20 February 2012
WASHINGTON, DC— Images of a martian landscape offer evidence that the Red Planet’s surface not only can shake like the surface of Earth, but has done so relatively recently. If marsquakes do indeed take place, said the scientists who analyzed the high-resolution images, our nearest planetary neighbor may still have active volcanism, which could help create conditions for liquid water.
With High Resolution Imaging Science Experiment (HiRISE) imagery, the research team examined boulders along a fault system known as Cerberus Fossae, which cuts across a very young (few million years old) lava surface on Mars. By analyzing boulders that toppled from a martian cliff, some of which left trails in the coarse-grained soils, and comparing the patterns of dislodged rocks to such patterns caused by quakes on Earth, the scientists determined the rocks fell because of seismic activity. The martian patterns were not consistent with how boulders would scatter if they were deposited as ice melted, another means by which rocks are dispersed on Mars.
Gerald Roberts, an earthquake geologist with Birkbeck, an institution of the University of London, who led the study, said that the images of Mars included boulders that ranged from two to 20 meters (6.5 to 65 feet) in diameter, which had fallen in avalanches from cliffs. The size and number of boulders decreased over a radius of 100 kilometers (62 miles) centered at a point along the Cerberus Fossae faults.
“This is consistent with the hypothesis that boulders had been mobilized by ground-shaking, and that the severity of the ground-shaking decreased away from the epicenters of marsquakes,” Roberts said.
The study, by Roberts and his colleagues, will be published Thursday in the Journal of
Geophysical Research-Planets, a publication of the American Geophysical Union (AGU).
The team compared the pattern of boulder falls, and faulting of the martian surface, with those seen after a 2009 earthquake near L’Aquila, in central Italy. In that event, boulder falls occurred up to approximately 50 km (31 miles) from the epicenter. Because the area of displaced boulders in the marsscape stretched across an area approximately 200 km124-miles) long, the quakes were likely to have had a magnitude greater than 7, the researchers estimated.
By looking at the tracks that the falling boulders had left on the dust-covered martian surface, the team determined that the marsquakes were relatively recent – and certainly within the last few percent of the planet’s history – because martian winds had not yet erased the boulder tracks. Trails on Mars can quickly disappear – for instance, tracks left by NASA robotic rovers are erased within a few years by martian winds, whereas other, sheltered tracks stick around longer. It is possible, the scientists concluded, that large-magnitude quake activity is still occurring on Mars.
The existence of marsquakes could be significant in the ongoing search for life on Mars, the researchers stated. If the faults along the Cerberus Fossae region are active, and the quakes are driven by movements of magma related to the nearby volcano, Elysium Mons, the energy provided in the form of heat from the volcanic activity under the surface of Mars could be able to melt ice. The resulting liquid water, they noted, could provide habitats friendly to life.
Joint Press Release
Kate Ramsayer, +1 (202) 777-7524, [email protected]
Birkback, University of London Contact:
Bryony Merritt, +44 (0)20 7380 3133, [email protected]
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“Possible evidence of palaeomarsquakes from fallen boulder populations, Cerberus Fossae, Mars”
Gerald P. Roberts: Department of Earth and Planetary Sciences, Birkbeck, University of London, United Kingdom;
Brian Matthews: Department of Physics and Astronomy, The Open University, Milton Keynes, United Kingdom;
Christ Bristow: Department of Earth and Planetary Sciences, Birkbeck, University of London, United Kingdom and Hyder Consulting, London, United Kingdom;
Luca Guerrieri: Geological Survey of Italy, ISPRA – High Institute for the Environmental Protection and Research, Rome, Italy;
Joyce Vetterlein: Department of Earth and Planetary Sciences, Birkbeck, University of London, United Kingdom.
Gerald Roberts, Phone: +44 (0)20 3073 8033, Email: [email protected]