Your search keyword '"Morbidelli, Alessandro"' showing total 39 results

1. Late Heavy Bombardment

Author

Morbidelli, Alessandro, Claeys, Philippe, Gargaud, Muriel, editor, Irvine, William M., editor, Amils, Ricardo, editor, Claeys, Philippe, editor, Cleaves, Henderson James, editor, Gerin, Maryvonne, editor, Rouan, Daniel, editor, Spohn, Tilman, editor, Tirard, Stéphane, editor, and Viso, Michel, editor

Published

2023

2. Dynamical Spreading of Asteroid Families by the Yarkovsky Effect

Author

Bottke, William F., Vokrouhlický, David, Brož, Miroslav, Nesvorný, David, and Morbidelli, Alessandro

Published

2001

3. Understanding the Distribution of Near-Earth Asteroids

Author

Bottke, William F., Jedicke, Robert, Morbidelli, Alessandro, Petit, Jean-Marc, and Gladman, Brett

Published

2000

4. Late Heavy Bombardment

Author

Claeys, Philippe, Morbidelli, Alessandro, Gargaud, Muriel, editor, Irvine, William M., editor, Amils, Ricardo, editor, Cleaves, Henderson James (Jim), II, editor, Pinti, Daniele L., editor, Quintanilla, José Cernicharo, editor, Rouan, Daniel, editor, Spohn, Tilman, editor, Tirard, Stéphane, editor, and Viso, Michel, editor

Published

2015

5. Origin of Multikilometer Earth-and Mars-Crossing Asteroids: A Quantitative Simulation

Author

Migliorini, Fabio, Michel, Patrick, Morbidelli, Alessandro, Nesvorný, David, and Zappalà, Vincenzo

Published

1998

6. A Unique Basaltic Micrometeorite Expands the Inventory of Solar System Planetary Crusts

Author

Gounelle, Matthieu, Chaussidon, Marc, Morbidelli, Alessandro, Barrat, Jean-Alix, Engrand, Cécile, Zolensky, Michael E., McKeegan, Kevin D., and Thiemens, Mark H.

Published

2009

7. The Nekhoroshev Theorem and the Asteroid Belt Dynamical System

Author

Morbidelli, Alessandro, Guzzo, Massimiliano, Dvorak, R., editor, and Henrard, J., editor

Published

1997

8. Trojans’ Odyssey: Unveiling the early history of the Solar System

Author

Lamy, Philippe, Vernazza, Pierre, Poncy, Joel, Martinot, Vincent, Hinglais, Emmanuel, Canalias, Elisabet, Bell, Jim, Cruikshank, Dale, Groussin, Olivier, Helbert, Joern, Marzari, Francesco, Morbidelli, Alessandro, Rosenblatt, Pascal, and Sierks, Holger

Published

2012

9. Construction of a Nekhoroshev like result for the asteroid belt dynamical system

Author

Guzzo, Massimilliano and Morbidelli, Alessandro

Published

1996

10. The nekhoroshev theorem and the asteroid belt dynamical system

Author

Morbidelli, Alessandro and Guzzo, Massimiliano

Published

1996

11. Proper elements for highly inclined asteroidal orbits

Author

Lemaitre, Anne and Morbidelli, Alessandro

Published

1994

12. Evolution of the Earth's atmosphere during Late Veneer accretion.

Author

Sinclair, Catriona A, Wyatt, Mark C, Morbidelli, Alessandro, and Nesvorný, David

Subjects

ATMOSPHERE, PLANETESIMALS, EARTH currents, INNER planets, ORIGIN of planets, SOLAR system, ASTEROIDS

