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51. Guidance of the divertor channel outside the main coil system for heliotron/torsatron devices

Author

N. Ohyabu and H. Takase

Subjects
Physics, Nuclear and High Energy Physics, Toroid, Field (physics), Electromagnetic coil, Nuclear engineering, Divertor, Remote area, Fusion power, Atomic physics, Condensed Matter Physics, Communication channel, Magnetic field
Abstract

A divertor magnetic configuration is proposed that significantly reduces heat load on the divertor plates in heliotron/torsatron devices. The proposed configuration utilizes an octupole field for guiding the divertor channels to a remote area outside the main coil system, where the magnetic field is weak. This allows a significant reduction of the heat load due to expansion of the divertor channels as well as substantially easier access to the divertor plates for maintenance, the key requirements for toroidal fusion reactor designs

Published
1995

52. Radial build between helical coil and plasma in the Large Helical Device

Author

N. Ohyabu, K. Yamazaki, Hantao Ji, S. Imagawa, H. Kaneko, S. Morimoto, N. Noda, T. Satow, J. Yamamoto, O. Motojima, and null LHD Design Group

Subjects
Quantitative Biology::Biomolecules, Materials science, Mechanical Engineering, Divertor, Torus, Field strength, Plasma, Radius, Large Helical Device, Nuclear magnetic resonance, Nuclear Energy and Engineering, Physics::Plasma Physics, Electromagnetic coil, General Materials Science, Atomic physics, Current density, Civil and Structural Engineering
Abstract

The Large Helical Device (LHD) is a heliotron/torsatron-type confinement device (B = 4 T, R = 3.9 m) equipped with a helical divertor. In the LHD configuration, the plasma region is shifted inwards approximately a third of the plasma minor radius relative to the center of the two pairing helical coils, thus making the distance between the coil center and the edge plasma small, 328 mm on the small major radius side of the torus. Within this space, many components must be installed, such as the superconducting helical coil (163), its coil can (45), the thermal shield (30), the vacuum gap (35), the plasma vacuum vessel (15), the first wall (25) (the numbers in the parentheses are allocated radial space in mm for the respective components). Effective edge plasma control by the divertor requires a space of more than 15 mm between the plasma and the first wall. To meet the above space requirement, the thickness of the helical coil is designed to be as small as possible, yet the coil current density and maximum field strength are within the limits of reliable coil operation.

Published
1993

53. Requirements for accuracy of superconducting coils in the Large Helical Device

Author

K. Yamazaki, N. Yanagi, H. Ji, H. Kaneko, N. Ohyabu, T. Satow, S. Morimoto, J. Yamamoto, O. Motojima, and null LHD Design Group

Subjects
Cryostat, Physics, Field (physics), Mechanical Engineering, Magnetic confinement fusion, Plasma, Mechanics, law.invention, Magnetic field, Large Helical Device, Nuclear magnetic resonance, Nuclear Energy and Engineering, law, Electromagnetic coil, Eddy current, General Materials Science, Civil and Structural Engineering
Abstract

Irregular magnetic fields resonate with the rational surface of the magnetic confinement systems, form magnetic islands and ergodic layers, and destruct the plasma confinement. To avoid this confinement destruction the requirement of an accuracy of 10 −4 in the magnetic field is adopted as the magnetic-accuracy design criterion for the LHD machine. Following this criterion the width of the undesirable magnetic island is kept less than one tenth of the plasma radius. The irregular magnetic field from the superconducting (SC) helical and poloidal coils is produced by winding irregularity, installing irregularity, cooling-down deformations and electromagnetic deformations. The local irregularities such as feeders, layer connections, adjacent-conductor connections of the coils also produce an error field. The eddy currents on the supporting shell structure of SC coils, the cryostat, etc. are also evaluated. All irregular effects are analyzed using Fourier decomposition and field mapping methods for the LHD design, and it is confirmed that the present design of the superconducting coil system satisfies the design criterion for these field irregularities.

Published
1993

54. Detachment stabilization with n/m=1/1 resonant magnetic perturbation field applied to the stochastic magnetic boundary of the Large Helical Device (invited)

Author

M., \\'Kobayashi, S., Masuzaki, I., Yamada, N., Tamura, Y., Feng, K., Sato, M., Goto, Y., Narushima, T., Akiyama, J., Miyazawa, M., Shoji, S., Morita, B.J., Peterson, H., Funaba, N., Ohyabu, K., Narihara, T., Morisaki, H., Yamada, A., Komori, Experimental Group, LHD, and D.\\', Reiter

Subjects
Physics, Large Helical Device, Physics::Plasma Physics, Divertor, Electron temperature, Flux, Plasma diagnostics, Plasma, Atomic physics, Magnetohydrodynamics, Condensed Matter Physics, Spectroscopy
Abstract

"It is found that the remnant island structure created by n/m=1/1 resonant magnetic perturbation field in the stochastic magnetic boundary of the Large Helical Device (LHD)[A. Komori et al.,Nucl. Fusion 49, 104015 (2009)] has a stabilizing effect on formation of radiating plasma, realizing stably sustained divertor detachment operation with the core plasma being unaffected. The data from the several diagnostics, (profiles of electron temperature and density, radiation and temporal evolution of divertor particle flux)indicate selective cooling around X-point of the island and thus peaked radiation there, which is stabilized outside of the last closed flux surface throughout the detachment phase. The vacuum ultraviolet spectroscopy measurements of high Z impurity (iron)emission shows significant decrease during the detachment, indicating core plasmadecontamination. The results from the three-dimensional (3D) edge transport code, edge Monte Carlo 3D (EMC3)[Y. Feng et al., Contrib. Plasma Phys. 44, 57 (2004)]-EIRENE [D. Reiter et al.,Fusion Sci. Technol. 47, 172 (2005)] show similar tendency in the radiation pattern. The island sizeand its radial location are varied to investigate the magnetic topology effects on the detachment control. The divertor particle flux and neutral pressure exhibit intermittent oscillation as well asmodification of recycling pattern during the detachment, which are found to reflect the island structure."

Published
2010

55. Effects of ergodization on plasma confinement in JFT-2M

Author

H. Aikawa, Toshihiko Yamauchi, Takaaki Fujita, M. Kazawa, N. Ohyabu, Toru Ogawa, T. Hamano, Nobuyuki Asakura, K. Hasegawa, T. Tokutake, T. Seike, Hikosuke Maeda, Shunji Tsuji, M. Mori, K. Kikuchi, Y. Kashiwa, Masaki Maeno, T. Shibata, Satoshi Kasai, Katsumichi Hoshino, A. Honda, G. Fuchs, A. W. Hyatt, Michiya Shimada, Kazuya Uehara, T. Shiina, Hiroaki Ogawa, Teruaki Shoji, E. Sato, Tatsuma D. Matsuda, Anthony Leonard, A.M. Howald, T. Tani, Hiroshi Tamai, Norio Suzuki, T. H. Jensen, T. Kawakami, Takumi Yamamoto, T. Yamasato, Y. Tomiyama, N. Seki, S. Suzuki, H. Okano, Hisato Kawashima, and Y.M. Miura

Subjects
Nuclear and High Energy Physics, Chemistry, Plasma confinement, Plasma, Auxiliary heating, Edge (geometry), Magnetic field, Plasma edge, Nuclear Energy and Engineering, Physics::Plasma Physics, Impurity, Electromagnetic coil, General Materials Science, Atomic physics
Abstract

A steady-state H-mode plasma with frequent ELMs (edge localized modes) was obtained by applying magnetic fields with high poloidal mode numbers resonant in the plasma edge. The induced ELMs limit the density and impurity accumulation normally observed during ELM-free H-mode. An EML coil with numerous resonant modes ( m 10) in the plasma edge appears the most effective. This method of control is extended to higher auxiliary heating power by increasing the magnitude of the magnetic perturbations.

