Title :
Coherent structures and their stability in ion temperature gradient turbulence
Author :
Dastgeer, Sheikh
Author_Institution :
Transp. Theor. Group, Chalmers Univ. of Technol., Goteborg, Sweden
fDate :
4/1/2003 12:00:00 AM
Abstract :
Periodic arrays of large scale coherent vortices and their stability have been investigated, within the framework of ηi turbulence, using two-dimensional fluid simulation in slab geometry. These vortices, in combination with viscosity damping of small scales, contribute to the formation of a steady state in a system with linearly unstable modes. The steady state comprises of a few vortex convective turn over times and seems to be fairly robust. It has been recognized that a vortex chain, consisting of positive and negative vorticities, continues to move stably in the poloidal direction (along periodic direction). On the other hand, an initial isolated monopole vortex is unstable and leads to a long-lived stable dipolar structure after a few vortex turnover periods. A variety of simple collisional interaction processes among these coherent vortices have also been explored numerically.
Keywords :
plasma flow; plasma instability; plasma simulation; plasma temperature; plasma turbulence; vortices; coherent structures; coherent vortices; collisonal interaction processes; initial isolated monopole vortex; ion temperature gradient turbulence; large scale coherent vortices; linearly unstable modes; negative vorticities; periodic arrays; periodic direction; poloidal direction; positive vorticities; slab geometry; stability; steady state formation; two-dimensional fluid simulation; unstable vortex; viscosity damping; vortex chain; vortex convective turn over times; vortex turnover periods; Damping; Geometry; Large-scale systems; Slabs; Solid modeling; Stability; Steady-state; Temperature; Time of arrival estimation; Viscosity;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2003.810722