Abstract

Recent advances in our understanding of the dynamical history of the Solar system have altered the inferred bombardment history of the Earth during accretion of the Late Veneer, after the Moon-forming impact. We investigate how the bombardment by planetesimals left-over from the terrestrial planet region after terrestrial planet formation, as well as asteroids and comets, affects the evolution of Earth's early atmosphere. We develop a new statistical code of stochastic bombardment for atmosphere evolution, combining prescriptions for atmosphere loss and volatile delivery derived from hydrodynamic simulations and theory with results from dynamical modelling of realistic populations of impactors. We find that for an initially Earth-like atmosphere, impacts cause moderate atmospheric erosion with stochastic delivery of large asteroids, giving substantial growth (× 10) in a few |${{\ \rm per\ cent}}$| of cases. The exact change in atmosphere mass is inherently stochastic and dependent on the dynamics of the left-over planetesimals. We also consider the dependence on unknowns including the impactor volatile content, finding that the atmosphere is typically completely stripped by especially dry left-over planetesimals (⁠|$\lt 0.02 ~ {{\ \rm per\ cent}}$| volatiles). Remarkably, for a wide range of initial atmosphere masses and compositions, the atmosphere converges towards similar final masses and compositions, i.e. initially low-mass atmospheres grow, whereas massive atmospheres deplete. While the final properties are sensitive to the assumed impactor properties, the resulting atmosphere mass is close to that of current Earth. The exception to this is that a large initial atmosphere cannot be eroded to the current mass unless the atmosphere was initially primordial in composition. [ABSTRACT FROM AUTHOR]

Published

2020

13. Chemical diversity of super-Earths as a consequence of formation.

Author

Scora, Jennifer, Valencia, Diana, Morbidelli, Alessandro, and Jacobson, Seth

Subjects

ASTEROIDS, SOLAR system, ORIGIN of planets, PLANETS

Abstract

Recent observations of rocky super-Earths have revealed an apparent wider distribution of Fe/Mg ratios, or core to mantle ratios, than the planets in our Solar system. This study aims to understand how much of the chemical diversity in the super-Earth population can arise from giant impacts during planetary formation. Planet formation simulations have only recently begun to treat collisions more realistically in an attempt to replicate the planets in our Solar system. We investigate planet formation more generally by simulating the formation of rocky super-Earths with varying initial conditions using a version of symb a , a gravitational N -body code, that incorporates realistic collisions. We track the maximum plausible change in composition after each impact. The final planets span a range of Fe/Mg ratios similar to the Solar system planets, but do not completely match the distribution in super-Earth data. We only form a few planets with minor iron-depletion, suggesting other mechanisms are at work. The most iron-rich planets have a lower Fe/Mg ratio than Mercury, and are less enriched than planets such as Kepler-100b. This indicates that further work on our understanding of planet formation and further improvement of precision of mass and radius measurements are required to explain planets at the extremes of this Fe/Mg distribution. [ABSTRACT FROM AUTHOR]

Published

2020

14. Debiased orbit and absolute-magnitude distributions for near-Earth objects.

Author

Granvik, Mikael, Morbidelli, Alessandro, Jedicke, Robert, Bolin, Bryce, Bottke, William F., Beshore, Edward, Vokrouhlický, David, Nesvorný, David, and Michel, Patrick

Subjects

*NEAR-Earth objects, *COMETS, *ASTEROIDS, *CHELYABINSK meteorite, *MICROBALANCES

Abstract

The debiased absolute-magnitude and orbit distributions as well as source regions for near-Earth objects (NEOs) provide a fundamental frame of reference for studies of individual NEOs and more complex population-level questions. We present a new four-dimensional model of the NEO population that describes debiased steady-state distributions of semimajor axis, eccentricity, inclination, and absolute magnitude H in the range 17 <  H  < 25. The modeling approach improves upon the methodology originally developed by Bottke et al. (2000, Science 288, 2190–2194) in that it is, for example, based on more realistic orbit distributions and uses source-specific absolute-magnitude distributions that allow for a power-law slope that varies with H . We divide the main asteroid belt into six different entrance routes or regions (ER) to the NEO region: the ν 6 , 3:1J, 5:2J and 2:1J resonance complexes as well as Hungarias and Phocaeas. In addition we include the Jupiter-family comets as the primary cometary source of NEOs. We calibrate the model against NEO detections by Catalina Sky Surveys’ stations 703 and G96 during 2005–2012, and utilize the complementary nature of these two systems to quantify the systematic uncertainties associated to the resulting model. We find that the (fitted) H distributions have significant differences, although most of them show a minimum power-law slope at H  ∼ 20. As a consequence of the differences between the ER-specific H distributions we find significant variations in, for example, the NEO orbit distribution, average lifetime, and the relative contribution of different ERs as a function of H . The most important ERs are the ν 6 and 3:1J resonance complexes with JFCs contributing a few percent of NEOs on average. A significant contribution from the Hungaria group leads to notable changes compared to the predictions by Bottke et al. in, for example, the orbit distribution and average lifetime of NEOs. We predict that there are 962 − 56 + 52 ( 802 − 42 + 48 × 10 3 ) NEOs with H  < 17.75 ( H  < 25) and these numbers are in agreement with the most recent estimates found in the literature (the uncertainty estimates only account for the random component). Based on our model we find that relative shares between different NEO groups (Amor, Apollo, Aten, Atira, Vatira) are (39.4,54.4,3.5,1.2,0.3)%, respectively, for the considered H range and that these ratios have a negligible dependence on H . Finally, we find an agreement between our estimate for the rate of Earth impacts by NEOs and recent estimates in the literature, but there remains a potentially significant discrepancy in the frequency of Tunguska-sized and Chelyabinsk-sized impacts. [ABSTRACT FROM AUTHOR]

