The Violent Collisional History of Asteroid 4 Vesta
A New Dawn
Since 17 July 2011, NASA's spacecraft Dawn has been orbiting the asteroid Vesta—the second most massive and the third largest asteroid in the solar system (see the cover). Russell et al. (p. 684) use Dawn's observations to confirm that Vesta is a small differentiated planetary body with an inner core, and represents a surviving proto-planet from the earliest epoch of solar system formation; Vesta is also confirmed as the source of the howardite-eucrite-diogenite (HED) meteorites. Jaumann et al. (p. 687) report on the asteroid's overall geometry and topography, based on global surface mapping. Vesta's surface is dominated by numerous impact craters and large troughs around the equatorial region. Marchi et al. (p. 690) report on Vesta's complex cratering history and constrain the age of some of its major regions based on crater counts. Schenk et al. (p. 694) describe two giant impact basins located at the asteroid's south pole. Both basins are young and excavated enough amounts of material to form the Vestoids—a group of asteroids with a composition similar to that of Vesta—and HED meteorites. De Sanctis et al. (p. 697) present the mineralogical characterization of Vesta, based on data obtained by Dawn's visual and infrared spectrometer, revealing that this asteroid underwent a complex magmatic evolution that led to a differentiated crust and mantle. The global color variations detailed by Reddy et al. (p. 700) are unlike those of any other asteroid observed so far and are also indicative of a preserved, differentiated proto-planet.
Abstract
Vesta is a large differentiated rocky body in the main asteroid belt that accreted within the first few million years after the formation of the earliest solar system solids. The Dawn spacecraft extensively imaged Vesta’s surface, revealing a collision-dominated history. Results show that Vesta’s cratering record has a strong north-south dichotomy. Vesta’s northern heavily cratered terrains retain much of their earliest history. The southern hemisphere was reset, however, by two major collisions in more recent times. We estimate that the youngest of these impact structures, about 500 kilometers across, formed about 1 billion years ago, in agreement with estimates of Vesta asteroid family age based on dynamical and collisional constraints, supporting the notion that the Vesta asteroid family was formed during this event.
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References and Notes
1
Wetherill G. W., An alternative model for the formation of the asteroids. Icarus 100, 307 (1992).
2
Bottke W. F., et al., Linking the collisional history of the main asteroid belt to its dynamical excitation and depletion. Icarus 179, 63 (2005).
3
O’Brien D. P., Morbidelli A., Bottke W. F., The primordial excitation and clearing of the asteroid belt—revisited. Icarus 191, 434 (2007).
4
Morbidelli A., Brasser R., Gomes R., Levison H. F., Tsiganis K., Evidence from the asteroid belt for a violent past evolution of Jupiter’s orbit. Astron. J. 140, 1391 (2010).
5
Turrini D., Magni G., Coradini A., Probing the history of solar system through the cratering records on Vesta and Ceres. Mon. Not. R. Astron. Soc. 413, 2439 (2011).
6
Russell C. T., et al., Dawn at Vesta: Testing the protoplanetary paradigm. Science 336, 684 (2012).
7
Jaumann R., et al., Vesta’s shape and morphology. Science 336, 687 (2012).
8
Thomas P. C., et al., Impact excavation on asteroid 4 Vesta: Hubble Space Telescope results. Science 277, 1492 (1997).
9
Schenk P., et al., The geologically recent giant impact basins at Vesta’s south pole. Science 336, 694 (2012).
10
Nesvorný D., et al., Fugitives from the Vesta family. Icarus 193, 85 (2008).
11
McCord T. B., Adams J. B., Johnson T. V., Asteroid vesta: Spectral reflectivity and compositional implications. Science 168, 1445 (1970).
12
Burbine T. H., et al., Vesta, Vestoids, and the howardite, eucrite, diogenite group: Relationships and the origin of spectral differences. Meteorit. Planet. Sci. 36, 761 (2001).
13
McSween H. Y., Mittlefehldt D. W., Beck A. W., Mayne R. G., McCoy T. J., HED meteorites and their relationship to the geology of Vesta and the Dawn mission. Space Sci. Rev. 163, 141 (2011).
14
De Sanctis M. C., et al., Spectral and mineralogical characterization of inner main-belt V-type asteroids. Astron. Astrophys. 533, A77 (2011).
15
It is also possible that a part of the Vestoids and HED meteorites have been originated by the older 400-km basin underneath Rheasilvia.
16
Methods and additional data are available as supplementary materials on Science Online.
17
Gault D. E., Saturation and equilibrium conditions for impact cratering on the lunar surface: Criteria and implications. Radio Sci. 5, 273 (1970).
