Washington: The protoplanet Vesta has been witness to an eventful past - images taken by the framing camera onboard NASA’s space probe Dawn show two enormous craters in the southern hemisphere.
The images were obtained during Dawn’s year-long visit to Vesta that ended in September 2012.
These huge impacts not only altered Vesta’s shape, but also its surface composition. Scientists under the lead of the Max Planck Institute for Solar System Research (MPS) in Germany have shown that impacting small asteroids delivered dark, carbonaceous material to the protoplanet.
In the early days of our solar system, similar events may have provided the inner planets such as Earth with carbon, an essential building block for organic molecules.
Vesta is remarkable in many respects. With a diameter of approximately 530 kilometres, Vesta is the one of the few protoplanets in our solar system still intact today. Like other protoplanets, Vesta underwent complete melting approximately 4.5 billion years ago.
However, most of the volcanic activity on Vesta is thought to have ceased within a few million years, making it a time capsule from the early solar system. Dawn observations of Vesta have shown a surface with diverse brightness variations and surface composition.
There is bright material on Vesta that is as white as snow and dark material on Vesta as black as coal.
The enigmatic dark material holds the key to understanding the impact environment around Vesta early in its evolution. Research led by scientists at the MPS has shown that this dark material is not native to Vesta but was delivered by impacting asteroids.
“The evidence suggests that the dark material on Vesta is rich in carbonaceous material and was brought there by collisions with smaller asteroids,” Prof. Dr. Vishnu Reddy, lead author of the paper from the University of North Dakota, said.
In the new study, he and his colleagues now present the most comprehensive analysis of this material so far. Compositional analysis, mapping, and modelling of dark material distribution on Vesta suggest that it was delivered during the formation of giant impact basins on Vesta.
“First, we created a map showing the distribution of dark material on Vesta using the framing camera data and found something remarkable,” Dr. Lucille Le Corre from the MPS, one of the lead authors of the study, said.
Dark material was preferentially spread around the edges of the giant impact basins in the southern hemisphere of Vesta suggesting a link to one of the two large impact basins.
A closer examination showed that the dark material was most probably delivered during the formation of the older Veneneia basin when a slow impacting asteroid collided with Vesta. Dark material from this two to three billion year old basin was covered up by the impact that subsequently created the Rheasilvia basin.
“We believe that the Veneneia basin was created by the first of two impacts two to three billion years ago,” Reddy said.
In fact, impact modelling presented in the paper reproduces the distribution of dark material from such a low velocity impact.
Evidence for dark material is also found in the HED meteorites that come from Vesta. Some of the meteorites show dark inclusions that are carbon-rich. Colour spectra of dark material on Vesta are identical to these carbon-rich inclusions in HED meteorites.
The link between dark material on Vesta and dark clasts in HED meteorites provides us with direct evidence that these meteorites are indeed from Vesta.
“Our analysis of the dark material on Vesta and comparisons with laboratory studies of HED meteorites for the first time proves directly that these meteorites are fragments from Vesta,” Le Corre added.
The study has been published in the journal Icarus.
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