Titan imagery with Keck adaptive optics during and after probe entry

We present adaptive optics data from the Keck telescope, taken while the Huygens probe descended through Titan's atmosphere and on the days following touchdown. No probe entry signal was detected. Our observations span a solar phase angle range from 0.05° up to 0.8°, with the Sun in the west....

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Bibliographic Details
Published in:Journal of Geophysical Research: Planets
Main Authors: de Pater, Imke, Ãdámkovics, Máte, Bouchez, Antonin H., Brown, Michael E., Gibbard, Seran G., Marchis, Franck, Roe, Henry G., Schaller, Emily L., Young, Eliot
Format: Article in Journal/Newspaper
Language:unknown
Published: American Geophysical Union 2006
Subjects:
South Pole
Gemini
South pole
Online Access:https://doi.org/10.1029/2005JE002620
Description
Summary:We present adaptive optics data from the Keck telescope, taken while the Huygens probe descended through Titan's atmosphere and on the days following touchdown. No probe entry signal was detected. Our observations span a solar phase angle range from 0.05° up to 0.8°, with the Sun in the west. Contrary to expectations, the east side of Titan's stratosphere was usually brightest. Compiling images obtained with Keck and Gemini over the past few years reveals that the east-west asymmetry can be explained by a combination of the solar phase angle effect and an enhancement in the haze density on Titan's morning hemisphere. While stratospheric haze was prominent over the northern hemisphere, tropospheric haze dominated the south, from the south pole up to latitudes of ∼45°S. At 2.1 μm this haze forms a polar cap, while at 1.22 μm it appears in the form of a collar at 60°S. A few small clouds were usually present near the south pole, at altitudes of 30–40 km. Our narrowband J,H,K images of Titan's surface compare extremely well with that obtained by Cassini ISS, down to the small-scale features. The surface contrast between dark and bright areas may be larger at 2 μm than at 1.6 and 1.3 μm, which would imply that the dark areas may be covered by a coarser-grained frost than the bright regions and/or that there is additional 2 μm absorption there. © 2006 American Geophysical Union. Received 21 October 2005; revised 1 March 2006; accepted 9 March 2006; published 22 June 2006. This work was funded by the National Science Foundation and Technology Center for Adaptive Optics, managed by the University of California at Santa Cruz under cooperative agreement AST-9876783, and by the Center for Integrative Planetary Science at the University of California in Berkeley. The research was further funded through UCB grants AST-0205893 from the National Science Foundation and NNG05GH63G from NASA. S.G.'s work was performed under the auspices of the U.S. Department of Energy, National Nuclear Security Administration by ...

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