* Astronomy

This image from the Synthetic Aperture Radar instrument on the Cassini spacecraft shows the radar-bright region Xanadu and two circular features interpreted to be degraded impact craters. In radar images, bright regions indicate a rough or scattering material, while a dark region might be smoother or more absorbing.
The image was acquired during a flyby of Titan on April 30, 2006.


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Near the top of the image is a 70-kilometer-wide impact structure. In contrast to a similarly sized crater called Sinlap, this crater shows a prominent central peak, indicating that the interaction between the impact and the crust was different in this region.
Near the bottom of the image is another circular feature with a dark central region that does not show evidence of a central peak. Numerous radar-bright channels cut across the image, indicating that liquids have flowed in this region.

This poster shows a composite view from the descent imager/spectral radiometer taken while the European Space Agency's Huygens probe was setting on Titan's surface, juxtaposed with a similarly scaled picture taken on the Moon's surface. Objects near the center of the picture are roughly the size of a person's foot. Objects at the horizon are a fraction of a person's height. The Huygens image was taken on January 14, 2005.


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The Cassini space probe has seen sand dunes on Saturn's giant moon Titan. The bright features in the radar photo are not clouds but topographic features among the dunes


Credit: NASA/JPL

The sand dunes are sculpted like Namibian sand dunes on Earth.


Credit: NASA/JSC

The images taken when the Cassini spacecraft flew by Titan last October show dunes 100 meters high that run parallel to each other for hundreds of miles at Titan's equator. One dune field runs more than 1500 km long.
How the sand formed is a puzzle.
Sand may have formed when liquid methane rain eroded particles from ice bedrock. Researchers had previously thought that it doesn't rain enough on Titan to erode much bedrock.

-- Edited by Blobrana at 02:09, 2006-05-05

Scientists at the University of Arizona Lunar and Planetary Laboratory (LPL) have made two new movies of the Huygens probe's landing on Saturn's giant moon, Titan, on Jan. 14, 2005.

The movies were made from images taken by Huygens' Descent Imager/Spectral Radiometer (DISR) during its 147-minute plunge through Titan's thick orange-brown atmosphere to a soft sandy riverbed. They are the most realistic way yet to experience the far-out-world landing.
These represent the best visual product from the mission obtained so far and the most realistic way yet to experience the landing on a far-away world.
The movie ‘View from Huygens on 14 January 2005’ shows in 4 minutes 40 seconds what the probe actually ‘saw’ within the few hours of the descent and the eventual landing.

"At first the Huygens camera just saw haze over the distant surface" - DISR team member Erich Karkoschka, from the DISR team at the University of Arizona and creator of the movies.


This poster shows a flattened (Mercator) projection of the view from the descent imager/spectral radiometer on the European Space Agency’s Huygens probe at four different altitudes. The images were taken on Jan. 14, 2005.
Credits: ESA/NASA/JPL/University of Arizona


Play movie (11mb)

The second, more technical movie (called ‘DISR movie’), shows DISR's 4-hour operating life in less than five minutes, too. A detailed caption to explain how the movie is structured is provided with the video.
The scientists analysed Huygens' speed, direction of motion, rotation and swinging during descent, represented in this movie. The video also features Huygens' trajectory views from the south, indication of the large and unexpected parachute movements, the changing direction of view as Huygens rotates along with the relative positions of the sun and Cassini, and a clock to follow the actual sequence of events.
Sounds from a left speaker trace Huygens' motion, with tones changing with rotational speed and the tilt of the parachute. There are also clicks that clock the rotational counter, as well as sounds for the probe's heat shield hitting Titan's atmosphere, parachute deployments, heat shield release, jettison of the DISR cover and touch-down.

Sounds from a right speaker go with DISR activity. There's a continuous tone that represents the strength of Huygens' signal to Cassini.

http://www.lpl.arizona.edu/DISR/