A killer pellet is an impurity pellet that is injected into a tokamak plasma in order to terminate a discharge without causing serious damage to the tokamak machine. In JT-60U neon ice pellets have been injected into OH and NB heated plasmas and fast plasma shutdowns have been demonstrated without large vertical displacement. The heat pulse on the divertor plate has been greatly reduced by killer pellet injection (KPI), but a low-power heat flux tail with a long time duration is observed. The total energy on the divertor plate increases with longer heat flux tail, so it has been reduced by shortening the tail. Runaway electron (RE) generation has been observed just after KPI and/or in the later phase of the plasma current quench. However, RE generation has been avoided when large magnetic perturbations are excited. These experimental results clearly show that KPI is a credible fast shutdown method avoiding large vertical displacement, reducing heat flux on the divertor plate, and avoiding (or minimizing) RE generation.
Internal modes with m = 1 and m ≥ 2, which localize around a pitch minimum, have been studied for ultra-low-q plasmas with 1/2 ≤ qa < 1 in REPUTE-1, where m is the poloidal mode number and qa is the safety factor at the plasma surface. One-dimensional stability analysis has shown that, for finite beta, m ≥ 2 modes have a relatively large growth rate compared with those of the m = 1 modes. The internal structure of the magnetic fluctuations with m = 1 and m ≥ 2 is found to be consistent with the numerically calculated eigenfunctions.
The nonlinear dynamics and structure of plasmas with
tightly twisted magnetic
field lines have been studied using a toroidal plasma device. Stepwise
magnetohydrodynamic (MHD) relaxation occurs, resulting in a discontinuous
change in the pitch of magnetic field lines. This discrete
nature of the pitch
stems from the instability of kink (torsional) modes. The MHD relaxation
stabilizes kink modes by selecting (self-organizing) appropriate
pitches. The self-organized state displays the characteristic of a
‘dissipative structure’ in
that it is accompanied by enhanced energy dissipation; the global
resistance of
the plasma current is substantially enhanced. The magnetic energy, which is
generated by the internal plasma current, first changes into
fluctuation energy
through the kink instability, and then it goes mainly to ion thermal energy
through viscous dissipation of the fluctuating flow. The
viscosity dissipates the
fluctuation energy with conservation of helicity. The self-organization
of the stabilized magnetic field is characterized by the
preferential conservation of the helicity.
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