Active upper-atmosphere chemistry and dynamics from polar circulation reversal on Titan

Saturn’s moon Titan has a nitrogen atmosphere comparable to Earth’s, with a surface pressure of 1.4 bar. Numerical models reproduce the tropospheric conditions very well but have trouble explaining the observed middle-atmosphere temperatures, composition and winds1, 2. The top of the middle-atmosphe...

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Bibliographic Details
Published in:Nature
Main Authors: Teanby, Nick A, Irwin, Patrick G. J., Nixon, Conor A., de Kok, R, Vinatier, S, Coustenis, A, Sefton-Nash, Elliot, Calcutt, SB, Flasar, FM
Format: Article in Journal/Newspaper
Language:English
Published: 2012
Subjects:
South pole
Online Access:https://hdl.handle.net/1983/5f9a976d-7bdf-4417-a48a-ded12f57b470
https://research-information.bris.ac.uk/en/publications/5f9a976d-7bdf-4417-a48a-ded12f57b470
https://doi.org/10.1038/nature11611
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Summary:Saturn’s moon Titan has a nitrogen atmosphere comparable to Earth’s, with a surface pressure of 1.4 bar. Numerical models reproduce the tropospheric conditions very well but have trouble explaining the observed middle-atmosphere temperatures, composition and winds1, 2. The top of the middle-atmosphere circulation has been thought to lie at an altitude of 450 to 500 kilometres, where there is a layer of haze that appears to be separated from the main haze deck3. This ‘detached’ haze was previously explained as being due to the co-location of peak haze production and the limit of dynamical transport by the circulation’s upper branch4. Here we report a build-up of trace gases over the south pole approximately two years after observing the 2009 post-equinox circulation reversal, from which we conclude that middle-atmosphere circulation must extend to an altitude of at least 600 kilometres. The primary drivers of this circulation are summer-hemisphere heating of haze by absorption of solar radiation and winter-hemisphere cooling due to infrared emission by haze and trace gases5; our results therefore imply that these effects are important well into the thermosphere (altitudes higher than 500 kilometres). This requires both active upper-atmosphere chemistry, consistent with the detection of high-complexity molecules and ions at altitudes greater than 950 kilometres6, 7, and an alternative explanation for the detached haze, such as a transition in haze particle growth from monomers to fractal structures8.

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