Scientists surprised by source of largest quake detected on Mars
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[October 19, 2023]
By Will Dunham
WASHINGTON (Reuters) - On May 4, 2022, NASA's InSight lander detected
the largest quake yet recorded on Mars, one with a 4.7 magnitude -
fairly modest by Earth standards but strong for our planetary neighbor.
Given Mars lacks the geological process called plate tectonics that
generates earthquakes on our planet, scientists suspected a meteorite
impact had caused this marsquake. But a search for an impact crater came
up empty, leading scientists to conclude that this quake was caused by
tectonic activity - rumbling in the planet's interior - and giving them
a deeper understanding about what makes Mars shake, rattle and roll.
"We concluded that the largest marsquake seen by InSight was tectonic,
not an impact. This is important as it shows the faults on Mars can host
hefty marsquakes," said planetary scientist Ben Fernando of the
University of Oxford in England, lead author of the research published
this week in the journal Geophysical Research Letters. "We really
thought that this event might be an impact."
"This represents a significant step forward in our understanding of
Martian seismic activity and takes us one step closer to better
unraveling the planet's tectonic processes," added Imperial College
London planetary scientist and study co-author Constantinos Charalambous,
co-chair of InSight's Geology Working Group.
NASA retired InSight in 2022 after four years of operations. In all,
InSight's seismometer instrument detected 1,319 marsquakes.
Earth's crust - its outermost layer - is divided into immense plates
that continually shift, triggering quakes. The Martian crust is a single
solid plate. But that does not mean all is quiet on the Martian front.
"There are still faults that are active on Mars. The planet is still
slowly shrinking and cooling, and there is still motion within the crust
even though there are no active plate tectonic processes going on
anymore. These faults can trigger quakes," Fernando said.
The researchers determined that the 4.7 magnitude quake was centered in
the Al-Qahira Vallis region in the Martian southern hemisphere, roughly
1,200 miles (2,000 km) southeast of InSight's location just north of the
equator. They think it originated perhaps a few dozen miles (km) below
the surface.
"Most of the marsquakes we've detected thus far have been associated
with a region called Cerberus Fossae, located eastward of InSight.
Conversely, the origin of this one left us puzzled, as no discernible
surface features indicated ongoing tectonic processes as a likely cause,
particularly ones that would cause such a powerful quake," Charalambous
added.
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The planet Mars is shown in this NASA Hubble Space Telescope view
taken May 12, 2016. NASA/Handout via Reuters /File Photo
The energy it released surpassed the cumulative energy from all the
other marsquakes InSight recorded. The researchers initially noted
similarities in its seismic signature to two meteorite impacts
detected by InSight that gouged craters roughly 500 feet (150
meters) wide.
They enlisted the various space agencies with spacecraft monitoring
the Martian surface - the European, U.S., Chinese, Indian and United
Arab Emirates agencies - to check for evidence of an impact on the
day of the quake. No luck.
"The absence of a crater in our image search for this large
marsquake represents a significant milestone in interpreting seismic
signals on Mars," Charalambous said.
With future human missions to Mars in mind, a greater understanding
of Martian seismic activity is pertinent.
"On Earth, a quake of this size would probably break windows, shake
things off shelves, etc., but would not bring the house down,"
Fernando said.
Charalambous said the location of the majority of the marsquakes
detected by InSight remained uncertain, with a poor understanding of
the mechanisms that triggered them.
"Each seismic event detected by InSight is a valuable piece of the
puzzle, but this particular event plays a crucial role in unveiling
the Red Planet's geological history, shedding light on its interior
and evolution," Charalambous said.
"Furthermore, it provides essential insights into the distribution
of seismic activity on Mars, which is a vital consideration for
planning future human missions to the planet."
(Reporting by Will Dunham; Editing by Daniel Wallis)
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