Published

2018

15. Initial velocity V-shapes of young asteroid families.

Author

Bolin, Bryce T., Walsh, Kevin J., Morbidelli, Alessandro, and Delbó, Marco

Subjects

ASTEROIDS, YARKOVSKY effect, CURVATURE, FLOW velocity, COMPUTER simulation

Abstract

Ejection velocity fields of asteroid families are largely unconstrained due to the fact that members disperse relatively quickly on Myr time-scales by secular resonances and the Yarkovsky effect. The spreading of fragments in a by the Yarkovsky effect is indistinguishable from the spreading caused by the initial ejection of fragments. By examining families <20 Myr old, we can use the V-shape identification technique to separate family shapes that are due to the initial ejection velocity field and those that are due to the Yarkovsky effect. Asteroid families that are <20 Myr old provide an opportunity to study the velocity field of family fragments before they become too dispersed. Only the Karin family's initial velocity field has been determined and scales inversely with diameter, D-1. We have applied the V-shape identification technique to constrain young families' initial ejection velocity fields by measuring the curvature of their fragments' V-shape correlation in semimajor axis, a, versus D-1 space. Curvature from a straight line implies a deviation from a scaling of D-1. We measure the V-shape curvature of 11 young asteroid families including the 1993 FY12, Aeolia, Brangane, Brasilia, Clarissa, Iannini, Karin, Konig, Koronis(2), Theobalda and Veritas asteroid families. We find that the majority of asteroid families have initial ejection velocity fields consistent with ~D-1 supporting laboratory impact experiments and computer simulations of disrupting asteroid parent bodies. [ABSTRACT FROM AUTHOR]

Published

2018

16. Extreme secular excitation of eccentricity inside mean motion resonance: Small bodies driven into star-grazing orbits by planetary perturbations.

Author

Pichierri, Gabriele, Morbidelli, Alessandro, and Lai, Dong

Subjects

*PLANETESIMALS, *GENERAL relativity (Physics), *ASTEROIDS, *CELESTIAL mechanics, *COMPUTER simulation

Abstract

Context. It is well known that asteroids and comets fall into the Sun. Metal pollution of white dwarfs and transient spectroscopic signatures of young stars like β-Pic provide growing evidence that extra solar planetesimals can attain extreme orbital eccentricities and fall into their parent stars. Aims.We aim to develop a general, implementable, semi-analytical theory of secular eccentricity excitation of small bodies (planetesimals) in mean motion resonances with an eccentric planet valid for arbitrary values of the eccentricities and including the short-range force due to General Relativity. Methods. Our semi-analytic model for the restricted planar three-body problem does not make use of series expansion and therefore is valid for any eccentricity value and semi-major axis ratio. The model is based on the application of the adiabatic principle, which is valid when the precession period of the longitude of pericentre of the planetesimal is much longer than the libration period in the mean motion resonance. In resonances of order larger than 1 this is true except for vanishingly small eccentricities. We provide prospective users with a Mathematica notebook with implementation of the model allowing direct use. Results. We confirm that the 4:1 mean motion resonance with a moderately eccentric (e' <≲ 0.1) planet is the most powerful one to lift the eccentricity of planetesimals from nearly circular orbits to star-grazing ones. However, if the planet is too eccentric, we find that this resonance is unable to pump the planetesimal's eccentricity to a very high value. The inclusion of the General Relativity effect imposes a condition on the mass of the planet to drive the planetesimals into star-grazing orbits. For a planetesimal at ~1 AU around a solar mass star (or white dwarf), we find a threshold planetary mass of about 17 Earth masses. We finally derive an analytical formula for this critical mass. Conclusions. Planetesimals can easily fall into the central star even in the presence of a single moderately eccentric planet, but only from the vicinity of the 4.1 mean motion resonance. For sufficiently high planetary masses the General Relativity effect does not prevent the achievement of star-grazing orbits. [ABSTRACT FROM AUTHOR]

