Skip to content
Starts With A Bang

Unique ‘sideways tornadoes’ shaped the surface of Mars, new study shows

Add sideways tornadoes to the list of things you can have when your atmosphere is as tenuous as Mars’ is.


“This would be like an F8 tornado sweeping across the surface. These are winds on Mars that will never be seen again unless [there is] another impact.” –Peter Schultz

When we look at ancient impact craters on Mars, one bizarre feature stands out: enormous, outward-going streaks.

Pairs of images illustrate how Martian crater rays appear in different wavelengths of light. The left hand images are THEMIS nighttime thermal infrared images, while the right are visible light images from Mars Global Surveyor. Image credit: Tornabene et al., 2006, JGR v. 111.

These aren’t visible during the day, but appear at night in the infrared, as bright streaks hold onto excessive heat.

On Mars, bare-rock structures hold onto heat far better than sand-like structures do, meaning they will appear brighter at night, when viewed in the infrared. Image credit: NASA/JPL-Caltech/MSSS, Mars Curiosity Rover.

To retain heat, the streaks must be made of bare, blocky structures that somehow had all the sand and dust stripped from them.

Sand and briny liquids can flow along the surface of Mars, but while they may explain some phenomena (like the recurring slope lineae shown here), they cannot explain these distant crater rays. Image credit: NASA/JPL/University of Arizona.

“That tells us that something came along and scoured those surfaces bare,” says Peter Schultz, lead author on the new study.

There are many craters on Mars that show evidence for this infrared ray effect, like Mojave crater, illustrated here. Image credit: Science/AAAS.

What could be that thing that came along? Barreling, sideways tornadoes.

Tornadoes are bigger and more powerful on Mars than they are on Earth; this one imaged by the Spirit Rover in 2005 is three separate images taken 2 seconds apart apiece. Image credit: NASA/JPL.

Many craters on worlds contain streaked, scarring pattern headed radially outward from a crater, but the ones on Mars are different.

A detailed, infrared view of a crater on Mars at night reveals these distant, outward streaks that hold onto heat better than all the surrounding areas. Scientists believe rolling tornadoes are the core explanation. Image credit: NASA/JPL/MSSS/HiRISE.

For the craters’ sizes and the energy that created them, the streaks — only visible in the infrared — extend out much too far.

Streaks arising from newly formed craters on Mars (shown in enhanced color, here) can extend for miles, but the infrared streaks of the earlier craters shown are far larger in extent. Image credit: NASA/JPL/MSSS/HiRiSE.

This isn’t normal ejecta, but an additional phenomenon, which is where the barreling tornadoes idea fits in.

Winds at speeds up to 100 km/hr travel across the martian surface. The craters in this image, caused by impacts in Mars’ past, all show different degrees of erosion. Some still have defined outer rims and clear features within them, while others are much smoother and featureless, almost seeming to run into one another or merge with their surroundings. Image credit: ESA/DLR/FU Berlin, CC BY-SA 3.0 IGO.

High-velocity impacts can cause high-speed vortices to form and travel just over the surface.

NASA’s Mars Reconnaissance Orbiter has captured images of dust devils, analogous to tornadoes, more than 10 miles high on the red planet’s surface. Image credit: NASA/JPL/MSSS.

Martian orbiters have already seen normal tornadoes form on the red planet’s surface.

These experiments at the Ames Vertical Gun Range helps researchers understand how surfaces and vapor plumes respond when struck by both hollow and solid impactors at high speeds. Image credit: Brown University/Peter H. Schultz and Brendan Hermalyn, NASA/Ames Vertical Gun Range.

These impacts formed vapor plumes, which travel at supersonic speeds.

The streaks are often associated with smaller craters that were in place when the larger crater was formed. The raised ridges of the preexisting craters disturb the flow of the vapor plume, which causes vortices to form and scour the ground. Image credit: NASA/JPL-Caltech/Arizona State University.

Raised surfaces in the way get scoured, creating these unique streaks.


Mostly Mute Monday tells an astronomical story of an object, image, or phenomenon in mostly visuals, with no more than 200 words of text.

Ethan Siegel is the author of Beyond the Galaxy and Treknology. You can pre-order his third book, currently in development: the Encyclopaedia Cosmologica.

Related

Up Next