Thirty giant icy avalanches on Saturn's moon Iapetus have been spied by NASA's Cassini spacecraft, a new study says. The events, likely triggered by large meteors, may offer a unique insight into the mechanics of landslides on Earth.

With steep crater walls and a 12-mile-high (19-kilometer-high) mountain ridge more than twice the height of Mount Everest, Iapetus has nearly a perfect setup for avalanches, according to study leader Kelsi Singer, a Ph.D. candidate in geology and geophysics at Washington University in St. Louis.

"When you look at Iapetus from space, you can clearly see the equatorial ridge sticking out, and it makes the icy moon look somewhat like a walnut." (Related: "Saturn's 'Walnut' Moon Mystery Cracked?")

The moon "has some of highest topography for its size of any major body in the solar system, and has the most landslides other than Mars," Singer said.

Analyzing the Cassini landslide images, Singer and her team noticed that icy debris falling down the crater walls and mountain ridges would travel surprisingly long distances horizontally across the terrain—sometimes 50 miles (80 kilometers), which is 20 to 30 times the height from which they fell.

"The scale is just enormous—if you were standing on the ground, you wouldn't be able to see" all of the cliff.

Flash Heating Spurs Long Landslides?

Most landslides on Earth spill out to twice the height from which they fall.

However, a less understood type of landslide called a long-runout rock landslide, or sturzstorm, does fall longer distances, behaving like those seen on Iapteus. (Watch video: Landslides 101.)

Long-runout landslides on Earth have long stumped scientists, since there should be enough friction to stop the tumbling rock or ice.

On Iapetus, scientists suspect, an unknown factor is reducing the friction of the ice avalanches.

The culprit may be a phenomenon called flash heating, during which friction from the landslide heats up the ice, making it slippery enough to speed along the rocks and debris as they fall.

"Because the material is moving very quickly, [the heat] doesn't have much time to dissipate into the surrounding material, and so the heat is concentrated in a small area—just enough heat to help make the cold, hard ice more slippery," said Singer, whose study appeared this week in the journal Nature Geoscience.

Unlocking Earth's Landslides

Singer and her team are most excited about how the Iapetus landslides will aid our understanding of similar natural events on Earth.

"Long-runout landslides are a natural hazard here on Earth that can seriously affect people if they were to occur in a populated area," she said.

"So of course we want to know more about the mechanisms that allow them to happen, and the landslides on Iapetus help narrow down the possible mechanisms."