Published
1992

56. Analysis of neoclassical transport in the banana regime with the DKES code for the Large Helical Device

Author

Noriyoshi Nakajima, Yuichi Ogawa, Ker-Chung Shaing, W. I. van Rij, N. Ohyabu, S.P. Hirshman, T. Amano, and K. Yamazaki

Subjects
Physics, Nuclear and High Energy Physics, Large Helical Device, Electric field, Radius, Electric potential, Statistical physics, Diffusion (business), Atomic physics, Condensed Matter Physics, Thermal diffusivity, Ion, Bootstrap current
Abstract

Neoclassical transport in the banana regime has been analysed with the DKES (Drift Kinetic Equation Solver) code for the Large Helical Device (LHD). It is found that in the 1/ν regime the diffusion coefficients change by one order of magnitude for various LHD configurations, depending on the structure of the helical magnetic ripple. The neoclassical transport calculated with the DKES code is quantitatively in good agreement with a multi-helicity theory formulated by Shaing and Hokin (1983). Incorporating the multi-helicity effect into the diffusion coefficient, the authors propose an interpolation formula for the diffusion coefficient in the 1/ν and ν regimes. When the ion temperature is increased at a fixed density of n = 1020 m-3, the ions undergo a transition from 1/ nu neoclassical transport to the nu regime when Ti > 3 keV, with a radial electric potential e comparable to the ion temperature (e/Ti ≈ 1). For the optimized configuration, the ion thermal diffusivity has a maximum value of ≈ 3.5 m2/s at a minor radius r/a ≈ 0.5. The bootstrap current has also been studied and the results have been compared with the theory. At the collisionless limit with a moderate radial electric potential of e/Ti ≈ 1, the DKES calculations evaluated for various LHD configurations support the theoretical formula given by Shaing and Callen (1983). For collision frequencies between the plateau regime and the banana regime, where the analytical theory is not applicable, the bootstrap current might become larger (by a factor of about two) than in the collisionless limit, depending on the radial electric field

Published
1992

57. Suppression of magnetic surface breaking by extra coils in finite beta equilibria of helical systems

Author

Tetsuya Sato, T. Hayashi, A. Takei, and N. Ohyabu

Subjects
Surface (mathematics), Physics, Nuclear and High Energy Physics, Condensed matter physics, law, Electrical equipment, Beta (plasma physics), Atmospheric-pressure plasma, Condensed Matter Physics, Stellarator, law.invention
Abstract

A simple method is proposed to suppress the breaking of magnetic surfaces which occurs in l = 2 heliotron/ torsatron equilibria. With this method, fairly high beta equilibria with clearly nested magnetic surfaces can be realized without changing other physical properties such as the rotational transform profile and the well depth.

Published
1991

58. Observation of the H-mode in ohmically heated divertor discharges on DIII-D

Author

D. N. Hill, W. Howl, K. H. Burrell, N.H. Brooks, N. Ohyabu, R. J. Groebner, L.L. Lao, T.H. Osborne, T. N. Carlstrom, A.G. Kellman, Mark E. Perry, and T. S. Taylor

Subjects
Nuclear and High Energy Physics, Materials science, DIII-D, Divertor, Particle, Auxiliary heating, Atomic physics, Condensed Matter Physics, Joule heating, Ohmic contact, Scaling
Abstract

On DIII-D, periods of improved particle and energy confinement have been observed in low q, low BT divertor discharges with Ohmic heating alone. The Ohmic H-mode has characteristics similar to those of the H-mode produced by auxiliary heating. In the Ohmic H-mode the energy confinement time can have values near those predicted by Neo-ALCATOR scaling and a factor of two above those of non-H-mode Ohmic discharges at similar densities. These observations indicate that the H-mode is not limited to an improvement in confinement over that of the L-mode in auxiliary heating discharges.

Published
1990

59. Observation of stable superdense core plasmas in the large helical device

Author

N., Ohyabu, T., Morisaki, S., Masuzaki, R., Sakamoto, M., Kobayashi, J., Miyazawa, M., Shoji, A., Komori, O., Motojima, and Experimental Group, LHD

Subjects
Maple, Physics, General Physics and Astronomy, High density, Plasma, engineering.material, Core (optical fiber), Large Helical Device, Nuclear magnetic resonance, Physics::Plasma Physics, Fusion ignition, engineering, Atomic physics, Internal diffusion, Dense core
Abstract

The anomalous particle transport in a tokamak core is believed to be linked to the advection of magnetically trapped electrons alone, owing to the passing electrons maintaining a thermal equilibrium along the field lines. Surprisingly, in nonlinear numerical studies, the radial flux of passing electrons rivals that of the trapped ones. The strong interaction of passing electrons and electric fluctuations is mediated by long tails of the modes along the magnetic field, which are generated by the passing electrons in the first place.

Published
2006

60. ECRH Experiments in an Extended Power Regime on the Large Helical Device

Author

T. Shimozuma, S. Kubo, H. Idei, Y. Yoshimura, T. Notake, T. Watari, Y. Mizuno, S. Ito, S. Kobayashi, Y. Takita, K. Narihara, I. Yamada, N. Ohyabu, K. Ida, S. Inagaki, Y. Nagayama, Y. Takeiri, H. Funaba, M. Yokoyama, S. Murakami, M. Emoto, M. Goto, K. Ikeda, R. Kumazawa, S. Masuzaki, T. Minami, J. Miyazawa, S. Morita, T. Morisaki, S. Muto, T. Mutoh, H. Nakanishi, Y. Narushima, K. Nishimura, N. Noda, S. Ohdachi, Y. Oka, M. Osakabe, T. Ozaki, B. J. Peterson, A. Sagara, S. Sakakibara, R. Sakamoto, M. Sasao, M. Sato, K. Satoh, T. Seki, S. Shoji, H. Suzuki, K. Tanaka, K. Toi, K. Tokuzawa, K. Tsumori, K. Y. Watanabe, M. Yoshinuma, K. Kawahata, Y. Nakamura, H. Yamada, O. Kaneko, A. Komori, K. Yamazaki, K. Ohkubo, S. Sudo, K. Itoh, K. Matsuoka, O. Motojima, and null LHD Experimental Group

Subjects
Physics, Large Helical Device, business.industry, Electronic engineering, Optoelectronics, business, Power (physics)
Published
2003

61. Divertors for Helical Devices: Concepts, Plans, Results, and Problems

Author

A. Komori, U. Wenzel, Y. Feng, K. Matsuoka, K. McCormick, T. Obiki, L. Giannone, N. Ohyabu, Suguru Masuzaki, T. Morisaki, Friedrich E. Wagner, Thomas Klinger, H. Ehmler, P. Grigull, Dirk Naujoks, N. Ramasubramanian, D. Hildebrandt, P. Mioduszewski, A. Werner, H. Renner, F. Gadelmeier, F. Sardei, H. Thomsen, J. Kisslinger, and R. König

Subjects
Physics, Nuclear and High Energy Physics, Toroid, Field line, 020209 energy, Mechanical Engineering, Divertor, Nuclear engineering, National Compact Stellarator Experiment, Magnetic confinement fusion, 02 engineering and technology, Fusion power, 01 natural sciences, 010305 fluids & plasmas, Nuclear physics, Large Helical Device, Nuclear Energy and Engineering, Heat flux, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Civil and Structural Engineering
Abstract

With Large Helical Device (LHD) and Wendelstein 7-X (W7-X), the development of helical devices is now taking a large step forward on the path to a steady-state fusion reactor. Important issues that need to be settled in these machines are particle flux and heat control and the impact of divertors on plasma performance in future continuously burning fusion plasmas. The divertor concepts that will initially be explored in these large machines were prepared in smaller-scale devices like Heliotron E, Compact Helical System (CHS), and Wendelstein 7-AS (W7-AS). While advanced divertor scenarios relevant for W7-X were already studied in W7-AS, other smaller-scale experiments like Heliotron-J, CHS, and National Compact Stellarator Experiment will be used for the further development of divertor concepts. The two divertor configurations that are being investigated are the helical and the island divertor, as well as the local island divertor, which was successfully demonstrated on CHS and just went into operation on LHD. At present, on its route to a fully closed helical divertor, LHD operates in an open helical divertor configuration. W7-X will be equipped right from the start with an actively cooled discrete island divertor that will allow quasi-continuous operation. The divertor design is very similar to the one explored on W7-AS. For sufficiently large island sizes and not too long field line connection lengths, this divertor gives access to a partially detached quasi-steady-state operating scenario in a newly found high-density H-mode operating regime, which benefits from high energy and low impurity confinement times, with edge radiation levels of up to 90% and sufficient neutral compression in the sub-divertor region (>10) for active pumping. The basic physics of the different divertor concepts and associated implementation problems, like asymmetries due to drifts, accessibility of essential operating scenarios, toroidal asymmetries due to symmetry breaking error fields, etc., are discussed.

