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1,350 results on '"Nagaoka, K."'

1. Analysis of the ECH effect on the EPM/AEs stability in Heliotron J plasma using a Landau closure model

Author

Varela, J., Nagasaki, K., Kobayashi, S., Nagaoka, K., Adulsiriswad, P., Cappa, A., Yamamoto, S., Watanabe, K. Y., Spong, D. A., Garcia, L., Ghai, Y., and Ortiz, J.

Subjects
Physics - Plasma Physics
Abstract

The aim of the present study is to analyze the effect of the electron cyclotron heating (ECH) on the linear stability of Alfven Eigenmodes (AE) and energetic particle modes (EPM) triggered by energetic ions in Heliotron J plasma. The analysis is performed using the FAR3d code that solves a reduced MHD model to describe the thermal plasma coupled with a gyrofluid model for the energetic particles (EP) species. The simulations reproduce the AE/EPM stability trends observed in the experiments as the electron temperature (Te) increases, modifying the thermal plasma beta, EP beta and EP slowing down time. Particularly, the n/m=1/2 EPM and 2/4 Global AE (GAE) are stabilized in the low bumpiness (LB) configuration due to an enhancement of the continuum, Finite Larmor radius (FLR) and e-i Landau damping effects as the thermal beta increases. On the other hand, a larger ECH injection power cannot stabilize the AE/EPM in Medium (MB) and High bumpiness (HB) configurations because the damping effects are weaker compared to the LB case, unable to balance the further destabilization induced by an enhanced EP resonance as the EP slowing down time and EP beta increases with Te

Published
2023
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3. Modeling of the ECCD injection effect on the Heliotron J and LHD plasma stability

Author

Varela, J., Nagasaki, K., Nagaoka, K., Yamamoto, S., Watanabe, K. Y., Spong, D. A., Garcia, L., Cappa, A., and Azegami, A.

Subjects
Physics - Plasma Physics
Abstract

The aim of the study is to analyze the stability of the Energetic Particle Modes (EPM) and Alfven Eigenmodes (AE) in Helitron J and LHD plasma if the electron cyclotron current drive (ECCD) is applied. The analysis is performed using the code FAR3d that solves the reduced MHD equations describing the linear evolution of the poloidal flux and the toroidal component of the vorticity in a full 3D system, coupled with equations of density and parallel velocity moments for the energetic particle (EP) species, including the effect of the acoustic modes. The Landau damping and resonant destabilization effects are added via the closure relation. The simulation results show that the n=1 EPM and n=2 Global AE (GAE) in Heliotron J plasma can be stabilized if the magnetic shear is enhanced at the plasma periphery by an increase (co-ECCD injection) or decrease (ctr-ECCD injection) of the rotational transform at the magnetic axis iota0. In the ctr-ECCD simulations, the EPM/AE growth rate decreases only below a given iota0, similar to the ECCD intensity threshold observed in the experiments. In addition, ctr-ECCD simulations show an enhancement of the continuum damping. The simulations of the LHD discharges with ctr-ECCD injection indicate the stabilization of the n=1 EPM, n=2 Toroidal AE (TAE) and n=3 TAE, caused by an enhancement of the continuum damping in the inner plasma leading to a higher EP beta threshold with respect to the co- and no-ECCD simulations.

Published
2020
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4. Effect of the tangential NBI current drive on the stability of pressure and energetic particle driven MHD modes in LHD plasma

Author

Varela, J., Cooper, W. A., Nagaoka, K., Watanabe, K. Y., Spong, D. A., Garcia, L., Cappa, A., and Azegami, A.

