Alfven Cyclotron Instability and Ion Cyclotron Emission

Two-dimensional solutions of compressional Alfven eigenmodes (CAE) are studied in the cold plasma approximation. For finite inverse aspect ratio tokamak plasmas the two-dimensional eigenmode envelope is localized at the low magnetic field side with the radial and poloidal localization on the order of u / f i and u/*, respectively, where rn is the dominant poloidal mode number. Charged fusion product driven Alfvkn Cyclotron Instability (ACI) of the compressional Alfvkn eigenmodes provides the explanation for the ion cyclotron emission (ICE) spectrum observed in tokamak experiments. The ACI is excited by fast charged fusion products via Doppler shifted cyclotron wave-particle resonances. The ion cyclotron and electron Landau dampings and fast particle instability drive are calculated perturbatively for deuterium-deuterium (DD) and deuterium-tritium (DT) plasmas. Near the plasma edge at the low field side the velocity distribution function of charged fusion products is localized in both pitch angle and velocity. The poloidal localization of the eigenmode enhances the ACI growth rates by a factor of fi in comparison with the previous results [N. N. Gorelenkov and C. Z. Cheng, to appear in Phys. Plasmas, June (1995)l without poloidal envelope. The thermal ion cyclotron damping determines that only modes with eigenfrequencies at multiples of the edge cyclotron frequency of the background ions can be easily excited and form an ICE spectrum similar to the experimental observations. Theoretical understanding is given for the results of TFTR DD and DT experiments with V,O/VA < 1 and JET experiments with u,o/u~ > 1. PACS numbers: 52.35.Qz, 52.55.Fa *Permanent address: Troitsk Institute for Innovative and Fusion Research, Troitsk, Moscow region, Russia, 142092 1 DlSTRlBUTION OF THIS DOCUMENT IS UNLIMmo