[en] The composition, energy and angular characteristics of upward flowing ionospheric ions at altitudes greater than 20000 km have been studied by means of the PROGNOZ-7 ion composition experiment. Very narrow beams, having widths corresponding to a mirroring altitude of the order a few thousand kilometers or less, may be found up to altitudes exceeding 30000 km on the nightside. At much higher altitudes and in regions connected to the dayside/flank boundary layer and plasma mantle, the beams are much broader than expected from adiabatic particle motions from an ionospheric source/acceleration region, suggesting that pitch angle scattering or transverse acceleration processes are present there. Considerable mass dispersion effects have also been observed in some upward flowing ionspheric ion beams. The peak energy for the o⁺ ions may differ by several keV compared to that for the H⁺ ions in one and the same ion beam at altitudes above 20000 km. The o⁺ ions in these beams have gained considerably more energy than H⁺ in the acceleration process. Many examples with a much higher o⁺ than H⁺ content in the beam have been observed. Possible mechanisms giving rise to the observed effects are discussed, one being several kilovolts of potential drop below the neutral H,O-crossover altitude (500-1500 km). At altitudes where the upflowing ionospheric ions are intermixed with magnetosheath ions, mass dispersion effects are also observed. This dispersion often appears to be the result of a velocity filtering effect caused by dawn-dusk electric (earthward convection). (author)