Subjects
Physics - Plasma Physics
Abstract

The aim of the present study is to analyze the stability of the pressure gradient driven modes (PM) and Alfven eigenmodes (AE) in the Large Helical Device (LHD) plasma if the rotational transform profile is modified by the current drive of the tangential neutral beam injectors (NBI). This study forms a basic search for optimized operation scenarios with reduced mode activity. The analysis is performed using the code FAR3d which solves the reduced MHD equations describing the linear evolution of the poloidal flux and the toroidal component of the vorticity in a full 3D system, coupled with equations for density and parallel velocity moments of the energetic particle (EP) species, including the effect of the acoustic modes. The Landau damping and resonant destabilization effects are added via the closure relation. On-axis and off-axis NBI current drive modifies the rotational transform which becomes strongly distorted as the intensity of the neutral beam current drive (NBCD) increases, leading to wider continuum gaps and modifying the magnetic shear. The simulations with on-axis NBI injection show that a counter (ctr-) NBCD in inward shifted and default configurations leads to a lower growth rate of the PM, although strong n=1 and 2 AEs can be destabilized. For the outward shifted configurations, a co-NBCD improves the AEs stability but the PM are further destabilized if the co-NBCD intensity is 30 kA/T. If the NBI injection is off-axis, the plasma stability is not significantly improved due to the further destabilization of the AE and energetic particle modes (EPM) in the middle and outer plasma region.

Published
2020
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7. Overview of Large Helical Device experiments of basic plasma physics for solving crucial issues in reaching burning plasma conditions

Author

Ida, K., Yoshinuma, M., Kobayashi, M., Kobayashi, T., Kenmochi, N., Nespoli, F., Magee, R. M., Warmer, F., Dinklage, A., Matsuyama, A., Sakamoto, R., Nasu, T., Tokuzawa, T., Kinoshita, T., Tanaka, K., Tamura, N., Nagaoka, K., Nishiura, M., Takemura, Y., Ogawa, K., Motojima, G., Oishi, T., Morishita, Y., Varela, J., Hayashi, W. H.J., Markl, M., Bouvain, H., Liang, Y., Leconte, M., Moseev, D., Moiseenko, V. E., Albert, C. G., Allfrey, I., Alonso, A., Arellano, F. J., Ashikawa, N., Azegami, A., Bardoczi, L., van Berkel, M., Beurskens, M., Binderbaue, M. W., Bortolon, A., Brezinsek, S., Bussiahn, R., Cappa, A., Carralero, D., Chan, I. C., Cheng, J., Dai, X., Salewski, M., Ida, K., Yoshinuma, M., Kobayashi, M., Kobayashi, T., Kenmochi, N., Nespoli, F., Magee, R. M., Warmer, F., Dinklage, A., Matsuyama, A., Sakamoto, R., Nasu, T., Tokuzawa, T., Kinoshita, T., Tanaka, K., Tamura, N., Nagaoka, K., Nishiura, M., Takemura, Y., Ogawa, K., Motojima, G., Oishi, T., Morishita, Y., Varela, J., Hayashi, W. H.J., Markl, M., Bouvain, H., Liang, Y., Leconte, M., Moseev, D., Moiseenko, V. E., Albert, C. G., Allfrey, I., Alonso, A., Arellano, F. J., Ashikawa, N., Azegami, A., Bardoczi, L., van Berkel, M., Beurskens, M., Binderbaue, M. W., Bortolon, A., Brezinsek, S., Bussiahn, R., Cappa, A., Carralero, D., Chan, I. C., Cheng, J., Dai, X., and Salewski, M.

Abstract

Recently, experiments on basic plasma physics issues for solving future problems in fusion energy have been performed on a Large Helical Device. There are several problems to be solved in future devices for fusion energy. Emerging issues in burning plasma are: alpha-channeling (ion heating by alpha particles), turbulence and transport in electron dominant heating helium ash exhaust, reduction of the divertor heat load. To solve these problems, understanding the basic plasma physics of (1) wave-particle interaction through (inverse) Landau damping, (2) characteristics of electron-scale (high-k) turbulence, (3) ion mixing and the isotope effect, and (4) turbulence spreading and detachment, is necessary. This overview discusses the experimental studies on these issues and turbulent transport in multi-ion plasma and other issues in the appendix.

Published
2024

10. MHD stability trends and improved performance of LHD inward-shifted configurations: The role of the neutral beam current drive and thermal plasma density.

Author

Varela, J., Nagaoka, K., Takemura, Y., Watanabe, K. Y., Ida, K., Yoshinuma, M., Nagasaki, K., Cappa, A., Sharapov, S., Spong, D. A., Garcia, L., Ghai, Y., and Ortiz, J.

