Auroral ion acceleration in dispersive Alfven waves

[1] Observations from the FAST satellite are used to create a model for dispersive Alfven waves above the auroral oval. Using this model, it is shown how these waves may accelerate ionospheric ions transverse to the geomagnetic field and cause ion outflow. The model waves grow from ionospheric conductivity variations due to auroral electron precipitation and resonate in the cavity between the ionosphere and the peak in the Alfven speed that occurs at altitudes of similar to1 Earth radius (Re). By tracing ions in the model wave field, it is demonstrated that for transverse wave amplitudes (E-perpendicular to) satisfying E-perpendicular to/B-o < Omega(i)/k(perpendicular to) (where B-o is the geomagnetic field strength, k(perpendicular to) is the perpendicular wave number, and Omega(i) is the ion gyrofrequency) the ion motion in the wave field is coherent and the ions may become trapped in the transverse wave potential. In Alfven waves having two-dimensional structure transverse to Bo, these ions may be accelerated up to a transverse energy that provides an ion gyrodiameter roughly equivalent to the perpendicular scale or wavelength (lambda(perpendicular to)) of the wave. Alternatively, when E-perpendicular to/B-o > Omega(i)/ k(perpendicular to) the ion motion may become stochastic allowing acceleration to energies exceeding that prescribed by lambda(perpendicular to). The transversely accelerated ions in both the coherent and stochastic cases flow upward from the ionosphere under the influence of the mirror force to altitudes of 1 Earth radii over timescales as small as a few seconds to minutes with energies in the keV range. Ions accelerated by these means may account for the intense outflowing ion fluxes observed in Alfven waves above the auroral oval.