Simulation Study of Ballooning Modes in the Large Helical Device
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概要
- 論文の詳細を見る
The magnetohydrodynamic (MHD) simulation code MHD Infrastructure for Plasma Simulation (MIPS) was benchmarked on ballooning instability in the Large Helical Device (LHD) plasma. The results were compared to the results of linear analysis by using the CAS3D code. Both the linear growth rates and the spatial profiles were found to be in good agreement. An extended MHD model with finite ion Larmor radius effects was implemented into the MIPS code. Ballooning instabilities were investigated using the extended MHD model, and the results were compared with those using the MHD model. Ion diamagnetic drift was found to reduce the growth rate of the short-wavelength modes; hence, modes with a diamagnetic drift frequency comparable to the ideal MHD growth rate are the most unstable. The most unstable toroidal mode number of ballooning instability in the LHD is reduced to |n| ≤ 5 for hydrogen plasma with ion number density ni ≤ 1019 m−3.
著者
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Miura Hideaki
National Institute For Fusion Science
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SATO MASAHIKO
National Research Institute of Brewing
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Nakajima Noriyoshi
National Institute For Fusion Science
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MIURA Hideaki
National Institute for Fusion Science, 322-6 Oroshi-cho, Toki 509-5292, Japan
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TODO Yasushi
National Institute for Fusion Science
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TODO Yasushi
National Institute for Fusion Science, 322-6 Oroshi-cho, Toki 509-5292, Japan
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NAKAJIMA Noriyoshi
National Institute for Fusion Science, 322-6 Oroshi-cho, Toki 509-5292, Japan
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SATO Masahiko
National Institute for Fusion Science, Toki 509-5292, Japan
関連論文
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- Intrinsic Rotation of a Magnetic Island with Finite Width
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- Possibility of LHD Equilibrium with Zero Rotational Transform Surface
- Simulation Study of Ballooning Modes in the Large Helical Device
- Spectrum Properties of Hall MHD Turbulence
- Electron Heat Transport in a Self-Similar Structure with Magnetic Islands
- Ballooning Modes Instabilities in Outward LHD Configurations
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- Derivation of the Selected Path Integral
- Rotations of Bulk Ions and Impurities in Non-Axisymmetric Toroidal Systems
- Beam-Driven Currents in the 1/v Regime in a Helical System
- はじめに
- Physical Mechanism of Eψ-driven Current in Asymmetric Toroidal System
- Effects of the Stochasticity on Transport Properties in High-β LHD
- Neoclassical Flow, Current, and Rotation in General Toroidal Systems
- Plasmoid Motion in Helical Plasmas
- Influences of Short-Wave Truncations to Spectral Energy Budget in Hall MHD Turbulence
- Orthonormal Divergence-Free Wavelet Analysis of Energy Transfer in Hall MHD Turbulence
- High-Beta Axisymmetric Equilibria with Flow in Reduced Single-Fluid and Two-Fluid Models
- Benchmark Tests of Fusion Plasma Simulation Codes for Studying Microturbulence and Energetic-Particle Dynamics
- On the Neoclassical Relationship between the Radial Electric Field and Radial Current in Tokamak Plasmas
- Nonlinear Hybrid Simulations of Energetic Particle Modes in Realistic Tokamak Flux Surface Geometry
- Transport Study of LHD High-Beta Plasmas Based on Power Balance Analysis with TASK3D Code Module
- Development of Integrated Transport Code, TASK3D, and Its Applications to LHD Experiment
- Gyrokinetic Simulations of Slab Ion Temperature Gradient Turbulence with Kinetic Electrons
- A Numerical Method for Parallel Particle Motions in Gyrokinetic Vlasov Simulations
- Time Evolution of the Rotational Transform Profile in Current-Carrying LHD Plasmas
- Erratum: "High-Beta Axisymmetric Equilibria with Flow in Reduced Single-Fluid and Two-Fluid Models" [Plasma Fusion Res. 3, 034 (2008)]
- Simulation Study of Energetic Ion Transport due to Alfvén Eigenmodes in LHD Plasma
- Construction of a Gyrokinetic Plasma Simulation Model for Electromagnetic Phenomena
- Analytic Equilibria of High-Beta Tokamaks with Toroidal and Poloidal Flows and Pressure Anisotropy Associated with Parallel Heat Flux
- Non-Local Simulation of the Formation of Neoclassical Ambipolar Electric Field in Non-Axisymmetric Configurations