Subjects
*THERMAL plasmas, *PLASMA density, *POLITICAL stability, *NEUTRAL beams, *PLASMA flow
Abstract

The aim of the present study is to analyze the effect of the neutral beam current drive (NBCD), thermal plasma density, and NBI operational regime on the stability of pressure gradient-driven modes (PGDM) and Alfvén eigenmodes (AE) in LHD inward-shifted configurations. The stabilization of n / m = 1 / 2 PGDM (n toroidal mode and m poloidal mode) is observed in the discharge 167 800 during the co-NBCD phase. The iota profile evolution measured by motional stark effect diagnostic may indicate the iota profile up-shift caused by the co-NBCD can induce a non-resonant transition of the rational surface 1/2 before the mode stabilization. The evolution of the iota profile and continuum gaps in the discharge 167 805 during the ctr-NBCD phase leads to the stabilization of the AE, caused by the narrowing of the continuum gap as the iota profile down-shift. Opposite stability trends are identified for PGDM and AE stability with respect to the thermal plasma density. A larger thermal plasma density (larger thermal β) further enhances PGDM although the continuum gaps are narrower leading to configurations with stable AEs. The linear stability of AEs is analyzed using the gyro-fluid FAR3d code to reproduce the AE stability trends observed in the experiments with respect to the NBCD and thermal plasma density. The analysis of hypothetical scenarios dedicated to study different NBI operational regimes with respect to EP energy, and β and radial density profiles indicate off-axis NBI operation shows a higher EP β threshold to destabilize AEs compared to on-axis configuration. This is explained by the presence of a TAE gap in the inner plasma region, easily destabilized by an on-axis NBI injection. The control of the NBCD and thermal plasma in the discharge 167 800 shows a transitory stabilization of PGDM and AEs, as well as an improved discharge performance identified by an increment of the neutron fluxes. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Experimental studies of zonal flow and field in compact helical system plasma

Author

Fujisawa, A, Itoh, K, Shimizu, A, Nakano, H, Ohshima, S, Iguchi, H, Matsuoka, K, Okamura, S, Minami, T, Yoshimura, Y, Nagaoka, K, Ida, K, Toi, K, Takahashi, C, Kojima, M, Nishimura, S, Isobe, M, Suzuki, C, Akiyama, T, Ido, T, Nagashima, Y, Itoh, SI, and Diamond, PH

Subjects
Fluids & Plasmas, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Astronomical and Space Sciences, Classical Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics
Abstract

The experimental studies on zonal flows and turbulence have been carried out in Compact Helical System [K. Matsuoka, S. Kubo, M. Hosokawa, in Plasma Physics and Controlled Nuclear Fusion Research, Proc. 12th Int. Conf., Nice, 1988 (International Atomic Energy Agency, Vienna, 1989, Vol. 2, p. 411] using twin heavy ion beam probes. The paper presents the experimental observations of stationary zonal flow, nonlinear couplings between zonal flow and turbulence, and the role of zonal flow in the improved confinement, together with the recent discovery of zonal magnetic field. The presented experimental results strongly support the new paradigm that the plasma transport should be considered as a system of drift wave and zonal flows, and provides the first direct evidence for turbulence dynamo that the structured magnetic field can be really generated by turbulence. © 2008 American Institute of Physics.

Published
2008

18. Experimental Evidence of a Zonal Magnetic Field in a Toroidal Plasma

Author

Fujisawa, A, Itoh, K, Shimizu, A, Nakano, H, Ohshima, S, Iguchi, H, Matsuoka, K, Okamura, S, Minami, T, Yoshimura, Y, Nagaoka, K, Ida, K, Toi, K, Takahashi, C, Kojima, M, Nishimura, S, Isobe, M, Suzuki, C, Akiyama, T, Nagashima, Y, Itoh, S-I, and Diamond, PH

Subjects
Mathematical Sciences, Physical Sciences, Engineering, General Physics
Abstract

A zonal magnetic field is found in a toroidal plasma. The magnetic field has a symmetric bandlike structure, which is uniform in the toroidal and poloidal directions and varies radially with a finite wavelength of mesoscale, which is analogous to zonal flows. A time-dependent bicoherence analysis reveals that the magnetic field should be generated by the background plasma turbulence. The discovery is classified as a new kind of phenomenon of structured magnetic field generation, giving insight into phenomena such as dipole field generation in rotational planets.