18
H. J. Melosh, Oxford Monographs on Geology and Geophysics, no. 11 (Clarendon Press, Oxford, 1989).
19
The slope of a cumulative crater size-frequency distribution is defined by Δlog(N)/Δlog(D), where N is the cumulative number of craters and D is the crater size.
20
Jutzi M., Asphaug E., Mega-ejecta on asteroid Vesta. J. Geophys. Res. 38, L01102 (2011).
21
Note that this region excludes the floor of the large basin underneath Rheasilvia, and it extends for about 10° to 15° degrees northward starting from Rheasilvia’s rim.
22
Bierhaus E. B., Dones L., Alvarellos J. L., Zahnle K., The role of ejecta in the small crater populations on the mid-sized saturnian satellites. Icarus 218, 602 (2012).
23
Holsapple K. A., Housen K. R., A crater and its ejecta: An interpretation of Deep Impact. Icarus 187, 345 (2007).
24
Marchi S., et al., The cratering history of asteroid (2867) Steins. Planet. Space Sci. 58, 1116 (2010).
25
Marchi S., et al., http://arXiv.org/abs/1111.3628 (2011).
26
Farinella P., Davis D. R., Collision rates and impact velocities in the main asteroid belt. Icarus 97, 111 (1992).
27
Intrinsic collisional probabilities among asteroids are computed by analytical means using the orbital distribution of asteroids >10 km (25). The main source of uncertainty in the age-estimation process, which is considered in the final error estimate, is due to the lack of detailed knowledge of the impactor size-frequency distribution.
28
The estimated size of the impactor that produced Rheasilvia is ~50 km or larger [e.g., (20)], resulting in an impact every ~16 Gy, according to the present main-belt impact rate. The knowledge that the event did happen in 4.5 Gy implies a 25% probability of occurrence in the past 1 Gy.
29
Marzari F., et al., Origin and evolution of the Vesta asteroid family. Astron. Astrophys. 316, 248 (1996).
30
De Sanctis M. C., et al., Spectroscopic characterization of mineralogy and its diversity across Vesta. Science 336, 697 (2012).
31
Morbidelli A., Bottke W. F., Nesvorny D., Levison H. F., Asteroids were born big. Icarus 204, 558 (2009).
32
Kring D. A., The dimensions of the Chicxulub impact crater and impact melt sheet. J. Geophys. Res. 100, 16979 (1995).
33
Schultz P. H., Gault D. E., Seismic effects from major basin formations on the moon and mercury. Moon 12, 159 (1975).
34
Woronow A., A Monte Carlo study of parameters affecting computer simulations of crater saturation density. J. Geophys. Res. 90, 817 (1985).
35
G. Neukum, B. A. Ivanov, in Hazards Due to Comets and Asteroids, T. Gehrels, Ed. (Univ. of Arizona Press, Tuscon, AZ, 1994), p. 359.
36
Chapman C. R., Cratering on asteroids from Galileo and NEAR Shoemaker. Asteroids III, 315 (2002).
37
Richardson J. E., Cratering saturation and equilibrium: A new model looks at an old problem. Icarus 204, 697 (2009).
38
W. F. Bottke, C. R. Chapman, Determining the main belt size distribution using asteroid crater records and crater saturation models, abstract no. 1349, 37th Annual Lunar and Planetary Science Conference, League City, TX, 13 to 17 March, 2006.
39
Marchi S., Bottke W. F., Kring D. A., Morbidelli A., The onset of the lunar cataclysm as recorded in its ancient crater populations. Earth Planet. Sci. Lett. 325, 27 (2012).
40
Head J. W., et al., Global distribution of large lunar craters: Implications for resurfacing and impactor populations. Science 329, 1504 (2010).
41
Gladman B. J., et al., On the asteroid belt’s orbital and size distribution. Icarus 202, 104 (2009).
42
O’Brien D. P., Sykes M. V., The origin and evolution of the asteroid belt—implications for Vesta and Ceres. Space Sci. Rev. 163, 41 (2011).
43
D. Nesvorny, Nesvorny HCM Asteroid Families V1.0, EAR-A-VARGBDET-5-NESVORNYFAM- V1.0, NASA Planetary Data System, 2010.
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Science
Volume 336 | Issue 6082
11 May 2012
11 May 2012
Copyright
Copyright © 2012, American Association for the Advancement of Science.
Submission history
Received: 5 January 2012
Accepted: 16 April 2012
Published in print: 11 May 2012
Acknowledgments
We thank the Dawn Science, Instrument, and Operations Teams for support. This work was supported by the Italian Space Agency and NASA’s Dawn at Vesta Participating Scientists Program. A portion of this work was performed at the Jet Propulsion Laboratory, California Institute of Technology, under contract with NASA. S. Marchi thanks Istituto Nazionale d’Astrofisica for the support in carrying on this work.
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