Observation and interpretation of cometary low frequency waves

The first observations of cometary wave activity were carried out in 1985/1986 by several space missions (ICE, VEGAs 1 and 2, Suisei, Sakigake, Giotto) in the environments of comets Giacobini-Zinner and Halley. The interpretation of thesein situ field (and particle) measurements fostered investigations on (among other topics) wave generation that, leaving aside the inherently nonlinear (but related) problem of the eventual formation of a cometary bow shock wave, explored the free energy available in two specific features of the velocity distributions of the newborn particle populations: their parallel (with respect to the IMF direction) drift in the solar wind frame and perpendicular ring-like organization. Analytical and simulation works looked into the influence of the solar wind and cometary newborn parameters on the instabilities and the ensuing, or associated (as evidenced by wave observations), nonlinear phenomenology. Comprehensive reviews have described the experimental and theoretical results obtained in this cometary wave research until 1992 and identified outstanding problems warranting further attention. Here, only a cursory revisit to the Giacobini-Zinner/Halley era of low frequency wave observation and interpretation shall be made: rather, attention shall be predominantly focussed on the new implications to cometary wave research of the recent Giotto encounter with comet Grigg-Skjellerup on July 10 of 1992. The three visited comets, starting with their gas production rates, had different characteristics that showed up in thein situ observations. Yet, with the important exception of the Grigg-Skjellerup encounter, the interpretation of the wave activity measurements could be made in terms of common basic generation mechanisms adapted to the relevant properties of the appropriate plasma environment. New aspects emerged in the last Giotto cometary mission: the smaller gas production rates yield a scale length for the neutral gas density that is not (much) larger than the gyration distance of a heavy newborn ion (estimated by the product of the solar wind speed and the ion cyclotron period). As a consequence of this inhomogeneity, the velocity distribution of the heavy newborn ions exhibits gyrophase organization, i.e. nongyrotropy. This new source of free energy, albeit briefly mentioned in a few studies preceding the Grigg-Skjellerup mission, was not investigated in the context of the Giacobini-Zinner and Halley encounters. Since the last Giotto observations strongly suggest that nongyrotropy plays a prominent role in wave generation as the comet Gigg-Skjellerup nucleus is approached and its stability characteristics have only seldomly been analyzed, the review shall emphasize the wave generation capabilities of particle populations with gyrophase organization.