Published
2003

62. Spatial Distribution Measurement of High Energy Particle using Time-Of-Flight Neutral Particle Energy Analyzer in Large Helical Device

Author

S. Ohdachi, R. Kumazawa, Shin Kubo, Hisamichi Funaba, Kazuo Sato, N. Ohyabu, S. Sakakibara, Y. Takeiri, K. Tanaka, B. J. Peterson, Mamiko Sasao, O. Motojima, Mamoru Shoji, Katsumi Ida, Satoshi Morita, Y. Nagayama, Kazuo Kawahata, V. Zanza, H. Torii, Kenji Saito, A. Sibio, H. Nakanishi, Katsunori Ikeda, S. Murakami, O. Kanko, Tomo-Hiko Watanabe, Tetsuo Watari, K. Narihara, M. Emoto, Motoshi Goto, K. Tsumori, Hiroshi Idei, Nobuaki Noda, P. Goncharov, S. Muto, Y. Nakamura, B. Tilia, M. Osakabe, T. Shimozuma, T. Ozaki, T. Mutoh, Giovanni Bracco, Y. Oka, T. Seki, T. Kobuchi, and Shigeru Sudo

Subjects
Physics, Time of flight, Spectrum analyzer, Large Helical Device, Optics, High energy particle, business.industry, Port (circuit theory), Pitch angle, Atomic physics, Viewing angle, business, Neutral particle
Abstract

The time-of-flight neutral particle measurement system1 has been installed on the 10-O port at the 2nd campaign. It has the capability of two-dimensional measurement with a larger viewing angle by using the pivot on the rectangular port, which is set inside of the 10-O mother port. The movable stage with the vertical scan mechanism rotates on the fan shaped stainless rails around the pivot. The sight lines of −2 to 32 degrees against the 10-O port surface makes the angle between the sight line and the magnetic axis of the standard configuration (3.6 m) of 95 to 35 in the 4th campaign. Therefore the analyzer can observe high-energy particles with these pitch angles. The higher scan speed of 0.17 degree/second than that in the last campaign (0.05 degree/s) can be obtained in this campaign. Precise spatial distribution of the high-energy particles can be expected because it enables the continuous scanning in the long discharge.

Published
2002

64. Energy confinement time and heat transport in initial neutral beam heated plasmas on the large helical device

Author

H. Yamada, K. Y. Watanabe, S. Sakakibara, S. Murakami, M. Osakabe, O. Kaneko, K. Narihara, K. Tanaka, K. Ida, T. Minami, M. Goto, H. Idei, S. Inagaki, S. Kado, K. Kawahata, A. Komori, S. Kubo, J. Miyazawa, T. Morisaki, S. Morita, H. Nakanishi, S. Ohdachi, N. Ohyabu, Y. Oka, B. J. Peterson, R. Sakamoto, M. Shoji, H. Suzuki, Y. Takeiri, K. Toi, T. Tokuzawa, K. Tsumori, I. Yamada, K. Ohkubo, S. Sudo, K. Yamazaki, O. Motojima, M. Fujiwara, and null LHD Experimental Group

Subjects
Maple, Materials science, General Physics and Astronomy, Plasma, Edge (geometry), engineering.material, Core (optical fiber), Large Helical Device, Pedestal, Nuclear magnetic resonance, Physics::Plasma Physics, engineering, Atomic physics, Scaling, Beam (structure)
Abstract

The confinement characteristics of large net-current-free plasmas heated by neutral-beam injection have been investigated in the Large Helical Device (LHD). A systematic enhancement in energy-confinement times from the scaling derived from the medium-sized heliotron/torsatron experiments have been observed, which is attributed to the edge pedestal. The core confinement is scaled with the Bohm term divided by the square root of the gyro radii. The comparative analysis using a dimensionally similar discharge in the Compact Helical System indicates gyro-Bohm dependence in the core and transport improvement in the edge region of LHD plasmas.

Published
1999

65. Edge thermal transport barrier In LHD discharges

Author

N. Ohyabu, K. Narihara, H. Funaba, T. Morisaki, S. Masuzaki, K. Kawahata, A. Komori, O. Kaneko, H. Yamada, P. deVries, M. Emoto, M. Goto, Y. Hamada, K. Ida, H. Idei, S. Inagaki, N. Inoue, S. Kado, S. Kubo, R. Kumazawa, T. Minami, J. Miyazawa, S. Morita, S. Murakami, T. Mutoh, S. Muto, Y. Nagayama, Y. Nakamura, H. Nakanishi, K. Nishimura, N. Noda, T. Kobuchi, S. Ohdachi, K. Ohkubo, Y. Oka, M. Osakabe, T. Ozaki, B. J. Peterson, A. Sagara, S. Sakakibara, R. Sakamoto, H. Sasao, M. Sasao, K. Sato, K. Saito, M. Sato, T. Seki, T. Shimozuma, M. Shoji, H. Suzuki, S. Sudo, Y. Takeiri, K. Tanaka, K. Toi, T. Tokuzawa, K. Tsumori, K. Tsuzuki, I. Yamada, S. Yamaguchi, K. Yamazaki, M. Yokoyama, K. Y. Watanabe, T. Watari, and O. Motojima

Subjects
Thermal barrier coating, Global energy, Materials science, Tokamak, Thermal transport, Condensed matter physics, Impurity, law, General Physics and Astronomy, Particle, Edge (geometry), High ratio, law.invention
Abstract

In LHD discharges a significant enhancement of the global energy confinement has been achieved for the first time in a helical device with an edge thermal barrier, which exhibits a sharp gradient at the edge of the temperature profile. Key features associated with the barrier are quite different from those seen in tokamaks: (i) almost no change in particle (including impurity) transport, (ii) a gradual formation of the barrier, (iii) a very high ratio of the edge temperature to the average temperature, and (iv) no edge relaxation phenomenon. These features are very attractive in applying the thermal barrier to future reactor grade devices.

Published
1999

66. Edge plasma control by a local island divertor in the Compact Helical System

Author

N. Ohyabu, S. Masuzaki, and A. Komori

Subjects
Chemistry, Divertor, Perturbation (astronomy), Particle flow, Atomic physics, Plasma control, Plasma density
Abstract

A local island divertor (LID) experiment was performed on the Compact Helical System (CHS) to demonstrate the principle of the LID. It was clearly demonstrated that the particle flow is controlled by adding a resonant perturbation field to the CHS magnetic configuration, and is guided to the back of an m/n = 1/1 island which is created by the perturbation field. The particles recycled there were pumped out with a pumping rate in the range from a few percent to about 10%. As a result, the line averaged core density was reduced by a factor of about 2 in comparison with non-LID discharges at the same gas puffing rate. In addition to the demonstration of these fundamental divertor functions, a modest improvement of energy confinement was observed, which could be attributed to the edge plasma control by the LID.

