* Astronomy

Could there be life on Titan?
Scientists have discovered that despite its alien environment Saturn's moon Titan looks remarkably like Earth - complete with methane rivers.
Scientists have now mapped a third of the moon's surface using radar, which was able to get through the thick atmosphere and see mountain ranges, lakes and what may be volcanoes.

Read more

The IAU has approved of the term planitia to be used for the naming of plains on Titan. All the plains will be called after planets from the Dune science fiction novels, by American author Frank Herbert.


Expand (139kb, 640 x 480)
Credit: NASA/JPL

The 125-km-wide feature on Titan, located at 5.0S, 23.5W, has been named Chusuk Planitia. The feature is named after the 'Music Planet' Chusuk, the fourth planet of Theta Shalish, from the Dune series.

The Cassini spaceprobe imaged the north pole of Titan, using the spacecrafts wide-angle camera on the 6th June, 2009, when it was approximately 194,000 kilometres from the moon.


Expand (27kb,1024 x 768)
Credit: NASA/JPL/Space Science Institute

The natural colour image shows the night/day terminator, and is centred at 49 degrees north latitude, 243 degrees west longitude, with the north pole rotated about 23 degrees to the left.
Image scale is 11 kilometres per pixel.

Title: Impact of aerosols present in Titan's atmosphere on the CASSINI radar experiment
Authors: S. Rodriguez (AIM, L3ab), P. Paillou (L3AB), M. Dobrijevic (L3AB, Oasu), G. Ruffié (LPIOM), P. Coll (LISA), J. M. Bernard (LISA), P. Encrenaz (OP, Lerma)

Simulations of Titan's atmospheric transmission and surface reflectivity have been developed in order to estimate how Titan's atmosphere and surface properties could affect performances of the Cassini radar experiment. In this paper we present a selection of models for Titan's haze, vertical rain distribution, and surface composition implemented in our simulations. We collected dielectric constant values for the Cassini radar wavelength (~ 2.2 cm) for materials of interest for Titan: liquid methane, liquid mixture of methane-ethane, water ice and light hydrocarbon ices. Due to the lack of permittivity values for Titan's haze particles in the microwave range, we performed dielectric constant (\varepsilon_r) measurements around 2.2 cm on tholins synthesized in laboratory. We obtained a real part of \varepsilon_r in the range of 2-2.5 and a loss tangent between 10^{-3} and 5.10^{-2}. By combining aerosol distribution models (with hypothetical condensation at low altitudes) to surface models, we find the following results: (1) Aerosol-only atmospheres should cause no loss and are essentially transparent for Cassini radar, as expected by former analysis. (2) However, if clouds are present, some atmospheric models generate significant attenuation that can reach -50 dB, well below the sensitivity threshold of the receiver. In such cases, a 13.78 GHz radar would not be able to measure echoes coming from the surface. We thus warn about possible risks of misinterpretation if a 'wet atmosphere' is not taken into account. (3) Rough surface scattering leads to a typical response of ~ -17 dB. These results will have important implications on future Cassini radar data analysis.

Read more  (513kb, PDF)