguhiro Watanabe, T. Ito, Ryuhei Kumazawa, Kazuo Toi, Motoshi Goto, Katsunori Ikeda, W. Guttenfelder, Fumihiro Koike, Hayato Tsuchiya, Shoji Yamamoto, Shinji Hamaguchi, M. Takeuchi, Hirotaka Chikaraishi, Katsuyoshi Tsumori, Sadayoshi Murakami, Y. Nakamura, Tetsuhiro Obana, Akira Ejiri, A. Murakami, Clive Michael, Sadatsugu Muto, S. E. Sharapov, S. Matsuoka, Leonid Vyacheslavov, Mamiko Sasao, Y. Hirooka, Seiya Nishimura, Tsuyoshi Kariya, Sumio Kitajima, Byron J. Peterson, Teruya Tanaka, Mamoru Shoji, Toshiyuki Mito, Keisuke Fujii, Tokihiko Tokuzawa, Takashi Mutoh, Katsumi Ida, Haruhisa Nakano, V.Y. Sergeev, Ryuichi Sakamoto, Masaki Nishiura, Kazuo Kawahata, Masayuki Tokitani, David Gates, Yasuhiro Suzuki, Hiroyuki A. Sakaue, Y. Asahi, Kuninori Sato, Izumi Murakami, Y. M. Nunami, Daiji Kato, Evgeny A. Drapiko, K.Y. Watanabe, Todd Evans, Masahiro Hasuo, M. Okamoto, Sanae I. Itoh, Hideya Nakanishi, Masahiko Emoto, A. W. Cooper, Yasushi Todo, Kobayashi, Masaharu Shiratani, Takashi Shimozuma, Yasuo Yoshimura, S. Yamada, A. Iwamoto, Nagato Yanagi, Tomo-Hiko Watanabe, D. R. Mikkelsen, Noriyasu Ohno, T. Ozaki, Katsuji Ichiguchi, Kunihiro Ogawa, Akihiro Shimizu, Osamu Kaneko, Hitoshi Tamura, Gen Motojima, Tetsuo Seki, and Shinsaku Imagawa

Subjects

Nuclear and High Energy Physics, Materials science, Divertor, Plasma, Mechanics, Edge (geometry), Fusion power, Condensed Matter Physics, Resonant magnetic perturbations, Ion, Large Helical Device, Physics::Plasma Physics, Beta (plasma physics), Atomic physics

Abstract

The progress of physical understanding as well as parameter improvement of net-current-free helical plasma is reported for the Large Helical Device since the last Fusion Energy Conference in Daejeon in 2010. The second low-energy neutral beam line was installed, and the central ion temperature has exceeded 7 keV, which was obtained by carbon pellet injection. Transport analysis of the high-T-i plasmas shows that the ion-thermal conductivity and viscosity decreased after the pellet injection although the improvement does not last long. The effort has been focused on the optimization of plasma edge conditions to extend the operation regime towards higher ion temperature and more stable high density and high beta. For this purpose a portion of the open helical divertors are being modified to the baffle-structured closed ones aimed at active control of the edge plasma. It is compared with the open case that the neutral pressure in the closed helical divertor increased by ten times as predicted by modelling. Studies of physics in a three-dimensional geometry are highlighted in the topics related to the response to a resonant magnetic perturbation at the plasma periphery such as edge-localized-mode mitigation and divertor detachment. Novel approaches of non-local and non-diffusive transport have also been advanced.

Published

2013

16. Detection of the kinetic geodesic acoustic mode (KGAM) near the centre region of JIPPT-IIU tokamak plasmas

Author

Atsushi J. Nishizawa, Katsumi Ida, Y. Kawasumi, Osamu Yamagishi, Takeshi Ido, Mamoru Kojima, Kazumichi Narihara, Kazuo Toi, T. Watari, and Y. Hamada

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Statistics::Applications, Geodesic, Mode (statistics), Plasma, Condensed Matter Physics, Kinetic energy, Spectral line, Statistics::Computation, law.invention, Physics::Plasma Physics, law, Harmonics, Statistics::Methodology, Atomic physics, Beam (structure)

Abstract

The broad and intense spectrum of the geodesic acoustic mode (GAM) oscillations near the magnetic axis of tokamak plasmas with T e/T i ≫ 1 becomes narrow and weak during neutral beam heating. It then becomes wide and weak during third harmonics ICRF heating. The wide spectra of GAMs are generally consistent with recent kinetic GAM (KGAM) theories.

Published

2011

17. GAM generation by drift waves in JIPP T-llU tokamak core plasmas

Author

Kazuo Toi, Takeshi Ido, Atsushi J. Nishizawa, Y. Hamada, Mamoru Kojima, Kazumichi Narihara, Y. Kawasumi, Osamu Yamagishi, and T. Watari

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Turbulence, Zonal flow (plasma), Plasma, Condensed Matter Physics, law.invention, Physics::Plasma Physics, law, Energy flow, Physics::Space Physics, Wavenumber, Plasma diagnostics, Atomic physics, Bicoherence

Abstract

Density and potential fluctuations were measured in the core region of the JIPP-TIIU plasma using a heavy ion beam probe. By applying a new technique of wavenumber resolved bicoherence, the coupling of the drift waves with zonal flows was clearly observed. In addition, nonlinear energy flow from drift-wave turbulence to high-frequency zonal flows using Ritz's model equation was first observed in the core region of low-density tokamak plasmas, which means there is generation of GAM by drift waves. The nonlinear growth rate of high-frequency zonal flow was estimated to be in the order of 104 s−1 or higher. In additionally heated plasmas where low-frequency ion temperature gradient mode is dominant, the bicoherence pattern changes drastically.

