The onset of electromagnetic oscillations that are observed in magnetically confined plasmas where beams of fast neutrals are injected is associated with the excitation of a mode with poloidal wave number m° ** 1 and phase velocity equal to the core-ion diamagnetic velocity. The resonant interaction of the mode with the beam ions is viewed as a form of dissipation that allows the release of the mode excitation energy, related to the gradient of the plasma pressure.PACS numbers: 52.35.-g, 52.55.-s A new type of instability has been observed in magnetically confined toroidal plasmas where beams of fast neutrals are injected nearly perpendicular to the equilibrium magnetic field. The poloidal magnetic field fluctuations produced by this instability have a characteristic signature and are called "fishbone oscillations." 1,2 Particle bursts corresponding to loss of energetic beam particles are correlated with fishbone events, reducing the beam heating efficiency and thus limiting the maximum achievable ft [ = (kinetic pressure)/(magnetic pressure)] by this technique.We present the results of an analysis that supports one of the interpretations 3 advanced when these experimental observations were first reported. This consisted of proposing the following: (a) The excited mode, whose spatial structure is dominated by the component with poloidal wave number m 0ass l, has a frequency related to the ion diamagnetic frequency and is one of the two m° = l modes that are found under the conditions for ideal MHD instability, but are rendered marginally stable by finite ion Larmor radius effects 4 ; (b) the mode "excergy" (excitation energy) is related to the plasma pressure gradient; and (c) the presence of a "viscous" dissipative process (e.g., produced by a mode-particle resonance that scatters the beam ions) is required for the instability to develop.We refer, for simplicity, to a large-aspect-ratio axisymmetric toroidal confinement configuration with circular magnetic surfaces, and consider perturbations of the equilibrium field that are dominated by the ra 0as=: l, n 0sss \ poloidal and toroidal components. The relevant model dispersion relation is 4when we omit mode-particle resonances and other dissipative processes. Here, tOdi" -(c/eBrn)dp i± /dr is the ion diamagnetic frequency evaluated at the surface r -TQ where the pitch angle of the unperturbed equilibrium magnetic field equals that of the perturbation, and p ix is the transverse ion pressure. The ideal MHD growth rate 7MHD is given by 4 YMHD^COAXH,where co A = v A9 s/r 0 with v A e ,BS B e I(4Km i ni) U2 , s^dlnq/dlnr, q^rB^/RBe, R is the major radius of the torus, X//-Xo(r 0 //?) 2 (/3p -~/?p,crit), ^o is a finite numerical factor, p p = -(R/ ro) 2 f°drr 2 (dp/dr), and, for a parabolic q profile, 5 Pp.crit 1 ** ^13/12-The ideal stability parameter XH is the negative of the (normalized) minimum value of the perturbed potential energy 4 8W m \ n and the dispersion relation (1) is valid for X H > §.In the realistic limit where 7MHD <^d H the dispersion relation (1)...
