SA24A-09:
Solar cycle dependence of ion cyclotron wave frequencies
Tuesday, 16 December 2014: 5:48 PM
Marc Lessard1, Erik Anders Lindgren1, Carol Weaver1 and Mark J. Engebretson2, (1)University of New Hampshire (UNH), Institute for the Study of Earth, Oceans and Space (EOS), Durham, NH, United States, (2)Augsburg College, Minneapolis, MN, United States
Abstract:
Electromagnetic ion cyclotron (EMIC) waves have been studied for decades, though remain a fundamentally important topic in heliospheric physics. The connection of EMIC waves to the scattering of energetic particles from Earth’s radiation belts is one of many topics that motivate the need for a deeper understanding of characteristics and occurrence distributions of the waves. In this study, we show that EMIC wave frequencies, as observed at Halley Station in Antarctica from 2009 through 2012, increase by approximately 50% over that interval. Assuming that these waves are excited in the vicinity of the plasmapause, the change in Kp in going from solar minimum to near solar maximum would drive increased plasmapause erosion, potentially shifting the generation region of the EMIC to lower L and resulting in the higher frequencies. A numerical estimate of the change in plasmapause location, however, implies that it is not enough to account for the shift in EMIC frequencies that are observed at Halley Station. Another possible explanation for the frequency shift, however, is that the relative density of heavier ions in the magnetosphere (that would be associated with increased solar activity) could account for the change in frequencies.