* Astronomy

The best views of the hydrocarbon lakes and seas on Saturn's moon Titan taken by the Cassini spacecraft are being released today.

North polar region

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A new radar image comprised from seven Titan fly-bys over the last year and a half shows a north pole pitted with giant lakes and seas, at least one of them larger than Lake Superior in the USA, the largest freshwater lake on Earth. Approximately 60% of Titan's north polar region, above 60° north, has been mapped by Cassini's radar instrument. About 14% of the mapped region is covered by what scientists interpret as liquid hydrocarbon lakes.

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Image courtesy NASA/JPL/Space Science Institute

The above image shows the ground trace of the Titan-36 flyby on a mosaic of Titan's surface, for a period of 32 hours around closest approach. The colour of the trace indicates Cassini's altitude above the surface. Blue: > 100 000 km, green: < 100 000 km, light blue: < 50 000, yellow: < 10 000 km, orange: < 5000 km, red: < 2000 km. The point of closest approach is marked T36 (Cassini at 975 km altitude). Cassini approaches Titan over the equatorial region at 16 hours before closest approach (centre right in this image), and then continues to pass over Titan's southern hemisphere.

This image of Titan was taken by the Cassini spacecraft narrow-angle camera on Sept. 2, 2007 using a spectral filter sensitive to wavelengths of ultraviolet light centred at 338 nanometers.
The northern hemisphere is currently in its Winter season.


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Credit NASA/JPL/Space Science Institute

This view was obtained at a distance of approximately 1.3 million kilometres from Titan and at a Sun-Titan-spacecraft, or phase, angle of 20 degrees. Image scale is 8 kilometres per pixel.

Title: About Titan's rotation: A forced "free" resonant wobble
Authors: B. Noyelles
(Version v2)

In Noyelles et al. (2007), a resonance involving the wobble of Titan is being suspected. This paper studies the probability of this scenario and its consequences.
The first step is to build an accurate analytical model that would help to feel the likely resonances in the rotation of every synchronous body. I n this model, I take the orbital eccentricity of the body into account, and also two terms in its orbital inclination. Then an analytical study using the second fundamental model of the resonance is being performed to study the interesting resonance. Finally, I study the dissipative consequences of this resonance.
I find that this resonance might have increased the wobble of Titan of several degrees. Thanks to an original formula, I find that the dissipation involved by the forced wobble might not be negligible compared to the contribution of the eccentricity. I also suspect that, due to the forced wobble, Titan's period of rotation might be a little underestimated by observers.
I finally use the analytical model presented in this paper to compute the periods of the free librations of the four Galilean satellites and Rhea. For Io and Europa, the results are consistent with the previous studies. For the other satellites, the periods of the free librations are respectively 186.37 d, 23.38 y and 30.08 y for Ganymede, 2.44 y, 209.32 y and 356.54 y for Callisto, and 51.84 d, 2.60 y and 3.59 y for Rhea.

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