Scientists find evidence of underground reservoir for water on Mars
A study released Monday using data from NASA's Mars InSight lander shows evidence of liquid water far below the surface of the fourth planet, advancing the search for life there and showing what might have happened to Mars' ancient oceans.
Agencies and A News
WORLD
Published August 13,2024
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View of the InSight's seismometer on the Martian surface, in one of the last images taken by NASA's InSight Mars lander, on December 11, 2022. (REUTERS File Photo)
Researchers have found evidence for a large underground reservoir of liquid water on Mars - enough to fill oceans on the planet's surface.
Using data from NASA's Insight lander, the scientists estimated that the amount of groundwater could cover all of Mars to a depth of between one and two kilometres.
But the experts say the reservoir is unlikely to be of much use to anyone trying to tap into it to supply a future Mars colony.
It is located in tiny cracks and pores in rock in the middle of the Martian crust, between 11.5 and 20 kilometres below the surface. Even on Earth, drilling a hole a kilometre deep is a challenge.
Vashan Wright, a former postdoctoral fellow at UC Berkeley, in the U.S., who is now an assistant professor at UC San Diego's Scripps Institution of Oceanography, said: "Understanding the Martian water cycle is critical for understanding the evolution of the climate, surface and interior.
"A useful starting point is to identify where water is and how much is there."
Scientists on Earth have sent many probes and landers to Mars to find out what happened to the water that was on the planet some three billion years ago, as well as when it happened and whether life exists or used to exist on the planet.
Experts suggest the findings are an indication that much of the water did not escape into space but filtered down into the crust.
The researchers used data that InSight collected during a four-year mission ending in 2022.
The lander gathered information from the ground directly beneath it, including on the speed of Marsquake waves.
Using a model informed by a mathematical theory of rock physics, the researchers determined that the presence of liquid water in the crust most plausibly explained the data.
"While available data are best explained by a water-saturated mid-crust, our results highlight the value of geophysical measurements and better constraints on the mineralogy and composition of Mars' crust," the authors wrote.
The findings are published in the Proceedings of the National Academy of Sciences journal.