TY - JOUR
T1 - Saturn's F ring grains
T2 - Aggregates made of crystalline water ice
AU - Vahidinia, Sanaz
AU - Cuzzi, Jeffrey N.
AU - Hedman, Matt
AU - Draine, Bruce
AU - Clark, Roger N.
AU - Roush, Ted
AU - Filacchione, Gianrico
AU - Nicholson, Philip D.
AU - Brown, Robert H.
AU - Buratti, Bonnie
AU - Sotin, Christophe
N1 - Funding Information:
We are very grateful to Kathy Rages for providing her Mie scattering code and for assistance fixing problems it developed with the unusual set of refractive indices we were using. We have profited greatly from generous allocations of cpu time on the NASA High-End Computing (HEC) machines at Ames. In addition to raw cycles, expert consultants have provided invaluable help in parallelization and optimization. We’d like to thank Terry Nelson, Piyush Mehrotra, and especially Art Lazanoff for help getting the optimizing done, Denis Richard for his help testing the code, Rachel Mastrapa for providing data in advance of publication and several helpful conversations, observation designers on the VIMS team, Essam Marouf and Frank Bridges for insightful conversations. The research was partially supported by the Cassini project and partially by a grant to JNC from NASA’s Planetary Geology and Geophysics program.
PY - 2011/10
Y1 - 2011/10
N2 - We present models of the near-infrared (1-5μm) spectra of Saturn's F ring obtained by Cassini's Visual and Infrared Mapping Spectrometer (VIMS) at ultra-high phase angles (177.4-178.5°). Modeling this spectrum constrains the size distribution, composition, and structure of F ring particles in the 0.1-100μm size range. These spectra are very different from those obtained at lower phase angles; they lack the familiar 1.5 and 2μm absorption bands, and the expected 3μm water ice primary absorption appears as an unusually narrow dip at 2.87μm. We have modeled these data using multiple approaches. First, we use a simple Mie scattering model to constrain the size distribution and composition of the particles. The Mie model allows us to understand the overall shapes of the spectra in terms of dominance by diffraction at these ultra-high phase angles, and also to demonstrate that the 2.87μm dip is associated with the Christiansen frequency of water ice (where the real refractive index passes unity). Second, we use a combination of Mie scattering with Effective Medium Theory to probe the effect of porous (but structureless) particles on the overall shape of the spectrum and depth of the 2.87μm band. Such simple models are not able to capture the shape of this absorption feature well. Finally, we model each particle as an aggregate of discrete monomers, using the Discrete Dipole Approximation (DDA) model, and find a better fit for the depth of the 2.87μm feature. The DDA models imply a slightly different overall size distribution. We present a simple heuristic model which explains the differences between the Mie and DDA model results. We conclude that the F ring contains aggregate particles with a size distribution that is distinctly narrower than a typical power law, and that the particles are predominantly crystalline water ice.
AB - We present models of the near-infrared (1-5μm) spectra of Saturn's F ring obtained by Cassini's Visual and Infrared Mapping Spectrometer (VIMS) at ultra-high phase angles (177.4-178.5°). Modeling this spectrum constrains the size distribution, composition, and structure of F ring particles in the 0.1-100μm size range. These spectra are very different from those obtained at lower phase angles; they lack the familiar 1.5 and 2μm absorption bands, and the expected 3μm water ice primary absorption appears as an unusually narrow dip at 2.87μm. We have modeled these data using multiple approaches. First, we use a simple Mie scattering model to constrain the size distribution and composition of the particles. The Mie model allows us to understand the overall shapes of the spectra in terms of dominance by diffraction at these ultra-high phase angles, and also to demonstrate that the 2.87μm dip is associated with the Christiansen frequency of water ice (where the real refractive index passes unity). Second, we use a combination of Mie scattering with Effective Medium Theory to probe the effect of porous (but structureless) particles on the overall shape of the spectrum and depth of the 2.87μm band. Such simple models are not able to capture the shape of this absorption feature well. Finally, we model each particle as an aggregate of discrete monomers, using the Discrete Dipole Approximation (DDA) model, and find a better fit for the depth of the 2.87μm feature. The DDA models imply a slightly different overall size distribution. We present a simple heuristic model which explains the differences between the Mie and DDA model results. We conclude that the F ring contains aggregate particles with a size distribution that is distinctly narrower than a typical power law, and that the particles are predominantly crystalline water ice.
KW - Ices, ir spectroscopy
KW - Planetary rings
KW - Radiative transfer
KW - Saturn, rings
UR - http://www.scopus.com/inward/record.url?scp=80053052505&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=80053052505&partnerID=8YFLogxK
U2 - 10.1016/j.icarus.2011.04.011
DO - 10.1016/j.icarus.2011.04.011
M3 - Article
AN - SCOPUS:80053052505
SN - 0019-1035
VL - 215
SP - 682
EP - 694
JO - Icarus
JF - Icarus
IS - 2
ER -