Published

2017

17. Terrestrial planet formation constrained by Mars and the structure of the asteroid belt.

Author

Izidoro, André, Raymond, Sean N., Morbidelli, Alessandro, and Winter, Othon C.

Subjects

INNER planets, ASTEROIDS, MARS (Planet), PROTOPLANETARY disks, GRAVITATION, NUMERICAL analysis

Abstract

Reproducing the large Earth/Mars mass ratio requires a strong mass depletion in solids within the protoplanetary disc between 1 and 3 au. The Grand Tack model invokes a specific migration history of the giant planets to remove most of the mass initially beyond 1 au and to dynamically excite the asteroid belt. However, one could also invoke a steep density gradient created by inward drift and pile-up of small particles induced by gas drag, as has been proposed to explain the formation of close-in super-Earths. Here we show that the asteroid belt's orbital excitation provides a crucial constraint against this scenario for the Solar system. We performed a series of simulations of terrestrial planet formation and asteroid belt evolution starting from discs of planetesimals and planetary embryos with various radial density gradients and including Jupiter and Saturn on nearly circular and coplanar orbits. Discs with shallow density gradients reproduce the dynamical excitation of the asteroid belt by gravitational self-stirring but form Mars analogues significantly more massive than the real planet. In contrast, a disc with a surface density gradient proportional to r-5.5 reproduces the Earth/Mars mass ratio but leaves the asteroid belt in a dynamical state that is far colder than the real belt. We conclude that no disc profile can simultaneously explain the structure of the terrestrial planets and asteroid belt. The asteroid belt must have been depleted and dynamically excited by a different mechanism such as, for instance, in the Grand Tack scenario. [ABSTRACT FROM AUTHOR]

Published

2015

18. THE ABSOLUTE MAGNITUDE DISTRIBUTION OF KUIPER BELT OBJECTS.

Author

Fraser, Wesley C., Brown, Michael E., Morbidelli, Alessandro, Parker, Alex, and Batygin, Konstantin

Subjects

KUIPER belt, TRANS-Neptunian objects, ASTEROIDS, SOLAR system, CENTAUR objects

Abstract

Here we measure the absolute magnitude distributions (H-distribution) of the dynamically excited and quiescent (hot and cold) Kuiper Belt objects (KBOs), and test if they share the same H-distribution as the Jupiter Trojans. From a compilation of all useable ecliptic surveys, we find that the KBO H-distributions are well described by broken power laws. The cold population has a bright-end slope, , and break magnitude, (r′-band). The hot population has a shallower bright-end slope of, , and break magnitude . Both populations share similar faint-end slopes of α2 ∼ 0.2. We estimate the masses of the hot and cold populations are ∼0.01 and ∼3 × 10–4M⊕. The broken power-law fit to the Trojan H-distribution has α1 = 1.0 ± 0.2, α2 = 0.36 ± 0.01, and HB = 8.3. The Kolmogorov-Smirnov test reveals that the probability that the Trojans and cold KBOs share the same parent H-distribution is less than 1 in 1000. When the bimodal albedo distribution of the hot objects is accounted for, there is no evidence that the H-distributions of the Trojans and hot KBOs differ. Our findings are in agreement with the predictions of the Nice model in terms of both mass and H-distribution of the hot and Trojan populations. Wide-field survey data suggest that the brightest few hot objects, with , do not fall on the steep power-law slope of fainter hot objects. Under the standard hierarchical model of planetesimal formation, it is difficult to account for the similar break diameters of the hot and cold populations given the low mass of the cold belt. [ABSTRACT FROM AUTHOR]

