Cracking the Code of Kimberlite Eruptions: New Study in Geology
on How Diamonds Make Their Rapid Ascent
Boulder, Colo., USA: If you’ve ever held or beheld a
diamond, there’s a good chance it came from a kimberlite. Over 70% of the
world’s diamonds are mined from these unique volcanic structures. Yet
despite decades of study, scientists are still working to understand how
exactly kimberlites erupt from deep in Earth’s mantle to the surface.
Kimberlites—carrot-shaped volcanic pipes that erupt from mantle depths
greater than 150 km—have long fascinated geologists as windows into the deep
Earth. Their mantle-derived melt ascends rapidly through the mantle and
crust, with some estimates suggesting ascent rates of up to 80 miles per
hour before kimberlites erupt violently at the surface. Along the way, the
magma captures xenoliths and xenocrysts, fragments of the rocks encountered
on its path.
“They’re very interesting and still very enigmatic rocks,” despite being
well-studied, says Ana Anzulović, a doctoral research fellow at the
University of Oslo’s Centre for Planetary Habitability.
In a study published this month in the journal
Geology, Anzulović and colleagues from the University of Oslo have taken a major
step toward solving the puzzle. By modelling how volatile compounds like
carbon dioxide and water influence the buoyancy of proto-kimberlite melt
relative to surrounding materials, they quantified for the first time what
it takes to erupt a kimberlite.
Diamonds make it to the surface in kimberlites because their rapid ascent
prevents them from reverting to graphite, which is more stable at shallow
pressures and temperatures. But the composition of the kimberlite’s original
melt—and how it rises so fast—has remained mysterious.
“They start off as something that we cannot measure directly,” says
Anzulović. “So we don’t know what a proto-kimberlite, or parental, melt
would be like. We know approximately but everything we know basically comes
from the very altered rocks that get emplaced.”
To constrain the composition of these parental melts, the team focused on
the Jericho kimberlite, which erupted into the Slave craton of far northwest
Canada. Using chemical modelling, they tested different original mixtures of
carbon dioxide and water.
“Our idea was, well, let’s try to create a chemical model of a kimberlite,
then vary CO2 and H2O,” says Anzulović. “Think of it
as trying to sample a kimberlite as it ascends at different pressure and
temperature points.”
The researchers used molecular dynamics software to simulate atomic forces
and track how atoms in a kimberlite melt move under varying depths. From
these calculations, they determined the density of the melt at different
conditions and whether it remained buoyant enough to rise.
“The most important takeaway from this study is that we managed to constrain
the amount of CO2 that you need in the Jericho kimberlite to
successfully ascend through the Slave craton,” Anzulović says. “Our most
volatile-rich composition can carry up to 44% of mantle peridotite, for
example, to the surface, which is really an impressive number for such a low
viscosity melt.”
The study also shows how volatiles play distinct roles. Water increases
diffusivity, keeping the melt fluid and mobile. Carbon dioxide helps
structure the melt at high pressures but, near the surface, it degasses and
drives the eruption upward. For the first time, researchers demonstrated
that the Jericho kimberlite needs at least 8.2% CO2 to erupt;
without it, diamonds would remain locked in the mantle.
“I was actually pretty surprised that I can take such a small scale system
and actually observe, ‘Okay, if I don’t put any carbon in, this melt will be
denser than the craton, so this will not erupt,’” says Anzulović. “It’s
great that modeling kimberlite chemistry can have implications for such a
large-scale process.”
FEATURED ARTICLE
ABuoyancy of volatile-rich kimberlite melts, magma ascent, and xenolith transport
Ana Anzulović, Anne H. Davis, Carmen Gaina, and Razvan Caracas
Contact: Ana Anzulović, University of Oslo, anaanz@uio.no
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About the Geological Society of America
The Geological Society of America (GSA) is a global professional society with more than 17,000 members across over 100 countries. As a leading voice for the geosciences, GSA advances the understanding of Earth's dynamic processes and fosters collaboration among scientists, educators, and policymakers. GSA publishes Geology, the top-ranked geoscience journal, along with a diverse portfolio of scholarly journals, books, and conference proceedings—several of which rank among Amazon's top 100 best-selling geology titles.
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