Water ice abundance and CO2 band strength on the saturnian satellite Phoebe from Cassini/VIMS observations

► Using Cassini–VIMS spectra, we map the water ice spatial abundance on Phoebe. ► The measured abundances are 0.1–4% with grain radii between 1 and 10μm. ► We used dirty ice models to better fit Phoebe spectra. ► These models increase the measured spatial abundances by 1.6–12 times. ► We measured an...

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Bibliographic Details
Published inIcarus (New York, N.Y. 1962) Vol. 220; no. 2; pp. 331 - 338
Main Authors Hansen, Gary B., Hollenbeck, Emily C., Stephan, Katrin, Apple, Sean K., Shin-White, Eun-Ju Z.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier Inc 01.08.2012
Elsevier
Subjects
Astronomy
Earth, ocean, space
Exact sciences and technology
Ices, IR spectroscopy
Satellites, Composition
Satellites, Surfaces
Saturn, Satellites
Solar system
Spectroscopy
Satellites, Composition
Spectroscopy
Ices, IR spectroscopy
Saturn, Satellites
Satellites, Surfaces
Phoebe
Cassini Huygens space probe
Infrared spectroscopy
Roughness
Abundance
Ice
Orbits
Saturn planet
Albedo
Near infrared spectrum
Saturn satellite
Models
Solar system
Corrections
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Summary:► Using Cassini–VIMS spectra, we map the water ice spatial abundance on Phoebe. ► The measured abundances are 0.1–4% with grain radii between 1 and 10μm. ► We used dirty ice models to better fit Phoebe spectra. ► These models increase the measured spatial abundances by 1.6–12 times. ► We measured and mapped the strength of the CO2 band on Phoebe. We have studied the near-infrared spectrum of the Saturn satellite Phoebe, a distant satellite observed before Cassini’s Saturn orbit insertion, using data from the Visual and Infrared Mapping Spectrometer (VIMS) on the Cassini orbiter. We have done a critical calibration of the dataset that involves careful correction of dark artifacts. We model areally mixed water ice and non-ice (assumed segregated because of the low ∼3% albedo of the non-ice material) for several high and medium resolution observations of Phoebe made near closest approach. Using a Hapke roughness factor of 15°, we find ice abundances from ∼0.1% to over 4%. The ice grain radii vary from 1 to 10μm. These are displayed on a projected map of Phoebe with about 50% coverage (about 33% coverage at better than 5km spatial resolution). Detailed looks at the water ice spectral fits shows that the weak 1.05 and 1.25-μm bands are missing in most of the spectra, implying that the ice endmember is not pure ice, but has a dark material mixed with it that lowers the albedo and suppresses these bands. We made a model of ice contaminated with Phoebe-like dark material showing that a few percent of dark material lowers the albedo to ∼50% and suppresses the bands. The dirty ice model produces better fits to the spectra and implies that the amount of dirty ice is about 1.5 times the amount of pure ice. We have also calculated the CO2 band depth for these same observations and projected the results. The CO2 band depth varies inversely with water ice abundance.
ISSN:0019-1035
1090-2643
DOI:10.1016/j.icarus.2012.05.004