by Staff WritersLemont, IL (SPX) Mar 30, 2018
Using Argonne's Advanced Photon Source, researchers identified a form of water known as Ice-VII, which was trapped within diamonds that crystallized deep in the Earth's mantle. |
A study published in Science last week relies on extremely bright X-ray beams from the U.S. Department of Energy's (DOE) Advanced Photon Source (APS) at Argonne National Laboratory to confirm the presence of naturally occurring water at least 410 kilometers below the Earth's surface. This exciting discovery could change our understanding of how water circulates deep in the Earth's mantle and how heat escapes from the lower regions of our planet.
Through use of the APS, a DOE Office of Science User Facility, the researchers identified a form of water known as Ice-VII, which was trapped within diamonds that crystallized deep in the Earth's mantle. This is the first time Ice-VII has been discovered in a natural sample, making the compound a new mineral accepted by the International Mineralogical Association.
"[T]hanks to the amazing technical capabilities of the APS, this team of researchers was able to pinpoint and study the exact area on the diamonds that trapped the water." - Stephen Streiffer, Argonne Associate Laboratory Director for Photon Sciences and Director of the APS
This study is just the latest in a long line of research projects at the APS that have shed light on the composition and makeup of the deep Earth, regions that humans cannot explore directly. Instead, scientists used high-powered X-ray beams to analyze inclusions in diamonds, which were formed in the deep Earth, so as to come to conclusions about what happened in those regions.
In other geological studies at the APS, researchers have used high-pressure chambers and lasers to put materials under extreme pressure and temperatures for study, literally recreating the conditions deep below the Earth's surface to understand what happens there.
"In this study, thanks to the amazing technical capabilities of the APS, this team of researchers was able to pinpoint and study the exact area on the diamonds that trapped the water," said Stephen Streiffer, Argonne Associate Laboratory Director for Photon Sciences and Director of the APS. "That area was just a few microns wide. To put that in context, a human hair is about 75 microns wide.
"This research, enabled by partners from the University of Chicago and the University of Nevada, Las Vegas, among other institutions, is just the latest example of how the APS is a vital tool for researchers across scientific disciplines," he said.
In this case, researchers analyzed rough, uncut diamonds mined from regions in China and Africa. Using an optical microscope, mineralogists first identified inclusions, or impurities, which must have formed when the diamond crystallized. Most diamonds have inclusions caused by a sample of other elements or compounds that were trapped as the carbon fused into a diamond.
"We are interested in those inclusions because they tell us about the chemical composition and conditions in the deep Earth when the diamond was formed," said Antonio Lanzirotti, a University of Chicago Research Associate Professor and a co-author on the study.
After many millions of years, diamonds are pushed up from the Earth's mantle to the surface, where many are mined for jewelry and industrial purposes.
To positively identify the composition of the inclusions, mineralogists needed a stronger instrument. That's where University of Chicago's GeoSoilEnviroCARS's (GSECARS) beamlines at the APS came in. GSECARS operates a suite of instruments at the APS dedicated to frontier research in the Earth sciences.
Oliver Tschauner, the lead author on the study and a mineralogist at University of Nevada in Las Vegas, worked with the GSECARS group to probe more than a dozen diamonds that he had identified with this inclusion.
Because of the pressure required for diamonds to form, the scientists know that these specimens formed between 410 and 660 kilometers below the Earth's surface.
Thanks to the very high brightness of the APS X-rays, which are a billion times more intense than conventional X-ray sources, scientists can determine the molecular or atomic makeup the specimens that are only micrometers across.
When the focused beam of X-rays hits the molecules of the specimen, they scatter. Pictures or images taken of this scattering pattern are then analyzed, as each compound or molecule shows a unique pattern.
What the team identified in this study was surprising: water, in the form of ice.
The composition of the water is the same as the water that we drink and use every day, but in a cubic crystalline form, the result of the extremely high pressure of the diamond.
This form of water, Ice-VII, was created in the lab decades ago, but this study was the first to confirm that it also forms naturally.
"This wasn't easy to find," said Vitali Prakapenka, a University of Chicago Research Professor and a co-author of the study, who said that the team used high-resolution diffraction techniques to get the right scans, or images, of the Ice-VII. "People have been searching for this kind of inclusion for a long time."
The researchers said the significance of the study is profound because it shows that flowing water is present much deeper below the Earth's surface than originally thought. Going forward, the results raise a number of important questions about how water is recycled in the Earth and how heat is circulated.
Tschauner has said the discovery can help scientists create new, more accurate models of what's going on inside the Earth, specifically how and where heat is generated under the Earth's crust. This may help scientists better understand one of the driving mechanisms for plate tectonics.
For now, the GSECARS team is wondering whether the mineral Ice-VII will be renamed, now that it is officially a mineral. This is not the first mineral to be identified thanks to research done at the APS beamlines managed by GSECARS: Bridgmanite, the Earth's most abundant mineral and a high-density form of magnesium iron silicate, was researched extensively at the APS before it was named. Tschauner was a lead author on that study, too.