A new low-latitude ionospheric model has been developed at the Naval Research Laboratory: Sami2 is Another Model of the Ionosphere (SAMI2). SAMI2 treats the dynamic plasma and chemical evolution of seven ion species (H +, He +, N +, O +, N• +, NO +, and O• +) in the altitude range • 100 km to several thousand kilometers. The ion continuity and momentum equations are solved for all seven species; the temperature equation is solved for H +, He +, O +, and the electrons. SAMI2 models the plasma along the Earth's dipole field from hemisphere to hemisphere, includes the E x B drift of a flux tube (both in altitude and in longitude), and includes ion inertia in the ion momentum equation for motion along the dipole field line. The final point is relevant for plasma dynamics at very high altitudes where ion inertia can be important. For example, we have found that ion sound waves, which are supported by ion inertia, may be generated in the topside ionosphere (> 1000 kin) at sunrise and sunset [Huba et al., 2000b]. The neutral species are specified using the Mass Spectrometer Incoherent Scatter model (MSIS86) and the Horizontal Wind Model (HWM93). In this paper we describe in detail the SAMI2 model and present representative results from the model. 1. Introduction Over the past two decades a number of computational models of the ionosphere have been developed. An excellent overview of the most widely used models is given in STEP: Handbook of Ionospheric Models [Schunk, 1996] and by Anderson et al. [1998]. In general, ionospheric models treat the global ionosphere in three parts: low latitude, midlatitude, and high latitude. Low-latitude models (e.g., the Phillips Laboratory global theoretical ionosphere model (GTIM) [Anderson, 1971; Anderson et al., 1996], the University of Alabama field line interhemispheric plasma model (FLIP) [Richards and Tort, 1996], and the Sheffield University plasmasphere-ionosphere model (SUPIM) [Bailey and Balan, 1996]) consider the plasma dynamics along an entire field line from hemisphere to hemisphere. Mid-latitude models (e.g., GTIM [Decker et al., 1994] and the Utah State University time-dependent ionosphere model (TDIM) [Schunk, 1988; Schunk and Sojka, 1996]) typically have the upper boundary •< 1000 kin; additional boundary conditions at the upper boundary (e.g., particle flux, heat flux) must be imposed that are generally not consistent with interhemispheric transport. Finally, high-latitude models (e.g., TDIM, GTIM) also have an upper boundary typically set at 1000 km. However, an important aspect of high latitude models is that magnetospheric effects need to be included: for example, the magnetospheric electric field and auroral precipitation effects. A common feature of these models is that they use empirical neutral atmosphere models such as the Mass Spectrometer Incoherent Scatter model (MSIS) [Hedin, 1987] and the Horizontal Wind Model (HWM) [Hedin et al., 1991] or observed data to specify neutral atmosphere densities and winds. There are also two global ionospheric models that sol...
