IE 11 is not supported. For an optimal experience visit our site on another browser.

Titan's surface: dusty dunes?

Scientists have observed dune structures on Titan, Saturn's largest moon — not the ethane ocean long thought to cover the satellite.
Cassini radar sees sand dunes on Saturn's giant moon Titan (upper photo) that are sculpted like Namibian sand dunes on Earth (lower photo).
Cassini radar sees sand dunes on Saturn's giant moon Titan (upper photo) that are sculpted like Namibian sand dunes on Earth (lower photo). Nasa / Jpl - Upper Photo
/ Source: Space.com

When the Cassini-Huygens probe landed on the surface of Saturn’s largest moon, Titan, last year, it found no evidence of the ethane ocean long thought to cover the satellite’s surface.

Instead, scientists observed dune structures that could be dust-like combinations of ethane and smog particles, according to a new study in the current issue of Nature.

Titan’s dense atmosphere is composed mostly of nitrogen with a small amount of methane. This methane is broken up by the Sun’s ultraviolet light to produce a dense orange-brown smog that hides the satellite’s surface.

Scientists thought that ethane, one of the products of these reactions with the Sun, was abundant enough to have condensed and rained down to form a kilometer-deep ocean across the entire surface of the satellite.

Month in Space: January 2014

Slideshow  12 photos

Month in Space: January 2014

From a launch out of the weeds to a special delivery in orbit, see the best space offerings from January 2014.

But observations of the surface suggest that it is instead covered by dunes, which Donald Hunten of the University of Arizona thinks could be made of a combination of ethane and smog particles.

Titan's ethane can't condense into liquid rain because “the smog particles grab the ethane before it has a chance to form drops,” Hunten said.

The resulting particles deposit on the moon's surface and pile up to form dunes that might be as deep as several kilometers, Hunten says. The particles would be more like dust than sand though, so Hunten has dubbed them “smust” (a combination of “smog” and “dust”).

Hunten based his proposal for this mechanism on the observed behavior of ethane in Jupiter’s atmosphere, where at certain levels, it condenses onto smog particles.

“Basically, I used Jupiter as the laboratory to show that the ethane is sticking to the particles,” Hunten told Space.com.

“I think there’s a very deep deposit of them on the ground [of Titan], but we can’t confirm that with observations,” he added.

To confirm Hunten’s theory, laboratory experiments would have to be conducted to show that ethane does indeed condense onto the smog particles.