This composite
image looking toward the higher regions of Mount Sharp was taken on September
9, 2015, by NASA's Curiosity rover. In the foreground -- about 2 miles (3
kilometers) from the rover -- is a long ridge teeming with hematite, an iron
oxide.
Credits:
NASA/JPL-Caltech/MSSS
While NASA
imagery has shown evidence of ancient rivers and lakes on Mars that
transitioned to dry dunes, uncertainty remains over the timing of the
environmental changes that may have contributed to these shifts.
Now, data
collected by NASA’s Curiosity rover has revealed that individual crystals in
the iron oxide hematite can be used as a mineralogical marker of changes to
Mars’ ancient climate. Because the shape and structure of these crystallites
reflect the conditions – such as temperature and water presence – under which
they were formed, they can serve as an indicator of when these changes
occurred.
Scientists
studied 20 samples collected by Curiosity across various elevations throughout
Gale Crater for a paper published Thursday in Science. Gale Crater’s walls
reveal Mars’ environmental history layer by layer, with deeper elevations
capturing its earliest years. The team analyzed data from the rover’s Chemistry
and Minerology (CheMin) instrument and discovered that hematite showed
different crystallite sizes at different elevations. They also discovered that
goethite, a mineral that typically forms alongside hematite, was absent in
samples from lower elevations but still present in samples from higher
elevations. This suggests that warm groundwater might have remained for up to
4.7 million years in the deepest layers of Gale Crater and that during much of
this time, these long-lived aquifers could have been potentially habitable.
This image shows
the 20 Curiosity drill samples from Gale Crater that were analyzed for this
study.
Credit:
NASA/JPL-Caltech/MSSS
“What we found
was that warm and wet conditions were present for extended periods in buried
rocks, despite Mars’ climate becoming colder,” said Tanya Peretyazhko, co-first
author of the study and planetary scientist in the Astromaterials Research and
Exploration Science division at NASA’s Johnson Space Center in Houston. “It
means that deep in those rocks, those warmer conditions could have made for
habitable conditions for much longer periods of time, provided that other
essential factors were present.”
Iron oxides are
considered indicators of water activity because they form in its presence. This
study shows that hematite can also be a marker of climate changes based on its
crystallite sizes and structures, which change under different temperatures. The
scientists found that hematite crystallites from higher elevations in Gale
Crater were less than 10 nanometers in size, while crystallites from lower
locations were generally larger, reaching up to 65 nanometers. These findings
aligned with the observations that samples from higher elevations contained
both hematite and goethite, while lower elevation samples lacked goethite.
“What we found was that warm and
wet conditions were present for extended periods in buried rocks, despite Mars’
climate becoming colder."
Tanya Peretyazhko
Planetary Scientist
They concluded that, under warmer
conditions when the pH of water is neutral or slightly alkaline, goethite can
transform into hematite. These warmer conditions also favored an increase in
hematite crystallite size in the deeper layers of Gale Crater through a process
known as Ostwald ripening, in which smaller crystallites dissolve and
contribute to the growth of larger ones.
“This can tell you that the top layers were colder and didn’t have enough water, or the water presence was relatively short-lived, so the crystallites didn’t have sufficient time and conditions to grow in size,” said Peretyazhko. “But the lower layers had longstanding warm water that allowed those crystallites to grow.”
An artist rendering of the
Curiosity rover with its scientific instruments labeled. Scientists used the
Chemistry and Minerology (CheMin) instrument to perform X-ray diffraction
analysis on samples of powdered rock.
Credit: NASA/JPL-Caltech/MSSS
A unique highlight of this study is
that the data comes from Martian samples, rather than from theoretical
modeling. Curiosity’s robotic arm delivered powdered rock to CheMin’s input
funnel, where it was analyzed. “With CheMin’s X-ray diffraction patterns, we
can look at the hematite crystal’s size and dimensions, information that that
can’t be gathered from satellite analysis of the Martian surface.” said Tom
Bristow, principal investigator of the CheMin instrument at NASA’s Ames
Research Center in California’s Silicon Valley.
Ashwin Vasavada, Curiosity’s
project scientist at NASA’s Jet Propulsion Laboratory in Southern California,
said CheMin is capable of making measurements with extraordinary scientific
fidelity.
“It doesn’t just tell you there is
hematite," Vasavada explained. "One can use the data to extract the
size and shape of the hematite crystallites and the presence of other related
minerals, all of which were necessary to produce this result.”
More about Curiosity
Curiosity was built by NASA JPL,
which is managed by Caltech in Pasadena, California. NASA JPL leads the mission
on behalf of NASA’s Science Mission Directorate in Washington as part of NASA’s
Mars Exploration Program portfolio. CheMin, led by NASA Ames , is one of 10
science instruments aboard Curiosity and has a cross-country team of
scientists, including researchers at NASA Ames, University of Arizona,
California Institute of Technology, Planetary Science Institute, Carnegie
Institution for Science, Lunar and Planetary Institute, JPL, NASA’s Goddard
Space Flight Center in Greenbelt, Maryland, and NASA’s Johnson. The team
combines expertise in mineralogy, petrology, materials science, astrobiology
and soil science, with experience studying terrestrial, lunar and Martian
rocks.
For more information on NASA’s
Curiosity rover, visit:
https://science.nasa.gov/mission/msl-curiosity
Source: NASA Uses Mineralogical Marker to Understand Ancient Martian Climate - NASA Science
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