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Science 10 April 1981:
Vol. 212. no. 4491, pp. 192 - 200
DOI: 10.1126/science.212.4491.192
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Articles

Infrared Observations of the Saturnian System from Voyager 1

R. HANEL 1, B. CONRATH 1, F. M. FLASAR 1, V. KUNDE 1, W. MAGUIRE 1, J. PEARL 1, J. PIRRAGLIA 1, R. SAMUELSON 1, L. HERATH 1, M. ALLISON 2, D. CRUIKSHANK 3, D. GAUTIER 4, P. GIERASCH 5, L. HORN 6, R. KOPPANY 6, and C. PONNAMPERUMA 7

1 Goddard Space Flight Center, Greenbelt, Maryland 20771
2 Rice University, Houston, Texas 77001
3 University of Hawaii, Honolulu 96822
4 Paris Observatory Meudon, France
5 Cornell University, Ithaca, New York 14853
6 Jet Propulsion Laboratory, Pasadena, California 91109
7 University of Maryland, College Park 20742

During the passage of Voyager 1 through the Saturn system, the infrared instrument acquired spectral and radiometric data on Saturn, the rings, and Titan and other satellites. Infrared spectra of Saturn indicate the presence of H2, CH4, NH3, PH3, C2H2, C2H6, and possibly C3H4 and C3H8. A hydrogen mole fraction of 0.94 is inferred with an uncertainty of a few percent, implying a depletion of helium in the atmosphere of Saturn relative to that of Jupiter. The atmospheric thermal structure of Saturn shows hemisphere asymmetries that are consistent with a response to the seasonally varying insolation. Extensive small-scale latitudinal structure is also observed. On Titan, positive identifications of infrared spectral features are made for CH4, C2H2, C2H4, C2H6, and HCN; tentative identifications are made for C3H4 and C3H8. The infrared continuum opacity on Titan appears to be quite small between 500 and 600 cm–1, implying that the solid surface is a major contributor to the observed emission over this spectral range; between 500 and 200 cm–1 theopacity increases with decreasing wave number, attaining an optical thickness in excess of 2 at 200 cm–1. Temperatures near the 1-millibar level are independent of longitude and local time but show a decrease of sim 20 K between the equator and north pole, which suggests a seasonally dependent cyclostrophic zonal flow in the stratosphere of sim 100 meters per second. Measurements of the C ring of Saturn yield a temperature of 85 ± 1 K and an infrared optical depth of 0.09 ± 0.01. Radiometer observations of sunlight transmitted through the ring system indicate an optical depth of 101.3 ±0.3 for the Cassini division. A phase integral of 1.02 ± 0.06 is inferred for Rhea, which agrees with values for other icy bodies in the solar system. Rhea eclipse observations indicate the presence of surface materials with both high and low thermal inertias, the former most likely a blocky component and the latter a frost.

Submitted on February 9, 1981


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Science. ISSN 0036-8075 (print), 1095-9203 (online)