This near-infrared, colour mosaic from NASA’s Cassini spacecraft shows
the sun glinting off of Titan’s north polar seas. While Cassini has
captured, separately, views of the polar seas and the sun glinting off
of them in the past, this is the first time both have been seen together
in the same view.
The sunglint, also called a specular reflection,
is the bright area near the 11 o’clock position at upper left. This
mirror-like reflection, known as the specular point, is in the south of
Titan’s largest sea, Kraken Mare, just north of an island archipelago
separating two separate parts of the sea.
This particular
sunglint was so bright as to saturate the detector of Cassini’s Visual
and Infrared Mapping Spectrometer (VIMS) instrument, which captures the
view. It is also the sunglint seen with the highest observation
elevation so far — the sun was a full 40 degrees above the horizon as
seen from Kraken Mare at this time — much higher than the 22 degrees
seen earlier. Because it was so bright, this glint was visible through
the haze at much lower wavelengths than before, down to 1.3 microns.
The
southern portion of Kraken Mare (the area surrounding the specular
feature toward upper left) displays a “bathtub ring” — a bright margin
of evaporate deposits — which indicates that the sea was larger at some
point in the past and has become smaller due to evaporation. The
deposits are material left behind after the methane & ethane liquid
evaporates, somewhat akin to the saline crust on a salt flat.
The
highest resolution data from this flyby — the area seen immediately to
the right of the sunglint — cover the labyrinth of channels that connect
Kraken Mare to another large sea, Ligeia Mare. Ligeia Mare itself is
partially covered in its northern reaches by a bright, arrow-shaped
complex of clouds. The clouds are made of liquid methane droplets, and
could be actively refilling the lakes with rainfall.
The view was acquired during Cassini’s August 21, 2014, flyby of Titan, also referred to as “T104″ by the Cassini team.
The
view contains real colour information, although it is not the natural
colour the human eye would see. Here, red in the image corresponds to
5.0 microns, green to 2.0 microns, and blue to 1.3 microns. These
wavelengths correspond to atmospheric windows through which Titan’s
surface is visible. The unaided human eye would see nothing but haze.
No comments:
Post a Comment