Published

2014

19. On the origin of the Almahata Sitta meteorite and 2008 TC3 asteroid.

Author

Gayon-Markt, Julie, Delbo, Marco, Morbidelli, Alessandro, and Marchi, Simone

Subjects

ASTEROIDS, SPECTRUM analysis, METEORITES, METEOROIDS, MINERALOGICAL research, ACCRETION (Astrophysics), SOLAR system

Abstract

ABSTRACT Asteroid 2008 TC3 was a near-Earth asteroid that impacted the Earth on 2008 October 7. Meteorites were produced by the break-up of 2008 TC3 in the high atmosphere and at present, about 600 meteorites - called Almahata Sitta - coming from 2008 TC3 have been recovered. A mineralogical study of Almahata Sitta fragments shows that the asteroid 2008 TC3 was made of meteorites of different types (ureilites, H, L and E chondrites). Understanding the origin of this body and how it was put together remain a challenge. Here we perform a detailed spectroscopical and dynamical investigation to show that the most likely source region of 2008 TC3 is in the inner main belt at low inclination ( i < 8°). We show that asteroids with spectroscopic classes that can be associated with the different meteorite types of Almahata Sitta are present in the region of the main belt that includes the Nysa-Polana family and objects of the background at low inclination. Searching for a possible scenario of formation for 2008 TC3, we show that there is little chance that 2008 TC3 was formed by low-velocity collisions between asteroids of different mineralogies, in the current asteroid belt. It seems more likely that the heterogeneous composition of 2008 TC3 was inherited from a time when the asteroid belt was in a different dynamical state, most likely in the very early Solar system. Because ureilites are fragments of a large, thermally metamorphosed asteroid, this suggests that the phases of collisional erosion (the break-up of the ureilite parent body) and collisional accretion (the formation of the parent body of 2008 TC3) overlapped for some time in the primordial asteroid belt. [ABSTRACT FROM AUTHOR]

Published

2012

20. Evidence for an asteroid-comet continuum from simulations of carbonaceous microxenolith dynamical evolution.

Author

BRIANI, Giacomo, MORBIDELLI, Alessandro, GOUNELLE, Matthieu, and NESVORNÝ, David

Subjects

*METEOROIDS, *ASTEROIDS, *PROBABILITY theory, *POPULATION, *CARBONACEOUS chondrites (Meteorites)

Abstract

- Micrometeoroids with 100 and 200 μm size dominate the zodiacal cloud dust. Such samples can be studied as micrometeorites, after their passage through the Earth atmosphere, or as microxenoliths, i.e., submillimetric meteorite inclusions. Microxenoliths are samples of the zodiacal cloud dust present in the asteroid Main Belt hundreds of millions years ago. Carbonaceous microxenoliths represent the majority of observed microxenoliths. They have been studied in detail in howardites and H chondrites. We investigate the role of carbonaceous asteroids and Jupiter-family comets as carbonaceous microxenolith parent bodies. The probability of low velocity collisions of asteroidal and cometary micrometeoroids with selected asteroids is computed, starting from the micrometeoroid steady-state orbital distributions obtained by dynamical simulations. We selected possible parent bodies of howardites (Vesta) and H chondrites (Hebe, Flora, Eunomia, Koronis, Maria) as target asteroids. Estimates of the asteroidal and cometary micrometeoroid mass between 2 and 4 AU from the Sun are used to compute the micrometeoroid mass influx on each target. The results show that all the target asteroids (except Koronis) receive the same amount (within the uncertainties) of asteroidal and cometary micrometeoroids. Therefore, both these populations should be observed among howardite and H chondrite carbonaceous microxenoliths. However, this is not the case: carbonaceous microxenoliths show differences similar to those existing among different groups of carbonaceous chondrites (e.g., CI, CM, CR) but two sharply distinct populations are not observed. Our results and the observations can be reconciled assuming the existence of a continuum of mineralogical and chemical properties between carbonaceous asteroids and comets. [ABSTRACT FROM AUTHOR]

Published

2011

21. Earth encounters as the origin of fresh surfaces on near-Earth asteroids.

Author

Binzel, Richard P., Morbidelli, Alessandro, Merouane, Sihane, DeMeo, Francesca E., Birlan, Mirel, Vernazza, Pierre, Thomas, Cristina A., Rivkin, Andrew S., Bus, Schelte J., and Tokunaga, Alan T.