Published
1997

67. Nonlinear dynamics of a collapse phenomenon in heliotron plasma with large pressure gradient

Author

N. Ohyabu, N. Mizuguchi, and Yasuhiro Suzuki

Subjects
Physics, Nuclear and High Energy Physics, Large Helical Device, Nonlinear system, Classical mechanics, Field line, Magnetic pressure, Mechanics, Plasma, Condensed Matter Physics, Instability, Pressure gradient, Magnetic field
Abstract

We have executed nonlinear magnetohydrodynamic simulations in a heliotron-type configuration with a large pressure gradient to reveal the nonlinear dynamics of a collapse phenomenon. The simulation results reproduce the qualitative characteristics of the experimental observation on the so-called core density collapse events in the Large Helical Device plasma with the super-dense core profile. A long-term nonlinear behaviour on the event, including the flushing mechanism of the core pressure, is clarified. The simulation result shows the linear growth of the ballooning-like resistive instability modes with the intermediate poloidal wavenumbers. The growth of the modes are eventually saturated, and the system experiences the energy relaxation in about 1 ms. It should be noted that the linear mode structures are localized in the edge region, whereas the core pressure rapidly falls as the system reaches the relaxed state. Such coexistence of the edge perturbation and the core collapse is consistent with the experimental observations. The lost pressure forms a wide base in the peripheral region. The core pressure is, on the other hand, remarkably reduced at a certain period, although it had well withstood the disturbance before it. The most salient feature on this period is the disordering of the magnetic field structure. The system keeps the nested-flux-surface structure well at the beginning, whereas part of them are abruptly lost in this period. Such a situation can induce a flattening of the pressure profile along the reconnected field lines. By checking the place where the plasma loss due to this mechanism occurs, such plasma outlets are found to be located mainly on the disordered region. Thus, one can conclude that the core collapse can be caused by the disturbance of the magnetic field.

Published
2009

68. Dependence of spontaneous growth and suppression of the magnetic island on beta and collisionality in the LHD

Author

Satoru Sakakibara, Hiroshi Yamada, Yoshiro Narushima, K. Narihara, K.Y. Watanabe, Satoshi Ohdachi, Yuji Nakamura, N. Ohyabu, Ichihiro Yamada, and Yasuhiro Suzuki

Subjects
Physics, Nuclear and High Energy Physics, Toroid, Condensed matter physics, Perturbation (astronomy), Magnetic field perturbation, Plasma, Collisionality, equipment and supplies, Condensed Matter Physics, Critical value, Magnetic field, Large Helical Device, human activities
Abstract

The dynamics of the magnetic island structure in the plasma are investigated in plasmas with a wide range of beta and collisionality. The perturbed magnetic field is diagnosed by a toroidal array of flux loops installed in the vacuum vessel on the Large Helical Device (LHD). It is found that the magnetic island grows with beta at relatively low beta values. In contrast, when the beta exceeds a critical value, the sign of the perturbed magnetic field suddenly reverses and its strength saturates to the magnetic field perturbation required to cancel the external perturbation. This suggests spontaneous healing of the magnetic island.

Published
2008

69. Extension of the high-ion-temperature regime in the Large Helical Device

Author

M., Yokoyama, K., Nagaoka, M., Yoshinuma, Y., Takeiri, K., Ida, S., Morita, O., Kaneko, T., Seki, H., Kasahara, T., Mutoh, Y., Oka, K., Tsumori, M., Osakabe, K., Ikeda, K., Tanaka, H., Funaba, S., Matsuoka, S., Masuzaki, J., Miyazawa, R., Sakamoto, H., Yamada, K., Kawahata, N., Ohyabu, S., Imagawa, A., Komori, S., Sudo, O., Motojima, and Experimental Group, LHD

Subjects
Physics, plasma confinement, Fusion, Hydrogen, Ambipolar diffusion, chemistry.chemical_element, Plasma, Condensed Matter Physics, Thermal diffusivity, plasma transport processes, Ion, Large Helical Device, plasma beam injection heating, chemistry, hydrogen, Electric field, plasma flow, stellarators, Atomic physics, plasma temperature
Abstract

High-ion-temperature (exceeding 5 keV) hydrogen plasmas have been successfully produced in the Large Helical Device [Iiyoshi et al., Nucl. Fusion 39, 1245 (1999); Motojima et al., Nucl. Fusion 47, S668 (2007)] with the ion heat confinement improvement in the core region. The experimental ion heat diffusivity at the core region is found to be almost independent of the ion temperature, T_i (even decreasing as T_i increases). The neoclassical (NC) ripple transport is suppressed by the ambipolar radial electric field, E_r (

Published
2008

70. Superdense core mode in the Large Helical Device with an internal diffusion barrier

Author

T., Morisaki, N., Ohyabu, S., Masuzaki, M., Kobayashi, R., Sakamoto, J., Miyazawa, H., Funaba, K., Ida, K., Ikeda, O., Kaneko, S., Morita, S., Mutoh, K., Nagaoka, Y., Nagayama, N., Nakajima, K., Narihara, Y., Oka, M., Osakabe, B.J., Peterson, S., Sakakibara, M., Shoji, Y., Suzuki, Y., Takeiri, N., Tamura, K., Tanaka, K., Tsumori, K.Y., Watanabe, I., Yamada, H., Yamada, A., Komori, O., Motojima, and Experiment Group, LHD

Subjects
Core (optical fiber), Physics, Large Helical Device, Density gradient, Divertor, Pellets, Electron temperature, Plasma, Magnetohydrodynamics, Atomic physics, Condensed Matter Physics
Abstract

In reduced recycling discharges using a local island divertor in the Large Helical Device [O. Motojima, H. Yamada, A. Komori et al., Phys. Plasmas 6, 1843 (1999)], a stable high-density plasma develops in the core region when a series of pellets is injected. A core region with ~5×10^20 m^?3 and temperature of 0.85 keV is maintained by an internal diffusion barrier (IDB). The density gradient at the IDB (r/a~0.6) is very high, and the particle confinement time in the core region is ~0.4 s. Because of the increase in the central pressure, a large Shafranov shift up to ~0.3 m is observed. The critical ingredients for IDB formation are a strongly pumped divertor to reduce edge recycling, and multiple pellet injection to ensure efficient central fueling. No serious magnetohydrodynamics activity and impurity accumulation have been observed so far in this improved discharge.

Published
2007

71. Magnetic Diagnostics of Magnetic Island in LHD

Author

Y. NARUSHIMA, K. Y. WATANABE, S. SAKAKIBARA, N. OHYABU, H. YAMADA, K. NARIHARA, I. YAMADA, T. MORISAKI, S. INAGAKI, Y. NAGAYAMA, A. KOMORI, null LHD exp. group, and W. A. COOPER

Subjects
Physics, Toroid, Phase (waves), magnetic diagnostics, Plasma, Condensed Matter Physics, Large Helical Device, Magnetic flux, Magnetic field, Amplitude, Nuclear magnetic resonance, self-healing, Plasma diagnostics, Atomic physics, magnetic island
Abstract

Characteristics of magnetic islands are investigated by magnetic diagnostics in the L arge Helical Device (LHD). The structure of the magnetic island with m/n = 1/ 1( where,m and n are poloidal and toroidal mode number, respectively) can be estimated from the perturbed magnetic field appearing when a magnetic island changes. To measure the toroidal profile of the perturbed magnetic field δb1 originating from the plasma, a toroidal array of magnetic flux loops is set up in the LHD. The toroidal profile of δb1 is then spatially Fourier decomposed to determine the amplitude of the n = 1c omponent, δb n=1 1 and its phase, φn=1 whic hc orrespond the change of the island width and the toroidal position of the X-point of the island, respectively. Therefore, the information about the magnetic island structure can be obtained from δb n=1 1 and φn=1 .I ncase the island width becomes larger than the seed island, measurements show that δb n=1 1 is non-zero and φn=1 is temporally constant. A non-zero δb n=1 1 can also be observed when the island width becomes smaller than the seed island. In this case, the angle φn=1 shifts by about π[rad] compared with the increasing case and the δb n=1 1 is limited to a certain value whic hc orresponding to the magnetic field suppressing the seed island.

