Magnetotail Assimilation Model S. Wing and P. T. Newell The Johns Hopkins University Applied Physics Lab. Simon.wing@jhuapl.edu/Fax:240-228-6670 2D/3D global distributions of the plasma sheet pressure, temperature, and density are crucial to understand many physical processes and dynamics in the magnetotail. Providing these global quantities is a goal of several future NASA multi-spacecraft missions. However, assimilating the unprecedentedly large multi-point data sets in a coherent and unified manner poses a challenge. A technique that can serve as a foundation for assimilating low-, mid-, and high-altitude observations from these multispacecraft missions to create 2D/3D images of the plasma sheet ion pressure, temperature, and density is presented. This method relies on the plasma sheet isotropy, which has a strong theoretical foundation and overwhelming observational support. Previously developed algorithms are used to detect the plasma isotropy boundary and to detect and exclude acceleration events. Global equatorial plasma sheet pressure, density, and temperature inferred from DMSP particle observations are presented. A statistical and a case study show a favorable comparison with in situ measurements. The power this method for magnetotail investigations is illustrated in two examples: (1) the dynamics of the 2D equatorial plasma sheet under northward and southward IMF orientations and (2) the quiet time plasma sheet ion pressure contribution to the field-aligned currents. During periods of northward IMF, cold dense ions can be found plentifully along the dawn and dusk flanks of the plasma sheet, suggesting massive LLBL ion entry into the magnetosphere along the flanks. However, during periods of southward IMF, the presence of the cold dense ions is noticeably diminished, especially along the dusk flank where the density peak is barely discernible. The nightside region-1 Birkeland currents exhibit a dawn-dusk asymmetry that can be explained by the dawn-dusk asymmetry in the plasma pressure arising from the E x B and curvature/gradient drifts of ions originating from the deep tail and LLBL. In the region tailward/poleward of region-1 currents, the pressure gradient generates additional currents, that have been called region-0 and that flow in the opposite sense as region-1.