M. Azumi scite author profile

The new nonlinear destabilization process is found in the nonlinear phase of the double tearing mode (DTM). This process causes the abrupt growth of DTM and subsequent collapse after long-time-scale evolution in the Rutherford-type regime. The nonlinear growth of the DTM is triggered when the triangular deformation of magnetic islands with sharp current point at the X point exceeds a certain value. Hence, the mode can be called the structure-driven one. Decreasing the resistivity increases the sharpness of the triangularity and the spontaneous growth rate in the abrupt-growth phase is almost independent of the resistivity.

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Nonlinear evolution of double tearing modes

Ishii

Azumi

Kurita

et al. 2000

112

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The linear and nonlinear behaviors of the tearing mode is systematically studied for nonmonotonic q-profiles on the basis of the reduced magnetohydrodynamics (MHD) equations in cylindrical geometry, and some new features about the double tearing mode are revealed. The linear eigenmode scales as a resistive internal mode for a small distance between two rational surfaces with the same q-value, Δrs, and as the tearing one for large Δrs. New nonlinear phenomena appear in the tearing mode regime and for shorter Δrs. The linear eigenfunction shows sharply localized fluid motion at both resonant surfaces and small but global convective motion between the resonant surfaces; consequently the mode goes through a Rutherford-type regime. When the islands have grown enough, the mode shows explosive growth. This results from the nonlinear coupling among the higher harmonics, so that the inner and outer magnetic islands interact with each other leading to an internal disruption.

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Numerical analysis of 2D MHD equilibrium with non-inductive plasma current in tokamaks

Tani

Azumi

Devoto

1992

Journal of Computational Physics

126

101

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Transport simulation on L-mode and improved confinement associated with current profile modification

Fukuyama

Itoh

et al. 1995

Plasma Phys. Control. Fusion

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A unified model of the L-mode confinement i n t o k o d s and the improved modes associated with current profile modification is investigated by means of a onedimensional m s p o n simulation. The thermal transport coefficient employed is based on the theory of selfsustined turbulence due to the current-diffusivity-driven modes. In the case of low pp (& being the ratio of the plasma pressure to the pressure of the poloidal magnetic field), the simulation results show fairly good agreement with empirical L-modc scaling laws of the thermal energy confinement time rE. indicating favourable dependence on the plasma current. When Bp exceeds about unity. however, the t r m ~p ~r t in the core region is strongly reduced. This confinement improvement is attributed to the weak or negative magnetic shear due to the bootstrap current and the Shafranov shift of the magnetic surface. The enhancement factor of Q scales BT and is consistent with experimental observation. The effect of current profile modification due to the current ramp down and the lower hybrid current drive is also studied.

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M. Azumi

Effect of Toroidal Field Ripple on Fast Ion Behavior in a Tokamak

Structure-Driven Nonlinear Instability of Double Tearing Modes and the Abrupt Growth after Long-Time-Scale Evolution

Nonlinear evolution of double tearing modes

Numerical analysis of 2D MHD equilibrium with non-inductive plasma current in tokamaks

Transport simulation on L-mode and improved confinement associated with current profile modification

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