Published
2007

72. Thirty-minute plasma sustainment by real-time magnetic-axis swing for effective divertor-load-dispersion in the Large Helical Device

Author

T. Mutoh, S. Masuzaki, R. Kumazawa, T. Seki, K. Saito, Y. Nakamura, S. Kubo, Y. Takeiri, T. Shimozuma, Y. Yoshimura, H. Igami, K. Ohkubo, T. Watanabe, H. Ogawa, J. Miyazawa, M. Shoji, N. Ashikawa, K. Nishimura, M. Sakamoto, M. Osakabe, K. Tsumori, K. Ikeda, H. Chikaraishi, H. Funaba, S. Morita, M. Goto, T. Tokuzawa, N. Takeuchi, F. Shimpo, G. Nomura, C. Takahashi, M. Yokota, Y. P. Zhao, J. G. Kwak, H. Yamada, K. Kawahata, N. Ohyabu, O. Kaneko, K. Ida, Y. Nagayama, N. Noda, A. Komori, S. Sudo, O. Motojima, and null LHD Experiment Group

Subjects
Physics, Electron density, Hydrogen, Nuclear engineering, Divertor, chemistry.chemical_element, Plasma, Radius, Condensed Matter Physics, Large Helical Device, chemistry, Electron temperature, Atomic physics, Dispersion (chemistry)
Abstract

Achieving steady-state plasma operation at high plasma temperatures is one of the important goals of worldwide magnetic fusion research. A high temperature of approximately 2 keV, and steady-state plasma-sustainment operation of the Large Helical Device (LHD) [O. Motojima, K. Akaishi, H. Chikaraishi et al., Nucl. Fusion 40, 599 (2000)] is reported. High-temperature plasmas were created and maintained for more than 30 min with a world record injected heating power of 1.3 GJ. The three-dimensional heat-deposition profile of the LHD helical divertor was modified and during long-pulse discharges it effectively dispersed the heat load using a magnetic-axis swing technique developed at the LHD. A sweep of only 3 cm of the major radius of the magnetic axis position (less than 1% of the major radius of the LHD) was enough to disperse the divertor heat load. The modification of the heat-load profile was explained well by field-line tracing. The steady-state plasma was heated and sustained mainly by hydrogen minority ion heating using ion cyclotron range of frequencies. The operation lasted until a sudden increase of radiation loss occurred, presumably because of wall metal flakes dropping into the plasma. The sustained line-averaged electron density was approximately 0.7?0.8×10^19 m^?3. The average input power was 680 kW, and the plasma duration was 31 min 45 s. This successful long operation shows that the heliotron configuration has a high potential as a steady-state fusion reactor.

Published
2006

73. Characteristics of confinement and stability in large helical device edge plasmas

Author

A., Komori, S., Sakakibara, T., Morisaki, K.Y., Watanabe, Y., Narushima, K., Toi, S., Ohdachi, S., Masuzaki, M., Kobayashi, M., Shoji, N., Ohyabu, K., Ida, K., Tanaka, K., Kawahata, K., Narihara, S., Morita, B. J., Peterson, R., Sakamoto, H., Yamada, K., Ikeda, O., Kaneko, S., Kubo, J., Miyazawa, K., Nagaoka, H., Nakanishi, K., Ohkubo, Y., Oka, M., Osakabe, T., Shimozuma, Y., Takeiri, K., Tsumori, I., Yamada, Y., Yoshimura, M., Yoshinuma, and O., Motojima

Subjects
Physics, Large Helical Device, Physics::Plasma Physics, Divertor, Physics::Space Physics, Limiter, Electron temperature, Plasma, Edge (geometry), Atomic physics, Magnetohydrodynamics, Condensed Matter Physics, Flattening
Abstract

Recent progress in the heating capability in the large helical device [O. Motojima et al., Phys. Plasmas 6, 1843 (1999)] has allowed the highest average beta value (4.1%) obtained in the helical devices, and enables exploration of magnetohydrodynamics (MHD) stability in this beta region. MHD activities in the periphery are found to become stable spontaneously from the inner region to the outer region when the averaged beta value exceeds a threshold, and then a flattening of the electron temperature profile is observed around the resonant surface. Such a flattening can be formed externally by producing an m/n=1/1 magnetic island, and the complete stabilization of the m/n=1/1 mode is demonstrated by the moderate island width. In addition, attempts to control peripheral plasmas are also performed by using a limiter and a local island divertor utilizing the m/n=1/1 island, to improve plasma confinement and, especially, to stabilize pressure-driven modes in the present study. The stabilization of peripheral MHD modes is obtained with both approaches, and this indicates that these are available to the production of higher-beta plasmas without edge MHD activities.

Published
2005

74. Observation of the low to high confinement transition in the large helical device

Author

K. Toi, S. Ohdachi, S. Yamamoto, S. Sakakibara, K. Narihara, K. Tanaka, S. Morita, T. Morisaki, M. Goto, S. Takagi, F. Watanabe, N. Nakajima, K. Y. Watanabe, K. Ida, K. Ikeda, S. Inagaki, O. Kaneko, K. Kawahata, A. Komori, S. Masuzaki, K. Matsuoka, J. Miyazawa, K. Nagaoka, Y. Nagayama, Y. Oka, M. Osakabe, N. Ohyabu, Y. Takeiri, T. Tokuzawa, K. Tsumori, H. Yamada, I. Yamada, K. Yoshinuma, and null LHD Experimental Group

Subjects
Physics, Large Helical Device, Electron density, Toroid, Physics::Plasma Physics, Electron temperature, Magnetohydrodynamic drive, Plasma, Atomic physics, Magnetohydrodynamics, Condensed Matter Physics, Neutral beam injection
Abstract

The low to high confinement transition has been observed on the large helical device [A. Iiyoshi, A. Komori, A. Ejiri et al., Nucl. Fusion 39, 1245 (1999)], exhibiting rapid increase in edge electron density with sharp depression of H_alpha emission. The transition occurs in low toroidal field (B_t = 0.5?0.75 T) discharges and are heated by high power neutral beam injection. The plasma thus has a relatively high value (~1.5%) of the volume averaged beta value. The electron temperature and density profiles have steep gradients at the edge region which has high magnetic shear but is at a magnetic hill. Formation of the edge transport barrier leads to enhanced activities of the interchange type of modes with m = 2/n = 3 (m,n are the poloidal and toroidal mode numbers) in the edge region. At present, these magnetohydrodynamic activities limit the rise of the stored energy; the resultant increment of the stored energy remains modest.

Published
2005

77. Recent advances in the LHD experiment.

Author

O. Motojima, N. Ohyabu, A. Komori, O. Kaneko, H. Yamada, K. Kawahata, Y. Nakamura, K. Ida, T. Akiyama, N. Ashikawa, W.A. Cooper, A. Ejiri, M. Emoto, N. Ezumi, H. Funaba, A. Fukuyama, P. Goncharov, M. Goto, H. Idei, and K. Ikeda

Published
2003

78. A simple model of energy confinement in tokamaks

Author

J.S. de Grassie, N. Ohyabu, and J.K. Lee

Subjects
Physics, Nuclear and High Energy Physics, Tokamak, Condensed matter physics, Mode (statistics), Mechanics, Edge (geometry), Condensed Matter Physics, Stability (probability), law.invention, law, Tearing, Current (fluid), Current density, Energy (signal processing)
Abstract

A simple model of energy confinement in tokamaks is proposed. In this model, the temperature and current profiles are determined by tearing mode stability considerations. As a result, the global energy confinement becomes strongly dependent on the boundary energy transport. A higher edge temperature ensures a higher core temperature and hence a higher global energy confinement.

