Moon’s Crust Underwent Resurfacing
After Forming fromMagma
Ocean
After Forming from
University of Texas
A research team led by The University of Texas at Austin Jackson School of
Geosciences took to the lab to recreate the magmatic melt that once formed the
lunar surface and uncovered new insights on how the modern moonscape came to
be. Their study shows that the Moon’s crust initially formed from rock floating
to the surface of the magma ocean and cooling. However, the team also found
that one of the great mysteries of the lunar body’s formation – how it could
develop a crust composed largely of just one mineral – cannot be explained by
the initial crust formation and must have been the result of some secondary
event.
The results were published on Nov. 21 in Geophysical Research Letters.
“It’s fascinating to me that there could be a body as big as the Moon that
was completely molten,” said Nick Dygert, an assistant professor at the University of Tennessee ,
Knoxville who led the research while a postdoctoral
researcher in the Jackson
School
Dygert collaborated with Jackson School Associate Professor Jung-Fu Lin,
Professor James Gardner and Ph.D. student Edward Marshall, as well as Yoshio
Kono, a beamline scientist at the Geophysical Laboratory at the Carnegie
Institution of Washington.
Large portions of the Moon’s crust are made up almost entirely of a single
mineral. In these sections, 98 percent of the crust is plagioclase. According
to the prevailing theory, which this study calls into question, the purity is
due to plagioclase floating to the surface of the magma ocean over hundreds of
millions of years and solidifying into the Moon’s crust. This theory hinges on
the magma ocean having a specific viscosity, a term related to the magma’s
“gooiness,” that would allow plagioclase to separate from other dense minerals
it crystallized with and rise to the top.
Dygert decided to test the plausibility of the theory by measuring the
viscosity of lunar magma directly. The feat involved using a high-pressure
apparatus called a synchrotron to shoot a concentrated beam of high-energy
X-rays into a sample of mineral powders and flash melting them into magma. The
researchers then measured the time it took for a melt-resistant sphere to sink
through the magma.
“Previously, there had not been any laboratory data to support models,”
said Lin. “So this is really the first time we have reliable laboratory
experimental results to understand how the Moon’s crust and interior formed.”
The experiment found that the magma melt had a very low viscosity,
somewhere between that of olive oil and corn syrup at room temperature, a value
that would have supported plagioclase flotation. However, it would have also
led to mixing of plagioclase with the magma, a process that would trap other
minerals in between the plagioclase crystals, creating an impure crust on the
lunar surface. Because satellite-based investigations demonstrate that a
significant portion of the crust on the Moon’s surface is pure, a secondary process
must have resurfaced the Moon, exposing a deeper, younger, purer layer of
crust. Dygert said the results support a “crustal overturn” on the lunar
surface where the old mixed crust was replaced with young, buoyant, hot
deposits of pure plagioclase. The older crust could have also been eroded away
by asteroids slamming into the Moon’s surface.
Dygert said the study’s results exemplify how small-scale experiments can
lead to large-scale understanding of geological processes that build planetary
bodies in our solar system and others.
“I view the Moon as a planetary lab,” Dygert said. “It’s so small that it
cooled quickly, and there’s no atmosphere or plate tectonics to wipe out the
earliest processes of planetary evolution. The concepts described here could be
applicable to just about any planet.”
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