Published
2007

20. Application of two-dimensional temperature response functions for reconstruction of divertor heat flux profile in commercial fusion reactors.

Author

Bui, X. N. S., Matsuura, H., Hayashi, Y., Nagaoka, K., and Masuzaki, S.

Subjects
FUSION reactor divertors, HEAT flux, FUSION reactors, HEAT conduction, NEUTRON flux, HIGH temperatures, SUPERCONDUCTING quantum interference devices
Abstract

To keep the tritium breeding rate TBR > 1 and to meet the high heat load and neutron shielding requirements for the first wall and divertor in fusion demonstration (DEMO) reactors, the number of port plugs and other openings must be limited. To accomplish this, it is necessary to develop alternatives to the use of infrared (IR) thermography to determine the peak heat flux and the heat flux profile onto divertor targets. A divertor tile equipped with multiple temperature monitoring channels can be used to reproduce the temperature profile. To avoid the high temperatures and high neutron flux environment in a DEMO, the monitoring positions can be set well away from the irradiated surface. However, the spatial resolution of this method is lower than that provided by IR thermography. In the present work, we apply two-dimensional temperature response functions and the corresponding heat conduction model to temperature data obtained from a divertor tile surface in the large helical device to study the effects of the spatial resolution of the monitored temperature profile on the reconstructed heat flux profile. The findings provide information that will be useful in defining a method for embedding thermocouples into the divertor tiles of future DEMO reactors. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Identification of Zonal Flows in a Toroidal Plasma

Author

Fujisawa, A, Itoh, K, Iguchi, H, Matsuoka, K, Okamura, S, Shimizu, A, Minami, T, Yoshimura, Y, Nagaoka, K, Takahashi, C, Kojima, M, Nakano, H, Ohsima, S, Nishimura, S, Isobe, M, Suzuki, C, Akiyama, T, Ida, K, Toi, K, Itoh, S-I, and Diamond, PH

Subjects
Mathematical Sciences, Physical Sciences, Engineering, General Physics
Abstract

This Letter presents experimental confirmation of the presence of zonal flows in magnetically confined toroidal plasma using an advanced diagnostic system--dual heavy ion beam probes. The simultaneous observation of an electric field at two distant toroidal locations (approximately 1.5 m apart) in the high temperature (approximately 1 keV) plasma provides a fluctuation spectrum of electric field (or flow), a spatiotemporal structure of the zonal flows (characteristic radial length of approximately 1.5 cm and lifetime of approximately 1.5 ms), their long-range correlation with toroidal symmetry (n=0), and the difference in the zonal flow amplitude with and without a transport barrier. These constitute essential elements of turbulence-zonal flow systems, and illustrate one of the fundamental processes of structure formation in nature.

Published
2004

29. Commissioning of the first KSTAR neutral beam injection system and beam experiments

Author

Bae, Y.S., Park, Y.M., Kim, J.S., Han, W.S., Kwak, S.W., Chang, Y.B., Park, H.T., Song, N.H., Yang, H.L., Yoon, S.W., Jeon, Y.M., Hahn, S.H., Lee, S.G., Ko, W.H., England, A.C., Kim, W.C., Oh, Y.K., Kwak, J.G., Kwon, M., Chang, D.H., Jeong, S.H., Kim, T.S., Oh, B.H., Jin, J.T., In, S.R., Lee, K.W., Chang, D.S., Watanabe, K., Dairaku, M., Tobari, H., Kashiwagi, M., Hanada, M., Inoue, T., Ikeda, Y., Kawai, M., Komata, M., Mogaki, K., Usui, K., Yamamoto, T., Matsuoka, M., Nagaoka, K., and Grisham, L.