Published
1986

79. Physics Guidelines for the Compact Ignition Tokamak

Author

S. D. Scott, R. A. Dory, P. Liewer, N. Ohyabu, M.G. Bell, John Sheffield, David Ross, Wayne A Houlberg, Douglass E. Post, Nermin A. Uckan, R.D. Stambaugh, J. Hosea, Martin Greenwald, Clifford E. Singer, Stanley Kaye, K. H. Burrell, M. Petravic, Kenneth M. Young, P. Colestock, and Harold Weitzner

Subjects
Physics, Tokamak, 020209 energy, Divertor, Nuclear engineering, General Engineering, Plasma confinement, 02 engineering and technology, Plasma, 01 natural sciences, 010305 fluids & plasmas, law.invention, Ignition system, Nuclear physics, law, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, High current, Alpha power, Plasma density
Abstract

The goal of the Compact Ignition Tokamak (CIT)d program is to provide a cost-effective route to the production of a burning deuterium-tritium plasma, so that alpha-particle effects may be studied. A key issue to be studied in the CIT is whether alpha power behaves like other power sources in affecting tokamak plasma confinement. The program is managed by the Princeton Physics Laboratory and includes broad community involvement. Guidelines for the preliminary design effort have been provided by the Ignition Technical Oversight Committee in discussion with the tokamak community. The reference design is a tokamak with a high filed (10 T), high current (10 MA), poloidal divertor, and liquid-nitrogen-cooled coils. It is a small, high-power-density device of the type proposed by Bruno Coppi (MIT). It has a major radius of 1.23 m, a minor radius of 0.43 m, and plasma elipticity of 1.8. This paper reviews the aims of the program and the basis for the physics guidelines. The role of the CIT in the longer-term tokamak program is briefly discussed. 23 refs., 9 figs., 1 tab.

Published
1986

80. Preliminary results from the ergodic magnetic limiter experiment on the TEXT experimental tokamak

Author

J.S. DeGrassie, H. Ikezi, T.S. Taylor, N.H. Brooks, and N. Ohyabu

Subjects
Physics, Nuclear and High Energy Physics, Tokamak, Field (physics), business.industry, Mechanics, Modular design, law.invention, Nuclear Energy and Engineering, law, Limiter, Ergodic theory, General Materials Science, business
Abstract

The first experimental test of the ergodic magnetic limiter concept is being conducted on the TEXT device. Modular coils have been installed on TEXT allowing the external generation of resonant helical field perturbations. Preliminary results are presented.

Published
1984

81. EXPANDED BOUNDARY APPROACH TO IMPURITY CONTROL IN TOKAMAKS

Author

N. Ohyabu

Subjects
Tokamak, Materials science, Radiative cooling, Boundary (topology), Flux, Mechanics, Edge (geometry), law.invention, Physics::Plasma Physics, Impurity, law, Limiter, Radiative transfer, Atomic physics
Abstract

It is proposed to expand the outermost flux surfaces in tokamaks to provide a large volume for radiative cooling. The radiative power at the boundary is enhanced by the effects of plasma flow as well as by a volumetric factor, and the resultant edge cooling and reduced heat load on the limiter may significantly retard impurity generation.

Published
1979

82. Experiments to test an intra-island scoop limiter on TEXT

Author

F. Karger, G. Haas, P. E. Phillips, W. L. Hodge, J.S. DeGrassie, G.L. Jackson, William L. Rowan, Alan J Wootton, Ch. P. Ritz, S. C. McCool, N. Ohyabu, Kenneth W Gentle, T. L. Rhodes, T.E. Evans, and B. Richards

Subjects
Physics, Nuclear and High Energy Physics, business.industry, Aperture, Divertor, Analytical chemistry, Radius, Temperature measurement, Magnetic field, law.invention, Optics, Pressure measurement, Nuclear Energy and Engineering, law, Limiter, Particle, General Materials Science, business
Abstract

An instrumented scoop limiter probe is being operated on TEXT to test the concept of limiter cooling and improved particle removal efficiencies using an externally-applied resonant magnetic field perturbation (the resonant helical divertor concept). Cooling of the limiter face has been demonstrated for limiter positions ranging from r L = 29.0 cm inward to r L = 25.5 cm (the Text primary poloidal hoop limiter radius r a = 27.0 cm). Pressure rises in the limiter throat of approximatel 40% are observed under optimized conditions. Interchangable limiter heads with thicknesses of 1.0 cm and 0.3 cm have been used to examine particle ducting into the scoop aperture. Experimental results are discussed along with observations of the limiter floating potential, H α recycling emissions, pressure measurements, and edge density and temperature measurements.

Published
1987

83. Thermal stability of the radiative boundary

Author

N. Ohyabu

Subjects
Physics, Tokamak, Classical mechanics, Physics::Plasma Physics, law, Radiative transfer, Boundary (topology), Thermal stability, Mechanics, Plasma, law.invention
Abstract

An analytic derivation is presented of a condition for thermal stability of a radiatively cooled tokamak boundary. Application of these results to the expanded boundary configuration shows that such plasmas are thermally stable over the parameter regime of interest.

Published
1981

84. Strong Ion Heating in a Magnetic Neutral Point Discharge

Author

S. Okamura, N. Ohyabu, and Nobuki Kawashima

Subjects
Physics, Range (particle radiation), Magnetic energy, Waves in plasmas, Chemistry, General Engineering, Plasma, equipment and supplies, Ion acoustic wave, Ion, Magnetic field, Physics::Plasma Physics, Electrical resistivity and conductivity, Physics::Space Physics, Plasma diagnostics, Electromagnetic electron wave, Astrophysical plasma, Atomic physics, Excitation
Abstract

An experiment is performed to study the magnetic energy dissipation and ion heating in a magnetic neutral point discharge which is related to both an explosive energy dissipation in space plasma phenomena and the ion heating in thermonuclear fusion research.A plasma current sheet is created by exciting a plasma current along the magnetic neutral line of a two dimensional quadrupole magnetic field. A sudden anomalous increase of resistivity is observed which results in fast energy dissipation and strong plasma heating. The sudden increase of the plasma resistivity appears earlier and its magnitude increases as, i) the plasma density is decreased, ii) the discharge plasma current is increased or iii) the external quadrupole magnetic field is increased. When the sharp rise of the resistivity appears, the electron and ion temperatures rise abruptly up to several keV range Within 0.5μsec and about 10% of the initial energy Stored in the capacitor (for the plasma current excitation) is converted into ion thermal energy. This strong and efficient ion heating cannot be explained by a simple classical process and the role of turbulent waves should be important.

Published
1974

85. Possible applications of a resonant helical magnetic field in the tokamak boundary

Author

N. Ohyabu and J.S. DeGrassie

Subjects
Physics, Nuclear and High Energy Physics, Tokamak, Condensed matter physics, Flux, Boundary (topology), Condensed Matter Physics, Computational physics, law.invention, Magnetic field, law, Impurity, Heat transfer, Radiative transfer, High heat
Abstract

Application of a resonant helical magnetic field to the tokamak boundary may provide substantial improvement in performance. This configuration could establish the radiative boundary for handling high heat flux and minimizing impurity generation. Also described is the potential for improved confinement with properly selected resonant perturbations.

Published
1987

86. Highβ and ECRH studies in DIII-D

Author

R Stambaugh, S Allen, G Bramson, N Brooks, K H Burrell, R Callis, T Carlstrom, M Chance, M Chu, A Colleraine, D Content, J DeBoo, J Ferron, H Fukumoto, P Gohil, N Gottardi, R J Groebner, G Haas, W Heidbrink, D Hill, R Hong, N Hosogane, W Howl, C Hsieh, G L Jackson, G Jahns, R James, A Kellman, J Kim, S Konshita, L Lao, E Lazarus, J Lohr, P Lomas, J Luxon, M Mahdavi, M Matsuoka, M Mayberry, C P Moeller, N Ohyabu, T Osborne, D Overskei, T Ozeki, S Perkins, P Petersen, M Perry, T Petrie, J Phillips, G Porter, R Prater, M Rensink, D Schissel, J Scoville, R Seraydarian, M Shimada, T Simonen, R T Snider, B Stallard, R Stav, H St John, R Stockdale, E J Strait, T S Taylor, and A Turnbull

Subjects
Physics, Tokamak, DIII-D, Divertor, Sawtooth wave, Condensed Matter Physics, Instability, Ballooning, law.invention, Nuclear physics, Nuclear Energy and Engineering, law, Beta (plasma physics), Pressure gradient
Abstract

The DIII-D high and low beta stability results have established the basic feasibility of the divertor and H-mode configurations up to elongation 2.0 for next generation tokamaks. The 6.8% beta T achieved has already exceeded projected operating requirements of next generation devices. beta T > 6% has been sustained for 800 ms. Stability calculations and patterns of MHD mode behavior suggest a central expanding zone of ballooning instabilities leads ultimately to unstable m/n=2/1 modes which cause beta collapse or disruption. The pressure gradient at the plasma edge just reaches the first regime ballooning limit prior to ELMs. ECRH has proven effective for generating H-mode, sawtooth suppression, and ELM suppression.

