On deterministic nature of the intermittent geodesic acoustic mode observed in L-mode discharge near tokamak edge, Part II Zonal flow-GAM driven by electron drift wave turbulence

This paper is part II of a possible series of papers that derive/investigate the salient features of the Zonal Flow-Geodesic Acoustic Mode (ZF-GAM) phenomenon observed, routinely, in the edge regions of L Mode discharges in tokamaks. Utilizing the techniques and methodologies developed in Part I, we work here with a different source of turbulence -- the electron drift wave (EDW) in the well-known $\delta_e$ model -- than Part I where the turbulence originated in the ITG; the two sources of turbulence, propagating, respectively, in the electron (ion) diamagnetic directions, are highly distinguished in their basic characteristics. Though the ITG generated ZF-GAM system is widely studied, this is, perhaps, the first attempt at exploring the system when driven by modes rotating in the electron direction. Several structural features of ZF-GAM appear to be quite robust, and are preserved through this drastic change in the underlying source of turbulence. Although this very idealized \delta_e model calculation, may not be fully representative of other electron drift waves, our initial investigations, however, do expose important differences with the ITG approach; the most striking is that the turbulence levels required for GAM excitation can be an order of magnitude higher than for ITG turbulence. Investigations involving other varieties of drift waves could finally settle the generality of this interesting result.