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Asteroid Vesta to reshape theories of planet formation

If Vesta has less of an olivine-rich mantle and more of a pyroxene-rich crust, then the proportion of materials making up Vesta, and probably Earth and other telluric planets, is different from what was previously expected.
RELATED TOPICS: SOLAR SYSTEM | VESTA
Asteroid Vesta
EPFL/Jamani Caillet, Harold Clenet
Ecole Polytechnique Federale de Lausanne (EPFL) researchers have a better understanding of the asteroid Vesta and its internal structure, thanks to numerical simulations and data from the space mission Dawn. Their findings question contemporary models of rocky planet formation, including that of Earth.

With its 300-mile (500 kilometers) diameter, the asteroid Vesta is one of the largest known planet embryos. It came into existence at the same time as the solar system. Spurring scientific interest, NASA sent the Dawn spacecraft on Vesta’s orbit for one year between July 2011 and July 2012.

A team of researchers from EPFL as well as the University of Bern in Brittany, France, and the University of Arizona analyzed data gathered by Dawn. Conclusion: The asteroid’s crust is almost three times thicker than expected. Not only does the study have implications for the structure of this celestial object located between Mars and Jupiter, but their results also challenge a fundamental component in planet formation models, namely the composition of the original cloud of matter that aggregated together, heated, melted, and then crystallized to form planets.

At EPFL’s Earth and Planetary Science Laboratory (EPSL), which is led by Philippe Gillet, Harold Clenet had a look at the composition of the rocks scattered across Vesta’s ground. “What is striking is the absence of a particular mineral, olivine, on the asteroid’s surface,” said Clenet. Olivine is a main component of planetary mantles and should have been found in large quantities on the surface of Vesta, due to a double meteorite impact that, according to computer simulations, “dug” the celestial body’s southern pole to a depth of 50 miles (80km), catapulting large amounts of materials to the surface.

The two impacts were so powerful that more than 5 percent of Earth’s meteorites come from Vesta. “But these cataclysms were not strong enough to pierce through the crust and reach the asteroid’s mantle,” Clenet said. The meteorites originating from Vesta and found on Earth confirm this since they generally lack olivine or contain only minute amounts compared to the amount observed in planetary mantles. Also, the spacecraft Dawn did not find olivine in the vicinity of the two impact craters. “ This means that the crust of the asteroid is not 30km [19 miles] thick, as suggested by the models, but more than 80km [50 miles].“

Composition of planets
These discoveries challenge models that describe the formation of Vesta, and consequently the formation of rocky planets in the solar system, including Earth. Cooling theory and “re- melting” phenomena in the depths of previously solidified elements also would need to be reviewed. “The crust might have been thickened by the formation of ‘plutons,’ that is, igneous rock intrusions, hundreds of meters large, some of which emerged to the surface,” said Clenet.

If Vesta has less of an olivine-rich mantle and more of a pyroxene-rich crust, then the proportion of materials making up Vesta, and probably Earth and other telluric planets — Mars, Venus, Mercury — is different from what was previously expected.

A more complex model of planet formation therefore has to be considered, one that takes into account not only the original composition of planets, but also their orbits, sizes, and related cooling times. Vesta is the only known asteroid that has an Earth-like structure — with a core, mantle, and crust — making it an incredible laboratory for testing hypotheses and theories.
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