Extensive
Water in Mar’s Interior
Washington,
D.C.—Until
now, Earth was the only planet known to have vast reservoirs of water in its
interior. Scientists analyzed the water content of two Martian meteorites
originating from inside the Red Planet. They found that the amount of water in
places of the Martian mantle is vastly larger than previous estimates and is
similar to that of Earth’s. The results not only affect what we know about the
geologic history of Mars, but also have implications for how water got to the
Martian surface. The data raise the possibility that Mars could have sustained
life.
The
research was led by former Carnegie postdoctoral scientist Francis McCubbin, now
at the University of New Mexico. The analysis was performed by Carnegie
Institution investigator Erik Hauri
and team and is published in the journal Geology.
The
scientists analyzed what are called shergottite meteorites. These are fairly
young meteorites that originated by partial melting of the Martian mantle—the
layer under the crust—and crystallized in the shallow subsurface and on the
surface. They came to Earth when ejected from Mars approximately 2.5 million
years ago. Meteorite geochemistry tells scientists a lot about the geological
processes the planet underwent.
“We
analyzed two meteorites that had very different processing histories,” explained
Hauri. “One had undergone considerable mixing with other elements during its
formation, while the other had not. We analyzed the water content of the mineral
apatite and found there was little difference between the two even though the
chemistry of trace elements was markedly different. The results suggest that
water was incorporated during the formation of Mars and that the planet was able
to store water in its interior during the planet’s differentiation.”
Based on
the mineral’s water content, the scientists estimated that the Martian mantle
source from which the rocks were derived contained between 70 and 300 parts per
million (ppm) water. For comparison, the upper mantle on Earth contains
approximately 50-300 ppm water. Hauri and team were able to determine these
values with new techniques and new standards they developed that can quantify
water in apatite using a technology called secondary ion mass spectrometry
(SIMS).
“There
has been substantial evidence for the presence of liquid water at the Martian
surface for some time,” Hauri said. “So it’s been puzzling why previous
estimates for the planet’s interior have been so dry. This new research makes
sense and suggests that volcanoes may have been the primary vehicle for getting
water to the surface.”
McCubbin
concluded, “Not only does this study explain how Mars got its water, it provides
a mechanism for hydrogen storage in all the terrestrial planets at the time of
their formation.”
__________________
This work was
supported by NASA Cosmochemistry grants NNX11AG76G, NNX10AI77G, the New Mexico
Space Grant Consortium, and the Carnegie Institution.
The Carnegie
Institution for Science (carnegiescience.edu) is a private,
nonprofit organization headquartered in Washington, D.C., with six research
departments throughout the U.S. Since its founding in 1902, the Carnegie
Institution has been a pioneering force in basic scientific research. Carnegie
scientists are leaders in plant biology, developmental biology, astronomy,
materials science, global ecology, and Earth and planetary science
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