Collisional and dynamical evolution of the main belt and NEA population

Aims.In this paper, we analyze the collisional evolution of the Main Belt and NEA population taking into account the major dynamical features present in both populations. Methods.To do this, we divide the asteroid belt into three semimajor axis zones, whose boundaries are given by the $\nu_{6}$ secu...

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Published inAstronomy and astrophysics (Berlin) Vol. 466; no. 3; pp. 1159 - 1177
Main Authors de Elía, G. C., Brunini, A.
Format Journal Article
LanguageEnglish
Published Les Ulis EDP Sciences 01.05.2007
Subjects
asteroids
Astronomy
Earth, ocean, space
Exact sciences and technology
methods: N-body simulations
methods: numerical
minor planets
solar system: formation
methods: N-body simulations
minor planets, asteroids
solar system: formation
Digital simulation
N body system
Numerical method
methods: numerical
Jupiter planet
Cosmic radiation
Mass transfer
Secular resonance
Meteorites
Dynamical evolution
Asteroids
Models
Solar system
Asteroid belt
Age
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Summary:Aims.In this paper, we analyze the collisional evolution of the Main Belt and NEA population taking into account the major dynamical features present in both populations. Methods.To do this, we divide the asteroid belt into three semimajor axis zones, whose boundaries are given by the $\nu_{6}$ secular resonance, and the 3:1, 5:2 and 2:1 mean motion resonances with Jupiter, treating them as strong sources of dynamical removal. We also consider the action of the Yarkovsky effect and diffusive resonances as mechanisms of mass depletion. This treatment allows us to calculate the direct collisional injection into the powerful resonances, to study the collisional exchange of mass between the different regions of the Main Belt and to analyze the provenance of the NEA objects. Results.Our model is in agreement with the major observational constraints associated with the Main Belt and NEA populations, such as their size distributions, the collisional history of Vesta, the number of large asteroid families and the cosmic-ray exposure (CRE) ages of meteorites. We find that none of the dynamical and collisional mechanisms included in our treatment are able to mix material between the three studied main belt regions, since more than 99% of the final mass of every ring of our model of the Main Belt is represented by primordial material. In addition, our results supports that the Yarkovsky effect is the most important process that removes material from the asteroid Main Belt, rather than collisional injection into the major resonances. With regards to the provenance of the NEAs, our work shows that ~94% of the NEA population comes from the region inside the 5:2 mean motion resonance.
Bibliography:istex:6E3B98D916445D81ABA10551236E1BC4D54A144B
publisher-ID:aa6046-06
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other:2007A%26A...466.1159D
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content type line 23
ISSN:0004-6361
1432-0746
DOI:10.1051/0004-6361:20066046