Published
2012
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30. Nonuniform plasma meniscus modelling based on backward calculation of negative ion beamlet

Author

Kisaki, M., Nagaoka, K., Slief, J.H., Haba, Y., Nakamoto, R., Tsumori, K., Nakano, H., Ikeda, K., Osakabe, M., Kisaki, M., Nagaoka, K., Slief, J.H., Haba, Y., Nakamoto, R., Tsumori, K., Nakano, H., Ikeda, K., and Osakabe, M.

Abstract

The shape of a plasma meniscus is a key factor to determine the beam focusing. The physics model of the meniscus formation for hydrogen negative ion sources has not been established yet. A backward trajectory calculation based on experimental observation is performed in order to derive the particle information at the meniscus. It is observed that the negative ion density is spatially nonuniform in the direction parallel to the magnets for suppression of co-extracted electrons. A nonuniformity of the negative ion density in the vicinity of the meniscus is taken into account in the forward trajectory calculation. It reveals that the nonuniform negative ion distribution leads to degradation of the beam focusing and the beam splitting in phase space. The importance of the spatial distribution of negative ions on meniscus modelling is discussed with a comparison to uniform extraction model.

Published
2022

37. Direct observation of the non-locality of non-diffusive counter-gradient electron thermal transport during the formation of hollow electron-temperature profiles in the Large Helical Device

Author

Tsujimura, T. I., primary, Kobayashi, T., additional, Tanaka, K., additional, Ida, K., additional, Nagaoka, K., additional, Yoshinuma, M., additional, Yamada, I., additional, Funaba, H., additional, Seki, R., additional, Satake, S., additional, Kinoshita, T., additional, Tokuzawa, T., additional, Kenmochi, N., additional, Igami, H., additional, Mukai, K., additional, Goto, M., additional, and Kawamoto, Y., additional

Published
2022
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38. 10 years of engineering and physics achievements by the Large Helical Device project

Author

Yamada, H., Imagawa, S., Takeiri, Y., Kaneko, O., Mutoh, T., Mito, T., Chikaraishi, H., Hamaguchi, S., Ida, K., Igami, H., Ikeda, K., Kasahara, H., Kobayashi, M., Kubo, S., Kumazawa, R., Maekawa, R., Masuzaki, S., Miyazawa, J., Morisaki, T., Morita, S., Nagaoka, K., Nakamura, Y., Narushima, Y., Osakabe, M., Saito, K., Sakakibara, S., Sakamoto, R., Seki, T., Shimozuma, T., Shoji, M., Suzuki, Y., Takahata, K., Tamura, H., Tsumori, K., Watanabe, K.Y., Yamada, S., Yanagi, N., Yoshimura, Y., Kawahata, K., Ohyabu, N., Komori, A., and Motojima, O.

Published
2009
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41. Isotope effects on transport in LHD

Author

Tanaka, K, primary, Nagaoka, K, additional, Ida, K, additional, Yamada, H, additional, Kobayashi, T, additional, Satake, S, additional, Nakata, M, additional, Kinoshita, T, additional, Ohtani, Y, additional, Tokuzawa, T, additional, Takahashi, H, additional, Warmer, F, additional, Mukai, K, additional, Murakami, S, additional, Sakamoto, R, additional, Nakano, H, additional, Osakabe, M, additional, Morisaki, T, additional, Nunami, M, additional, Tala, T, additional, Tsujimura, T, additional, Takemura, Y, additional, Yokoyama, M, additional, Seki, R, additional, Igami, H, additional, Yoshimura, Y, additional, Kubo, S, additional, Shimozuma, T, additional, Akiyama, T, additional, Yamada, I, additional, Yasuhara, R, additional, Funaba, H, additional, Yoshinuma, M, additional, Goto, M, additional, Oishi, T, additional, Morita, S, additional, Motojima, G, additional, Shoji, M, additional, Masuzaki, S, additional, Michael, C A, additional, and Vacheslavov, L N, additional

Published
2021
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42. Overview of transport and MHD stability study: focusing on the impact of magnetic field topology in the Large Helical Device

