Stability of the Global Alfven Eigenmode in the presence of fusion alpha particles in an ignited tokamak plasma
Abstract
The stability of the Global Alfven Eigenmodes is investigated in the presence of super-Alfvenic energetic particles, such as the fusion-product alpha particles in an ignited deuterium-tritium tokamak plasma. Alpha particles tend to destabilize these modes when omega (sub * alpha) greather than (omega)(sub A), where omega (sub A) is the shear-Alfven modal frequency and omega (sub * alpha) is the alpha particle diamagnetic drift frequency. This destabilization due to alpha particles is found to be greatly enhanced when the alpha particles are modeled with a slowing-down distribution function rather than with a Maxwellian. However, previously neglected electron damping due to the magnetic curvature drift is found to be comparable in magnitude to the destabilizing alpha particle term. Furthermore, the effects of toroidicity are also found to be stabilizing, since the intrinsic toroidicity induces poloidal mode coupling, which enhances the parallel electron damping from the sideband shear Alfven Landau resonance. In particular, for the parameters of the proposed Compact Ignition Tokamak, the Global Alfven Eigenmodes are found to be completely stabilized by either the electron damping that enters through the magnetic curvature drift or the damping introduced by finite toroidicity.
- Publication:
-
Unknown
- Pub Date:
- May 1989
- Bibcode:
- 1989sgae.rept.....F
- Keywords:
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- Alpha Particles;
- Magnetohydrodynamic Stability;
- Magnetohydrodynamic Waves;
- Nuclear Fusion;
- Plasma Equilibrium;
- Tokamak Devices;
- Deuterium;
- Landau Damping;
- Plasmas (Physics);
- Tritium;
- Wave Functions;
- Plasma Physics