Research, 1990 (hereinafter referred to as Ma and Schunk, submitted manuscript, 1990)]. These studies have indicated that the plasma cloud evolution is complicated and depends on the cloud density and species, the injection angle relative to the geomagnetic field, the injection velocity, the altitude of injection, time-dependent ionization processes, degree of collisionality, chemistry, and the ambient ionospheric and thermospheric conditions. Also, the cloud evolution has been both observed and predicted to progress through various stages, with the characteristic times ranging from microseconds to tens of minutes.
Although significant progress has been made in under-standing the evolution of plasma clouds, there are still a number of unresolved problems. However, the upcoming chemical releases during the CRRES (Combined Release and Radiation Effects Satellite) mission and complementary rocket-borne investigations have been designed to address some of the important issues concerning cloud evolution. The CRRES releases will involve both small (5 kg) and large (20 kg) injections of Ba, Li, SFa, and Ba-Li mixtures. Single and multiple releases at both high and low altitudes will 1337 1338 SCHUNK AND SZUSZCZEWICZ: IONIZED CLOUD EXPANSION occur and there will be a range of injection angles relative to the geomagnetic field. Consequently, the CRRES releases will provide information that is relevant to a wide range of issues, including (1) critical velocity ionization mechanisms; (2) electron heating and high-frequency wave excitation; (3) wave-particle interactions resulting from the injection of the different species; (4) plasma cloud slippage across the magnetic field (B); (5) cloud braking mechanisms both parallel and perpendicular to B; (6) the formation of unstable ring-shaped ion velocity distributions; (7) plasma expansion phenomena and associated ion acceleration; (8) plasma striations and irregularity formation mechanisms; and (9) simulations of polar wind and interhemispheric flows. Our immediate interest is in the early-time phenomena and in particular in the plasma expansion characteristics of the ionized cloud along the geomagnetic field and how these characteristics apply to naturally occurring expansion phenomena in various geospace domains. The possible importance of plasma expansion processes in solar-terrestrial physics was first noted by Guterich et al. [1966, 1968, 1973]. Since these pioneering studies, plasma expansion phenomena have been studied in connection with laser fusion research, satellite wakes, planetary wakes, the polar wind, plasmaspheric refilling, solar wind outflow from coronal holes, the acceleration of plasma in the magnetotail, and the expansion of artificial plasma clouds [cf. Denavit, 1979; True et al., 1981; Crow et al., 1975; Bezzerides et al., 1978; $ingh and $chunk, 1983; $amir et al., 1983; Tariq et al., 1985; Eastman et al., 1986; $chunk and $zuszczewicz, 1988; and references therein]. In addition to the natural consequences of plasma expansions, our modeling effort is mot...