Author

Ida, K., Nagaoka, K., Inagaki, S., Kasahara, H., EVANS5, Todd, Yoshinuma, M., Kamiya, K., Ohdachi, S., Osakabe, M., Kobayashi, M., Sudo, S., Itoh, K., Akiyama, T., Emoto, M., DINKLAGE, Andreas, Du, X., Fujii, K., Goto, M., GOTO, Takuya, HASUO, Masahiro, Hidalgo, C., Ichiguchi, K., Ishizawa, A., JAKUBOWSKI, Marcin, KAWAMURA, Gakushi, Kato, D., Morita, S., Mukai, Kiyofumi, Murakami, I., Murakami, S., Narushima, Y., Nunami, M., OHNO, Noriyasu, Pablant, N., Sakakibara, S., Seki, T., Shimozuma, T., SHOJI, M., Tanaka, K., Tokuzawa, T., Todo, Y., Wang, H., Collaborators, Ida, K., Nagaoka, K., Inagaki, S., Kasahara, H., EVANS5, Todd, Yoshinuma, M., Kamiya, K., Ohdachi, S., Osakabe, M., Kobayashi, M., Sudo, S., Itoh, K., Akiyama, T., Emoto, M., DINKLAGE, Andreas, Du, X., Fujii, K., Goto, M., GOTO, Takuya, HASUO, Masahiro, Hidalgo, C., Ichiguchi, K., Ishizawa, A., JAKUBOWSKI, Marcin, KAWAMURA, Gakushi, Kato, D., Morita, S., Mukai, Kiyofumi, Murakami, I., Murakami, S., Narushima, Y., Nunami, M., OHNO, Noriyasu, Pablant, N., Sakakibara, S., Seki, T., Shimozuma, T., SHOJI, M., Tanaka, K., Tokuzawa, T., Todo, Y., Wang, H., and Collaborators

Abstract

The progress in the understanding of the physics and the concurrent parameter extension in the large helical device since the last IAEA-FEC, in 2012 (Kaneko O et al 2013 Nucl. Fusion 53 095024), is reviewed. Plasma with high ion and electron temperatures (Ti(0) ~ Te(0) ~ 6 keV) with simultaneous ion and electron internal transport barriers is obtained by controlling recycling and heating deposition. A sign flip of the nondiffusive term of impurity/momentum transport (residual stress and convection flow) is observed, which is associated with the formation of a transport barrier. The impact of the topology of three-dimensional magnetic fields (stochastic magnetic fields and magnetic islands) on heat momentum, particle/impurity transport and magnetohydrodynamic stability is also discussed. In the steady state operation, a 48 min discharge with a line-averaged electron density of 1 × 1019 m−3 and with high electron and ion temperatures (Ti(0) ~ Te(0) ~ 2 keV), resulting in 3.36 GJ of input energy, is achieved., source:K. Ida et al 2015 Nucl. Fusion 55 104018, source:https://doi.org/10.1088/0029-5515/55/10/104018, identifier:0000-0002-0585-4561

Published
2021

45. Increasing rate of water temperature due to an Ekman layer flow in a heated pot (fluid dynamics in the kitchen)

Author

Ida, K., Yoshinuma, M., and Nagaoka, K.

Subjects
Planetary boundary layer -- Research, Hydrodynamics -- Research, Hydrofoil boats -- Hydrodynamics, Hydrofoil boats -- Research, Physics
Abstract

A sharp increase in the local temperature of heated water at the center of an aluminum pot is demonstrated a few tens of second after rotating the heated water with a spoon. The stirring leads to a sharp gradient of the temperature in the heated water, which contradicts the general belief that stirring causes a uniform temperature distribution. This sharp increase of temperature is due to the flow of an Ekman layer near the heated bottom of the pot. When this flow is prevented by a barrier at the bottom of the pot, there is no sharp increase of the water temperature. The experiments using an aluminum pot in the kitchen aid in understanding the existence and importance of flow in an Ekman layer, which is a crucial concept in hydrodynamics. [DOI: 10.1119/1.1900098]

Published
2005

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