Published
1988

87. Electron thermal confinement studies with applied resonant fields on TEXT

Author

Kenneth W Gentle, Y.X. He, N. Ohyabu, S. B. Zheng, Alan J Wootton, S. C. McCool, B. A. Smith, M. S. Foster, B. Richards, David W. Ross, W. A. Peebles, Roger D. Bengtson, R.L. Hickock, W.H. Miner, Neville C. Luhmann, Todd Evans, Jose Boedo, J. C. Forster, A. Y. Aydemir, Ch. P. Ritz, Mike Kotschenreuther, S.P. Fan, P. M. Schoch, Se Kwon Kim, G.L. Jackson, P. E. Phillips, W. L. Rowan, X. H. Yu, J.S. deGrassie, D. L. Brower, R. V. Bravenec, J. C. Wiley, D. M. Patterson, and T. L. Rhodes

Subjects
Physics, Nuclear and High Energy Physics, Tokamak, Toroid, Condensed matter physics, Electron, Edge (geometry), Condensed Matter Physics, Thermal diffusivity, law.invention, Magnetic field, Physics::Plasma Physics, law, Thermal, Electron temperature
Abstract

Externally applied magnetic fields are used on the Texas Experimental Tokamak (TEXT) to study the possibility of controlling the particle, impurity and heat fluxes at the plasma edge. Fields with toroidal mode number n = 2 or 3 and multiple poloidal mode numbers m (dominantly m = 7) are used, with a poloidally and toroidally averaged ratio of radial to toroidal field components 〈|br/Bo〉 ≅0. 1%. Calculations show that it is possible to produce mixed islands and stochastic regions at the plasma edge (r/a ≥ 0.8) without affecting the interior. The expected magnetic field structure is described and experimental evidence of the existence of this structure is presented. The edge electron temperature decreases with increasing 〈|br/Bo〉, while interior values are not significantly affected. The implied increase in edge electron thermal diffusivity is compared with theoretical expectations and is shown to agree with applicable theories to within a factor of three.

Published
1989

88. Delayed Emission Excited by a High Power Microwave Pulse

Author

N. Ohyabu, O. Kaneko, S. Sasaki, and N. Kawashima

Subjects
Physics, Dense plasma focus, Materials science, Cyclotron, General Engineering, Cyclotron resonance, Electron, Plasma, Plasma oscillation, law.invention, Physics::Plasma Physics, law, Excited state, Harmonics, Physics::Space Physics, Harmonic, Electromagnetic electron wave, Atomic physics, Microwave
Abstract

An experiment is performed to study the interaction of a high power microwave pulse with a magnetized dense plasma. A delayed emission appears after the complete termination of a pumping microwave pulse when the frequency of the pumping wave is equal to the harmonics of the cyclotron frequency and is near the plasma frequency. Three types of the delayed mission (type I, II, III) are observed, depending on the experimental conditions. Type I delayed emission is characterized by the frequency spectrum with sharp peaks at cyclotron harmonics (mfce m= 1, 2, ..), type II with broad peaks between (m+1/2) fce and (m + 1) fce and type III with broad peak between 0.8 fce and fce. Main properties of these phenomena are explained in terms of anomalous power absorption at cyclotron harmonic resonances and excitation of electron plasma waves by an anisotropic electron velocity distribution. Each type of the delayed emission can be triggered artificially by a sudden decrease of cold back ground plasma density and is suppressed by an increase of cold plasma. It can be also triggered by a pulsed electron beam.

Published
1975

89. Merging tokamaks

Author

N. Ohyabu, C. L. Hsieh, and T. H. Jensen

Subjects
Condensed Matter Physics
Abstract

The concept of merging tokamak plasmas is proposed. It has potential applications for solving the problems of pseudo steady-state tokamak operation, refuelling, impurity removal and plasma heating. The currents in the two merging tokamak plasmas are in the same direction so that the columns attract each other. A model for the merging process is given.

Published
1979

90. Expanded Boundary with Destroyed Flux Surfaces

Author

N. Ohyabu

Subjects
Engineering, Tokamak, business.industry, Boundary (topology), Flux, Plasma, Mechanics, law.invention, Power (physics), Core (optical fiber), Heat flux, Physics::Plasma Physics, law, Electromagnetic coil, business, Simulation
Abstract

It is proposed to expand the outermost flux surfaces in tokamaks to divert the heat flux emerging from the plasma core. The approach previously discussed in detail is to deform the poloidal field configuration for expansion of the boundary. A simpler approach is discussed here which does not require any coil system or power supply, an attractive feature for reactor application.

Published
1980

91. Features of edge magnetic turbulence in DIII-D expanded boundary divertor discharges

Author

T.H. Osborne, G.L. Jahns, N. Ohyabu, E. J. Strait, and R.D. Stambaugh

Subjects
Physics, Nuclear and High Energy Physics, DIII-D, Condensed matter physics, Turbulence, Divertor, Plasma, Condensed Matter Physics, Amplitude, Physics::Plasma Physics, Plasma parameter, Atomic physics, Edge-localized mode, Line (formation)
Abstract

It is found that the magnetic fluctuation amplitudes abruptly decrease at L-H transitions and increase at H-ELM transitions (ELM is the edge localized mode). No other plasma parameter change precedes the magnetic signals, suggesting that the fluctuations are responsible for the increased edge transport in regimes with poor confinement. The fluctuation amplitude during L- and ELM-phases is largest at the points where the separatrix intersects the divertor plates. This is interpreted as evidence for the existence of line tied image currents in the scrape-off plasma.

Published
1989

92. Study of Giant Edge-Localized Modes in DIII-D and Comparison with Ballooning Theory

Author

L. L. Lao, R. D. Stambaugh, R. T. Snider, R. E. Stockdale, C. L. Hsieh, M. Ali Mahdavi, Keith H. Burrell, Ming-Sheng Chu, N. Ohyabu, J.C. DeBoo, and P. Gohil

Subjects
Physics, DIII-D, Physics::Plasma Physics, General Physics and Astronomy, Atmospheric-pressure plasma, Plasma, Atomic physics, Curvature, Instability, Pressure gradient, Ballooning, Marginal stability
Abstract

In DIII-D H-mode plasmas, large amplitude modulation of steep edge electron pressure gradients are observed during the occurrences of giant edge-localized modes (ELM's). For a considerable range of plasma currents (1 to 2 MA), the experimental pressure gradient before a giant ELM is close to the theoretically predicted marginal stability limit for the first regime of the ideal ballooning mode. These results, together with observations showing that ELM's originate in the region of bad curvature, strongly suggest that ELM's are triggered by ballooning mode instabilities.

