Enormous Ice Avalanches on Mars May Have Rushed Down Craters at 260 Feet Per Second



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Not a cinnamon bun: A computer-generated perspective of the Mars north polar ice cap.

Not a cinnamon bun: A computer-generated perspective of the Mars north polar ice cap.
Image: ESA / DLR / FU Berlin; NASA MGS MOLA Science Team

Enigmatic features tucked inside two Martian impact craters could be the remnants of colossal ice avalanches, the largest of which traveled over 9 miles.

Two impact craters in the far northern latitudes of Mars have strange linear features on their inner slopes. New research published in Planetary and Space Science suggests these moraine-like ridges are what’s left of monumental ice avalanches that occurred around a million years ago.

Experts say it’s an interesting theory, but more work will be needed to bolster the claim.

Scientists had previously argued that these linear landforms look like moraines because that’s precisely what they are. Moraines are hilly linear structures formed by slow-moving glaciers, which shove dirt and rocks at the head of their advance. In the Martian polar regions, these glaciers are made from carbon dioxide (rather than the water-ice that makes up Earth’s glaciers), but their geological effects are the same.

The new paper, co-authored by Sergey Krasilnikov from the Russian Academy of Sciences, proposes an alternative explanation: fast-running glacier surges. Essentially, the new paper argues that large towers of water ice, called massifs, located along the top slope of the craters collapsed, resulting in epic avalanches. The moraine-like ridges were formed by accumulating debris shoved to the bottom of the craters by collapsing massifs.

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The two craters containing the moraine-like ridges. The collapsing ice is hypothesized to have fallen from right to left, starting near the outer slopes of the impact craters.

The two craters containing the moraine-like ridges. The collapsing ice is hypothesized to have fallen from right to left, starting near the outer slopes of the impact craters.
Image: NASA / Planetary and Space Science

Krasilnikov and his colleagues simulated these hypothesized surges using data collected by NASA and by performing independent calculations. Together, these methods supported a scenario in which the “excessive accumulation of water ice on slopes” reached “a critical unstable condition,” resulting in the ice avalanches and the formation of the moraine-like ridges below.

Massifs form through the steady accumulation of frost. Eventually, the weight and pressure got so intense that the massifs collapsed, unleashing their contents to the bottom of the crater, according to this interpretation. These collapses would’ve been a sight to behold. The larger of the two collapses involved an estimated 2.42 square kilometers of ice (nearly 1 square mile), while the smaller involved 1.1 square kilometers (0.4 square miles). The larger massif was an estimated 150 meters (492 feet) tall, and the shorter one 100 meters (328 feet) tall.

The falling ice and debris would have traveled at an estimated 80 meters (260 feet) per second. And because gravity is lower on Mars, the debris spread across a wide territory, reaching some 15 kilometers (9.3 miles) from the starting point in the larger collapse, and 12 kilometers (7.5 miles) in the smaller one. During the largest massif collapse, the avalanche encompassed a total area extending 104 square kilometers (40 square miles).

“It’s a nice alternative explanation,” Mike Sori, a planetary scientist from the University of Arizona who wasn’t involved in the new research, told EOS, a publication of the American Geophysical Union. Martian avalanches have been documented before, he said, but these ridges look an awful lot like moraines crafted by carbon dioxide glaciers, he said. Sori said more evidence will be required to make a stronger case.

Future research will also have to figure out why only two examples of ice avalanches have been found on Mars, as EOS points out. Indeed, more examples of these strange ridges would add credence to the claim that ice avalanches do actually occur on the Red Planet.

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