Overwhelming O+ contribution to the plasma sheet energy density during the October 2003 superstorm: Geotail/EPIC and IMAGE/LENA observations M. Nose, S. Taguchi, K. Hosokawa, S.P. Christon, R.W. McEntire, T.E. Moore, and M.R. Collier We studied dynamics of O+ ions during the superstorm that occurred on 29Ð31 October 2003, using energetic (9Ð210 keV/e) ion flux data obtained by the energetic particle and ion composition (EPIC) instrument on board the Geotail satellite and neutral atom data in the energy range of 10 eV to a few keV acquired by the low-energy neutral atom (LENA) imager on board the Imager for Magnetopause-to-Aurora Global Exploration (IMAGE) satellite. Since the low-energy neutral atoms are created from the outflowing ionospheric ions by the charge exchange process, we could examine variations of ionospheric ion outflow with the IMAGE/LENA data. In the near-Earth plasma sheet of XGSM ~-6 RE to -8.5 RE, we found that the H+ energy density showed no distinctive differences between the superstorm and quiet intervals (1Ð10 keV cm 3), while the O+ energy density increased from 0.05Ð3 keV cm 3 during the quiet intervals to 100 keV cm 3 during the superstorm. The O+/H+ energy density ratio reached 10Ð20 near the storm maximum, which is the largest ratio in the near-Earth plasma sheet ever observed by Geotail, indicating more than 90% of O+ in the total energy density. We argued that such extreme increase of the O+/H+ energy density ratio during the October 2003 superstorm was due to mass-dependent acceleration of ions by storm-time substorms as well as an additional supply of O+ ions from the ionosphere to the plasma sheet. We compared the ion composition between the ring current and the near-Earth plasma sheet reported by previous studies and found that they are rather similar. On the basis of the similarity, we estimated that the ring current had the O+/H+ energy density ratio as large as 10Ð20 for the October 2003 superstorm. _______________ Journal of Geophysical Research, 110, A09S24, doi:10.1029/2004JA010930.