Subjects

*TELESCOPIC gun sights, *ASTEROIDS, *METEORITES, *EARTH (Planet), *ORBITS (Astronomy), *SPECTRUM analysis, *SEISMOLOGY, *LUNAR orbit, *SOLAR system

Abstract

Telescopic measurements of asteroids’ colours rarely match laboratory reflectance spectra of meteorites owing to a ‘space weathering’ process that rapidly reddens asteroid surfaces in less than 106 years. ‘Unweathered’ asteroids (those having spectra matching the most commonly falling ordinary chondrite meteorites), however, are seen among small bodies the orbits of which cross inside Mars and the Earth. Various explanations have been proposed for the origin of these fresh surface colours, ranging from collisions to planetary encounters. Less reddened asteroids seem to cross most deeply into the terrestrial planet region, strengthening the evidence for the planetary-encounter theory, but encounter details within 106 years remain to be shown. Here we report that asteroids displaying unweathered spectra (so-called ‘Q-types’) have experienced orbital intersections closer than the Earth–Moon distance within the past 5 × 105 years. These Q-type asteroids are not currently found among asteroids showing no evidence of recent close planetary encounters. Our results substantiate previous work: tidal stress, strong enough to disturb and expose unweathered surface grains, is the most likely dominant short-term asteroid resurfacing process. Although the seismology details are yet to be worked out, the identification of rapid physical processes that can produce both fresh and weathered asteroid surfaces resolves the decades-long puzzle of the difference in colour of asteroids and meteorites. [ABSTRACT FROM AUTHOR]

Published

2010

22. Asteroids were born big

Author

Morbidelli, Alessandro, Bottke, William F., Nesvorný, David, and Levison, Harold F.

Subjects

*ASTEROIDS, *ASTROPHYSICAL collisions, *SIMULATION methods & models, *MATHEMATICAL models, *PLANETS, *SOLAR system, ORIGIN of the solar system

Abstract

Abstract: How big were the first planetesimals? We attempt to answer this question by conducting coagulation simulations in which the planetesimals grow by mutual collisions and form larger bodies and planetary embryos. The size frequency distribution (SFD) of the initial planetesimals is considered a free parameter in these simulations, and we search for the one that produces at the end objects with a SFD that is consistent with Asteroid belt constraints. We find that, if the initial planetesimals were small (e.g. km-sized), the final SFD fails to fulfill these constraints. In particular, reproducing the bump observed at diameter in the current SFD of the asteroids requires that the minimal size of the initial planetesimals was also ∼100km. This supports the idea that planetesimals formed big, namely that the size of solids in the proto-planetary disk “jumped” from sub-meter scale to multi-kilometer scale, without passing through intermediate values. Moreover, we find evidence that the initial planetesimals had to have sizes ranging from 100 to several 100km, probably even 1000km, and that their SFD had to have a slope over this interval that was similar to the one characterizing the current asteroids in the same size range. This result sets a new constraint on planetesimal formation models and opens new perspectives for the investigation of the collisional evolution in the Asteroid and Kuiper belts as well as of the accretion of the cores of the giant planets. [Copyright &y& Elsevier]

Published

2009

23. Considerations on the magnitude distributions of the Kuiper belt and of the Jupiter Trojans

Author

Morbidelli, Alessandro, Levison, Harold F., Bottke, William F., Dones, Luke, and Nesvorný, David

Subjects

*KUIPER belt, *TROJAN asteroids, *ASTEROIDS, *STELLAR dynamics, *MATHEMATICAL models, *JUPITER (Planet)

