Models of Radar Absorption in Europan Ice

John C. Moore

Arctic Centre, University of Lapland, Box 122, Rovaniemi 96101, Finland

Abstract

The detection of a sub-surface present-day ocean on Europa is of considerable interest. One possible method of detecting an ocean is by an orbiting radar sounder. The effects of a range of possible European ice chemistries on radar attenuation are investigated, using plausible Europa ice temperature profiles. Ice chemistries are derived from geochemical models of Europa predicting a sulfate dominated ocean, a chloride dominated ocean scaled from the Earth, experimental data on marine ice formed beneath ice shelves on Earth, and on low salinity sea ice, and models of rock and ice mixtures. Chloride ions are expected to dominate the radar absorption because they are incorporated into the ice lattice, though if freezing rates are rapid or similar to sea ice, then brine pockets will dominate losses. In the case of an ocean being present underneath the ice, the range of attenuation found in the models is between about 5 dB/km for rock/ice mixtures up to 80 dB/km for sea ice models. However perhaps the best model at present is for ice formed from a plausible sulfate dominated ocean with the fraction of chloride incorporated into the ice set to the same as the low accretion rate Ronne Ice Shelf marine ice samples. This has a radar absorption of 9-16 dB/km for surface temperatures of 50-100K. In the case of a convecting isothermal ice layer beneath a conducting ice crust, absorption in the conducting crust is lower for all the models than over an ocean as the convecting ice is modeled to be 250-260K. Absorption in the isothermal layers is very high, but the interface between conducting and convecting ice may be marked by a reflection coefficient that enables it to be imaged. It is concluded that realistic ice penetrating radars and likely to be able to penetrate some kilometres into the ice, though problems of interpretation caused by scattering are not considered here.