Physics – Plasma Physics
Scientific paper
Jun 1994
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1994jgr....9911495s&link_type=abstract
Journal of Geophysical Research, Volume 99, Issue A6, p. 11495-11506
Physics
Plasma Physics
9
Ionosphere: Ionosphere/Magnetosphere Interactions, Magnetospheric Physics: Plasmasphere, Space Plasma Physics: Kinetic And Mhd Theory, Space Plasma Physics: Transport Processes
Scientific paper
Hydrodynamic and semikinetic treatments of plasma flow along closed geomagnetic field lines are compared. The hydrodynamic treatment is based on a simplified 16-moment set of transport equations as the equations for the heat flows are not solved; the heat flows are treated heuristically. The semikinetic treatment is based on a particle code. The comparison deals with the distributions of the plasma density, flow velocity, and parallel and perpendicular temperatures as obtained from the two treatments during the various stages of the flow subject to certain assumed boundary conditions. In the kinetic treatment, the appropriate boundary condition is the prescription of the velocity distribution functions for the particles entering the flux tubes at the ionospheric boundaries; those particles leaving the system are determined by the processes occurring in the flux tube. The prescribed distributions are half-Maxwellian with temperature T0 and density n0. In the hydrodynamic model, the prescribed boundary conditions are placed on density (n0), flow velocity (V0), and temperature (T0). We found that results from the hydrodynamic treatment critically depend on V0; for early stages of the flow this treatment yields results in good agreement with those from the kinetic treatment, when V0=(kT0/2πm)1/2, which is the average velocity of particles moving in a given direction for a Maxwellian distribution. During this early stage, the flows developing from the conjugate ionospheres show some distinct transitions.
For the first hour or so, the flows are highly supersonic and penetrate deep into the opposite hemispheres, and both hydrodynamics and kinetic treatments yield almost similar features. It is found that during this period heat flow effects are negligibly small. When a flow penetrates deep into the opposite hemisphere, the kinetic treatment predicts reflection and setting up of counterstreaming. In contrast, the hydrodynamic treatment yields a shock in the flow. The reasons for this difference in the two treatments is discussed, showing that in view of the relatively warm ions, the coupling of ion beams and the consequent shock formation in the off-equatorial region are not likely due to the enhancements in the beam temperatures. The counterstreaming in the kinetic treatment and the shock in the hydrodynamic treatment first advance upward to the equator and then downward to the ionospheric boundary from where the flow originated. The transit time for this advancement is found to be about 1 hour for the perspective models. After 2 hours or so, both models predict that the flows from the ionospheric boundaries are generally subsonic with respect to the local ion-sound speed. At late stages of the flow, when a substantial fraction of ions entering the flux tube begin to return back in the kinetic treatment, the hydrodynamic treatment with the boundary condition V0=(kT0/2πm)1/2 yields an overrefilling, and the choice of V0 becomes uncertain.
Horwitz James L.
Singh Nagendra
Wilson Gordon Ray
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