Published
1988

93. Role of particle recycling in beam heated expanded boundary divertor discharges in D-III

Author

N.H. Brooks, G. Zawadski, S. Ejima, N. Ohyabu, J.C. DeBoo, T.S. Taylor, R.D. Stambaugh, and K.H. Burrell

Subjects
Nuclear and High Energy Physics, Large particle, Nuclear Energy and Engineering, Chemistry, Separatrix, Divertor, Monte Carlo method, Limiter, General Materials Science, Penetration (firestop), Plasma, Atomic physics
Abstract

Discharges with improved energy confinement are produced in Doublet III when the major recycling location is shifted away from the main plasma by forming an expanded boundary (XB) divertor configuration with a separatrix to limiter separation Δ > 1.5 cm. Monte Carlo calculations indicate that over a wide range in density the divertor plasma effectively limits the penetration of recycled neutrals to the main plasma. This results in large particle recycling rates at the divertor plates and a reduction of particle recycling near the main plasma. This divertor function apparently plays an important role in obtaining improved energy confinement. Particle containment, as inferred from variations in Dα emission near the main plasma, is found to decrease with n e and BT, and increases rapidly (faster than quadratic) with IP whereas energy confinement is relatively insensitive to variations in n e and BT and increases linearly with IP. This improved energy confinement with the XB divertor configuration is suggestive of particle confinement playing an important role. However, in view of their rather different parametric dependences, the correlation between τP and τE, if any, remains unclear.

Published
1984

94. A double-layer field-shaping coil system

Author

N. Ohyabu

Subjects
Quantitative Biology::Biomolecules, Nuclear and High Energy Physics, Materials science, Acoustics, Physics::Medical Physics, Voice coil, Plasma, Condensed Matter Physics, Power (physics), Nuclear magnetic resonance, Physics::Plasma Physics, Electromagnetic coil, Plasma shaping, Magnetohydrodynamics, Layer (electronics), Rogowski coil
Abstract

A new field-shaping coil concept is proposed which allows satisfactory plasma shaping and control and is compatible with some stringent reactor design requirements. The proposed field-shaping coil system has two coil layers. The inner coil layer, situated immediately outside the first wall, is very close to the plasma, thus significantly improving both MHD equilibrium and stability. The role of the outer coil layer,is to minimize the current in the inner coil layer, i.e. to reduce the power required to maintain the plasma configuration.

Published
1978

95. Ergodic magnetic limiter experiments on TEXT with a resonance

Author

Kenneth W Gentle, J. Porter, R. D. Bengston, K. Leung, B. Richards, J.S. deGrassie, P. E. Phillips, William L. Rowan, S. J. Levinson, K. Nelin, Ch. P. Ritz, T. P. Kochanski, W. L. Hodge, S. B. Kim, N.H. Brooks, J. A. Snipes, T. P. Price, C. Christopher Klepper, N. Ohyabu, and R. V. Bravenec

Subjects
Nuclear and High Energy Physics, Electron density, Condensed matter physics, Chemistry, Field line, Perturbation (astronomy), symbols.namesake, Nuclear magnetic resonance, Nuclear Energy and Engineering, Impurity, Limiter, symbols, Ergodic theory, Langmuir probe, Electron temperature, General Materials Science
Abstract

The ergodic magnetic limiter coils on TEXT have been reconfigured to produce the primary helical perturbation resonance at m = 7 n = 3 . The experiments continue to demonstrate that the weak resonant perturbations modify the edge conditions in keeping with model predictions. We observe a reduction in the intrinsic impurity levels accompanying the helical current pulse, presumably the result of a reduction in the electron temperature in the edge. Heat follows the perturbed field lines to the limiter, generating heat load patterns which reflect the geometry of a magnetic island-limiter intersection. A strong spatial modulation of the electron density in the scrape-off-layer also reflects the helical mode structure.

Published
1984

96. NEW TOROIDAL COIL SYSTEM FOR TOKAMAKS

Author

N. Ohyabu

Subjects
Reduction (complexity), Engineering, Tokamak, Toroidal coil, Electromagnetic coil, business.industry, law, Nuclear engineering, Toroidal field, Electrical engineering, Radio frequency, business, law.invention
Abstract

An idea is suggested which leads to a significant reduction in the required number of toroidal field coils and to a dramatic improvement in access for tokamak maintenance and diagnostics. It is found that a two or four coil system may be practical. The basic concept is presently being used for designing RST (Radio Frequency Driven, Steady-State Tokamak) of General Atomic Company.

Published
1979

97. Attainment of reactor level volume-averaged toroidal beta in doublet III

Author

R.K. Fisher, J.R. Treglio, S.S. Wojtowicz, J.T. Scoville, J.R. Smith, J. Kim, C.L. Hsieh, T.S. Taylor, R. Hong, A.P. Colleraine, G. Bramson, L. Rottler, R.D. Stambaugh, R.W. Harvey, N. Ohyabu, R.P. Seraydarian, R.L. Silagi, J.H. Kamperschroer, E.S. Fairbanks, T. McMahon, R.W. Callis, R.L. Freeman, F.P. Blau, T.R. Angel, F.B. Marcus, W. Pfeiffer, J.F. Tooker, J.C. Wesley, K.H. Burrell, R.D. Stav, T.W. Petrie, S. Ejima, R.J. Groebner, D.O. Overskei, A.J. Lieber, J.L. Luxon, N.H. Brooks, G.L. Jahns, T.N. Todd, J. Fasolo, J.C. DeBoo, T. Ohkawa, P.I. Petersen, C.J. Armentrout, R.T. Snider, J.M. Lohr, J.R. Gilleland, D.R. Eames, D.F. Vaslow, R.P. Chase, G. Zawadzki, D.B. McColl, M.A. Mahdavi, J.M. Rawls, and S.K. Wong

Subjects
Physics, Nuclear and High Energy Physics, Tokamak, Toroid, Volume (thermodynamics), law, Beta (plasma physics), Atomic physics, Elongation, Condensed Matter Physics, law.invention
Abstract

Using a neutral-beam injection power of 3.4 M W, volume-averaged toroidal betas of up to βT = 4.5% have been obtained in low-toroidal-field, low-qψ, vertically elongated discharges in the Doublet III tokamak. This level of βT is above the minimum level required for a tokamak reactor, thus demonstrating that reactor level values of βT are possible in a tokamak device. The observed enhancement of βT with vertical elongation lends confidence in the design of future devices which rely on vertical elongation.

Published
1983

98. Resonant helical divertor experiments in ohmic and auxiliary heated JIPP T-IIU plasmas

Author

J.S. deGrassie, L. S. Peranich, Shoichi Okamura, Kohnosuke Sato, Y. Hamada, F. Karger, Katsumi Ida, Osamu Kaneko, S. Kitagawa, Icrf, Tsutomu Kuroda, Akihiro Mohri, Tetsuo Watari, Anthony Leonard, Jipp T-Iiu Operation Groups, Satoshi Morita, Yuichi Ogawa, Kazuo Kawahata, Kozo Yamazaki, M. Sakamoto, Harold R. Garner, Kuniaki Masai, Todd Evans, Hiroshi Yamada, and N. Ohyabu

Subjects
Nuclear and High Energy Physics, Convective heat transfer, Chemistry, Divertor, Plasma, Instability, Ion, symbols.namesake, Nuclear Energy and Engineering, Physics::Plasma Physics, Limiter, symbols, Langmuir probe, General Materials Science, Atomic physics, Magnetohydrodynamics
Abstract

A series of initial resonant helical divertor (RHD) experiments have been carried out in ohmically and auxiliary heated JIPP T-IIU plasmas. Disruptive and MHD instabilities make the interpretation of the RHD results difficult but an apparent increase in the energy confinement time is observed when the helical magnetic perturbation is applied. This may be due to the suppression of MHD activity or to a reduction in the edge convective heat losses. Magnetic island effects have been observed on the floating potential of a Langmuir probe array and energy scrape-off layer widths have been measured with and without helical perturbations during ICRF operation. Basic pump limiter data is presented including ion temperatures and C4+ impurity profiles. Energy confinement times are reported in ohmically and NBI heated discharges.

Published
1989

99. Density limit in tokamaks

Author

N. Ohyabu

Subjects
Physics, Nuclear and High Energy Physics, Tokamak, Differential equation, Boundary (topology), Plasma, Condensed Matter Physics, Computational physics, law.invention, Physics::Plasma Physics, law, Quantum electrodynamics, Density limit, Thermal stability, Limit (mathematics), Perturbation theory
Abstract

From a condition for thermal stability of the plasma boundary in tokamaks, an upper limit on the density which is consistent with the experimental observations has been derived.

Published
1979

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