.jpeg) |
Artist's impression of the trio of
super-Earths discovered by an European team using the HARPS
spectrograph on ESO's 3.6-m telescope at La Silla, Chile, after 5
years of monitoring. The three planets, having 4.2, 6.7, and 9.4
times the mass of the Earth, orbit the star HD 40307 with periods of
4.3, 9.6, and 20.4 days, respectively. Credit: ESO
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The mantles of Earth and other rocky
planets are rich in magnesium and oxygen. Due to its simplicity, the
mineral magnesium oxide is a good model for studying the nature of
planetary interiors. New work from a team led by Carnegie's Stewart
McWilliams studied how magnesium oxide behaves under the extreme
conditions deep within planets and found evidence that alters our
understanding of planetary evolution. It is published November 22
by Science Express.
McWilliams and his team observed
magnesium oxide between pressures of about 3 million times normal
atmospheric pressure (0.3 terapascals) to 14 million times
atmospheric pressure (1.4 terapascals) and at temperatures reaching
as high as 90,000 degrees Fahrenheit (50,000 Kelvin), conditions that
range from those at the center of our Earth to those of large
exo-planet super-Earths. Their observations indicate substantial
changes in molecular bonding as the magnesium oxide responds to these
various conditions, including a transformation to a new high-pressure
solid phase.
In fact, when melting, there are signs
that magnesium oxide changes from an electrically insulating material
like quartz (meaning that electrons do not flow easily) to a metal
similar to iron (meaning that electrons do flow easily through the
material).
Drawing from these and other recent
observations, the team concluded that while magnesium oxide is solid
and non-conductive under conditions found on Earth in the present
day, the early Earth's magma ocean might have been able to generate a
magnetic field. Likewise, the metallic, liquid phase of magnesium
oxide can exist today in the deep mantles of super-Earth planets, as
can the newly observed solid phase.
"Our findings blur the line
between traditional definitions of mantle and core material and
provide a path for understanding how young or hot planets can
generate and sustain magnetic fields," McWilliams said.
"This pioneering study takes
advantage of new laser techniques to explore the nature of the
materials that comprise the wide array of planets being discovered
outside of our Solar System," said Russell Hemley, director of
Carnegie's Geophysical Laboratory. "These methods allow
investigations of the behavior of these materials at pressures and
temperatures never before explored experimentally."
The experiments were carried out at the
Omega Laser Facility of the University of Rochester, which is
supported by DOE/NASA. The research involved a team of scientists
from University of California Berkley and Lawrence Livermore National
Laboratory.
This work was supported by the
Department of Energy, the U.S. Army Research Office, A Krell
Institute graduate fellowship, the DOE/NNSA National Laser User
Facility Program, the Miller Institute for Basic Research in Science,
and the University of California.
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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