Cassini Imaging Science: Instrument Characteristics And Anticipated Scientific Investigations At Saturn

Porco, C. C.; West, Robert A.; Squyres, S. W.; McEwen, A. S.; Thomas, P. C.; Murray, C. D.; DelGenio, Anthony D.; Ingersoll, Andrew P.; Johnson, T. V.; Neukum, G.; Veverka, J.; Dones, L.; Brahic, A.; Burns, Joseph A.; Haemmerle, V.; Knowles, Benjamin; Dawson, D. D.; Roatsch, Thomas; Beurle, K.; Owen, W. M.

doi:10.1007/s11214-004-1456-7

Cited by 333 publications

(284 citation statements)

References 248 publications

(150 reference statements)

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“…Both of these cameras have multiple filters, but for the purposes of this analysis we only considered images obtained through the clear filters or the RED filter on the WAC. Note that the effective wavelength of the RED filter (647 nm) is close to the effective wavelengths of the NAC and WAC clear filters (651 nm and 634 nm, respectively, Porco et al 2004). Thus the measured brightness through these different filters should be insensitive to the rings' spectral slopes.…”

Section: Data Sourcesmentioning

confidence: 86%

Saturn’s G and D Rings Provide Nearly Complete Measured Scattering Phase Functions of Nearby Debris Disks

Hedman

Stark

2015

ApJ

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The appearance of debris disks around distant stars depends upon the scattering/phase function (SPF) of the material in the disk. However, characterizing the SPFs of these extrasolar debris disks is challenging because only a limited range of scattering angles are visible to Earth-based observers. By contrast, Saturn's tenuous rings can be observed over a much broader range of geometries, so their SPFs can be much better constrained. Since these rings are composed of small particles released from the surfaces of larger bodies, they are reasonable analogs to debris disks and so their SPFs can provide insights into the plausible scattering properties of debris disks. This work examines two of Saturn's dusty rings: the G ring (at 167,500 km from Saturn's center) and the D68 ringlet (at 67,600 km). Using data from the cameras onboard the Cassini spacecraft, we are able to estimate the rings' brightnesses at scattering angles ranging from 170• to 0.5 • . We find that both of the rings exhibit extremely strong forwardscattering peaks, but for scattering angles above 60• their brightnesses are nearly constant. These SPFs can be well approximated by a linear combination of three Henyey-Greenstein functions, and are roughly consistent with the SPFs of irregular particles from laboratory measurements. Comparing these data to Fraunhofer and Mie models highlights several challenges involved in extracting information about particle compositions and size distributions from SPFs alone. The SPFs of these rings also indicate that the degree of forward scattering in debris disks may be greatly underestimated.

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Section: Data Sourcesmentioning

confidence: 86%

Saturn’s G and D Rings Provide Nearly Complete Measured Scattering Phase Functions of Nearby Debris Disks

Hedman

Stark

2015

ApJ

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“…The ultraviolet channel is sensitive to the upper haze layer and Rayleigh scattering. The filter details can be found in Figure 2(g) and in Porco et al (2004), Zhang et al (2013). The data points are available in digital form as supplementary online material.…”

Section: Jupitermentioning

confidence: 99%

Reflected Light Curves, Spherical and Bond Albedos of Jupiter- And Saturn-Like Exoplanets*

Dyudina

Zhang

et al. 2016

ApJ

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Reflected light curves observed for exoplanets indicate that a few of them host bright clouds. We estimate how the light curve and total stellar heating of a planet depends on forward and backward scattering in the clouds based on Pioneer and Cassini spacecraft images of Jupiter and Saturn. We fit analytical functions to the local reflected brightnesses of Jupiter and Saturn depending on the planet's phase. These observations cover broadbands at 0.59-0.72 and 0.39-0.5 μm, and narrowbands at 0.938 (atmospheric window), 0.889 (CH4 absorption band), and 0.24-0.28 μm. We simulate the images of the planets with a ray-tracing model, and disk-integrate them to produce the full-orbit light curves. For Jupiter, we also fit the modeled light curves to the observed full-disk brightness. We derive spherical albedos for Jupiter andSaturn, and for planets with Lambertian and Rayleigh-scattering atmospheres. Jupiter-like atmospheres can produce light curves that are a factor of two fainter at half-phase than the Lambertian planet, given the same geometric albedo at transit. The spherical albedo is typically lower than for a Lambertian planet by up to a factor of ∼1.5. The Lambertian assumption will underestimate the absorption of the stellar light and the equilibrium temperature of the planetary atmosphere. We also compare our light curves with the light curves of solid bodies: the moons Enceladus and Callisto. Their strong backscattering peak within a few degrees of opposition (secondary eclipse) can lead to an even stronger underestimate of the stellar heating.

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“…The peak zonal velocityū was (5). An image at 889 nm, where methane gas is a strong absorber, is projected onto the blue plane.…”

mentioning

confidence: 99%

Dynamics of Saturn's South Polar Vortex

Dyudina

Ingersoll

Ewald

et al. 2008

Science

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The camera onboard the Cassini spacecraft has allowed us to observe many of Saturn's cloud features. We present observations of Saturn's south polar vortex (SPV) showing that it shares some properties with terrestrial hurricanes: cyclonic circulation, warm central region (the eye) surrounded by a ring of high clouds (the eye wall), and convective clouds outside the eye. The polar location and the absence of an ocean are major differences. It also shares properties with the polar vortices on Venus, such as polar location, cyclonic circulation, warm center, and long lifetime, but the Venus vortices have cold collars and are not associated with convective clouds. The SPV's combination of properties is unique among vortices in the solar system

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Cassini Imaging Science: Instrument Characteristics And Anticipated Scientific Investigations At Saturn

Cited by 333 publications

References 248 publications

Saturn’s G and D Rings Provide Nearly Complete Measured Scattering Phase Functions of Nearby Debris Disks

Saturn’s G and D Rings Provide Nearly Complete Measured Scattering Phase Functions of Nearby Debris Disks

Reflected Light Curves, Spherical and Bond Albedos of Jupiter- And Saturn-Like Exoplanets*

Dynamics of Saturn's South Polar Vortex

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