Published

2010

18. Development of net-current free heliotron plasmas in the Large Helical Device

Author

Mamoru Shoji, Clive Michael, Katsumi Ida, Hideya Nakanishi, Kazuya Takahata, Osamu Mitarai, Masahiko Emoto, Takataro Hamajima, Kunihiro Ogawa, H. Miura, Yasushi Todo, Chihiro Suzuki, Osamu Yamagishi, Yoshiro Narushima, Ryuichi Sakamoto, S. Morita, Shinichiro Kado, Yasuhiko Takeiri, Yutaka Matsumoto, Hidenobu Takenaga, Sadatsugu Muto, Makoto Ichimura, Hiroyuki Okada, T. Ito, Motoshi Goto, Tetsuji Okamura, Yasuhiro Suzuki, Hiroyuki A. Sakaue, Akihiro Shimizu, Osamu Kaneko, Yasuo Yoshimura, S. Yamada, E. V. Veshchev, Masahiro Kobayashi, Mamiko Sasao, Mikiro Yoshinuma, Tomohiro Morisaki, Ryuhei Kumazawa, Katsunori Ikeda, Masaharu Shiratani, Hiroshi Kasahara, Noriaki Matsunami, M. Sato, Naomichi Ezumi, Tsuyoshi Akiyama, Masayuki Yokoyama, T. Fukuda, N. Yoshida, Hisamichi Funaba, Suguru Masuzaki, Seiya Nishimura, Kazunobu Nagasaki, Sumio Kitajima, A. Komori, Noriyoshi Nakajima, Takashi Shimozuma, T. Ohishi, Akihiko Isayama, Katsuji Ichiguchi, Shigeru Sudo, Tomoaki Hino, Takashi Minami, Mitsutaka Isobe, Hirohiko Tanaka, J. Miyazawa, Gen Motojima, A. Weller, Hajime Urano, Nobuhiro Nishino, Osamu Motojima, Malay Bikas Chowdhuri, Atsushi Iwamae, Tetsuo Seki, Tsuguhiro Watanabe, T. Osako, Tetsuhiro Obana, Luis Garcia, Naoki Mizuguchi, Shinsuke Satake, Nagato Yanagi, Nobuyoshi Ohyabu, Masaki Nishiura, Kazumichi Narihara, Hiroe Igami, Shigeru Inagaki, Soichiro Yamaguchi, Arata Nishimura, P. R. Goncharov, Izumi Murakami, K. Nishimura, Naoki Tamura, Shin Kubo, Daiji Kato, Tomokazu Yoshinaga, Sadao Masamune, Shinji Yoshimura, Tomo-Hiko Watanabe, Masaki Osakabe, Hideo Sugama, Yoshio Nagayama, T. Ido, Yuji Nakamura, Satoru Sakakibara, Hiroyuki Takahashi, K. Nagaoka, Hiroaki Nishimura, K. Saito, S. Iio, Hayato Tsuchiya, Hiroshi Idei, Sadayoshi Murakami, Y. Nakamura, Kazuo Kawahata, Shinichiro Toda, Byron J. Peterson, Takashi Notake, Kenji Okuno, Satoshi Ohdachi, Kimitaka Itoh, T. Kato, Hiroshi Yamada, Naoko Ashikawa, Kazuo Toi, T. Ishigooka, Shinji Hamaguchi, Kotaro Ono, Katsuyoshi Tsumori, Yuichi Takase, Katsumi Kondo, Ichihiro Yamada, Noriyasu Ohno, T. Ozaki, Masayuki Tokitani, Kenji Tanaka, Kuninori Sato, Tokihiko Tokuzawa, Takashi Mutoh, Haruhisa Nakano, Y. Feng, K.Y. Watanabe, F. Watanabe, Shinji Kobayashi, Toshiyuki Mito, Hirotaka Chikaraishi, M. Irie, Yoshihide Oka, and Shinsaku Imagawa

Subjects

Physics, Nuclear and High Energy Physics, Magnetic confinement fusion, Plasma, Fusion power, Condensed Matter Physics, Thermal conduction, law.invention, Ion, Nuclear physics, Large Helical Device, law, Beta (plasma physics), Atomic physics, Stellarator

Abstract

Remarkable progress in the physical parameters of net-current free plasmas has been made in the Large Helical Device (LHD) since the last Fusion Energy Conference in Chengdu, 2006 (Motojima et al 2007 Nucl. Fusion 47 S668). The beta value reached 5% and a high-beta state beyond 4.5% from the diamagnetic measurement has been maintained for longer than 100 times the energy confinement time. The density and temperature regimes have also been extended. The central density has exceeded 1 × 1021 m−3 due to the formation of an internal diffusion barrier. The ion temperature has reached 5.2 keV at the density of 1.6 × 1019 m−3, which is associated with the suppression of ion heat conduction loss. Although these parameters have been obtained in separated discharges, each fusion-reactor relevant parameter has elucidated the potential of net-current free heliotron plasmas. Diversified studies in recent LHD experiments are reviewed in this paper.

Published

2009