The Borealis basin and the origin of the martian crustal dichotomy

Cosmic cataclysms: An impact origin for the Mars dichotomy A 'near Mars object' that got too near is a possible explanation for one of the most prominent features we see on Mars — the north-south dichotomy of the planet's surface appearance. The southern highlands on Mars cover about...

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Bibliographic Details
Published in:Nature 2008-06, Vol.453 (7199), p.1212-1215
Main Authors: Andrews-Hanna, Jeffrey C., Zuber, Maria T., Banerdt, W. Bruce
Format: Article
Language:English
Subjects:
Compensation
Cosmochemistry. Extraterrestrial geology
Crust
Earth
Earth sciences
Earth, ocean, space
Exact sciences and technology
Extraterrestrial geology
Gravity
Humanities and Social Sciences
letter
Mars
Mars (Planet)
multidisciplinary
Planets
Properties
Science
Science (multidisciplinary)
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Summary:Cosmic cataclysms: An impact origin for the Mars dichotomy A 'near Mars object' that got too near is a possible explanation for one of the most prominent features we see on Mars — the north-south dichotomy of the planet's surface appearance. The southern highlands on Mars cover about 60% of the planet and are heavily cratered, while the northern lowlands are lightly cratered, are geologically younger, and the underlying crust is significantly thinner than in the south. The two favoured explanations for this 'hemispheric dichotomy' are mantle convection and a giant impact, but there is little available evidence to distinguish between the theories. Three Letters in this issue provide support for the giant impact model. Marinova et al . present the results of dynamical simulations of dichotomy-forming impacts that demonstrate the feasibility of a giant impact origin. Andrews-Hanna et al . use the gravity and topography of Mars to map the dichotomy boundary beneath the large Tharsis volcanic province, and find the boundary to be elliptical, consistent with an oblique giant impact origin. This 'Borealis basin' would be the largest impact scar in the Solar System. Nimmo et al . use numerical modelling to simulate the effects of vertical impacts. They find that the impact model, as well as excavating a crustal cavity of the correct size, can explain the observed crustal disruption and the formation of the northern lowlands crust by impact-generated melt. The hemispheric dichotomy between the southern highlands and northern lowlands on Mars is characterized by a change in crustal thickness along an apparently irregular boundary, which can be traced around the planet, except where it is presumably buried beneath the Tharsis volcanic rise. The gravity and topography of Mars is used to constrain the location of the dichotomy boundary beneath Tharsis, and finds that the dichotomy boundary along its entire path around the planet is accurately fit by an ellipse measuring about 10,600 by 8,500 km. The most prominent feature on the surface of Mars is the near-hemispheric dichotomy between the southern highlands and northern lowlands. The root of this dichotomy is a change in crustal thickness along an apparently irregular boundary, which can be traced around the planet, except where it is presumably buried beneath the Tharsis volcanic rise 1 , 2 . The isostatic compensation of these distinct provinces 2 , 3 and the ancient population of impact craters buried beneath the y
ISSN:0028-0836
1476-4687
1476-4679
DOI:10.1038/nature07011