Abstract

Abstract: By examining the absolute magnitude (H) distributions (hereafter HD) of the cold and hot populations in the Kuiper belt and of the Trojans of Jupiter, we find evidence that the Trojans have been captured from the outer part of the primordial trans-neptunian planetesimal disk. We develop a sketch model of the HDs in the inner and outer parts of the disk that is consistent with the observed distributions and with the dynamical evolution scenario known as the ‘Nice model’. This leads us to predict that the HD of the hot population should have the same slope of the HD of the cold population for , both as steep as the slope of the Trojans'' HD. Current data partially support this prediction, but future observations are needed to clarify this issue. Because the HD of the Trojans rolls over at to a collisional equilibrium slope that should have been acquired when the Trojans were still embedded in the primordial trans-neptunian disk, our model implies that the same roll-over should characterize the HDs of the Kuiper belt populations, in agreement with the results of Bernstein et al. [Bernstein, G.M., and 5 colleagues, 2004. Astron. J. 128, 1364–1390] and Fuentes and Holman [Fuentes, C.I., Holman, M.J., 2008. Astron. J. 136, 83–97]. Finally, we show that the constraint on the total mass of the primordial trans-neptunian disk imposed by the Nice model implies that it is unlikely that the cold population formed beyond 35 AU. [Copyright &y& Elsevier]

Published

2009

24. The primordial excitation and clearing of the asteroid belt—Revisited

Author

O'Brien, David P., Morbidelli, Alessandro, and Bottke, William F.

Subjects

*ORBITS (Astronomy), *ASTEROIDS, *STARS, *SOLAR system

Abstract

Abstract: We have performed new simulations of two different scenarios for the excitation and depletion of the primordial asteroid belt, assuming Jupiter and Saturn on initially circular orbits as predicted by the Nice Model of the evolution of the outer Solar System [Gomes, R., Levison, H.F., Tsiganis, K., Morbidelli, A., 2005. Nature 435, 466–469; Tsiganis, K., Gomes, R., Morbidelli, A., Levison, H.F., 2005. Nature 435, 459–461; Morbidelli, A., Levison, H.F., Tsiganis, K., Gomes, R., 2005. Nature 435, 462–465]. First, we study the effects of sweeping secular resonances driven by the depletion of the solar nebula. We find that these sweeping secular resonances are incapable of giving sufficient dynamical excitation to the asteroids for nebula depletion timescales consistent with estimates for solar-type stars, and in addition cannot cause significant mass depletion in the asteroid belt or produce the observed radial mixing of different asteroid taxonomic types. Second, we study the effects of planetary embryos embedded in the primordial asteroid belt. These embedded planetary embryos, combined with the action of jovian and saturnian resonances, can lead to dynamical excitation and radial mixing comparable to the current asteroid belt. The mass depletion driven by embedded planetary embryos alone, even in the case of an eccentric Jupiter and Saturn, is roughly 10–20× less than necessary to explain the current mass of the main belt, and thus a secondary depletion event, such as that which occurs naturally in the Nice Model, is required. We discuss the implications of our new simulations for the dynamical and collisional evolution of the main belt. [Copyright &y& Elsevier]

Published

2007

25. Models of the collisional damping scenario for ice-giant planets and Kuiper belt formation

Author

Levison, Harold F. and Morbidelli, Alessandro

Subjects

*SOLAR system, *DWARF planets, *ASTEROIDS, *KUIPER belt

Abstract

Abstract: Chiang et al. [Chiang, E., Lithwick, Y., Murray-Clay, R., Buie, M., Grundy, W., Holman, M., 2007. In: Protostars and Planets V, pp. 895–911] have recently proposed that the observed structure of the Kuiper belt could be the result of a dynamical instability of a system of ∼5 primordial ice-giant planets in the outer Solar System. According to this scenario, before the instability occurred, these giants were growing in a highly collisionally damped environment according to the arguments in Goldreich et al. [Goldreich, P., Lithwick, Y., Sari, R., 2004. Astrophys. J. 614, 497–507; Annu. Rev. Astron. Astrophys. 42, 549–601]. Here we test this hypothesis with a series of numerical simulations using a new code designed to incorporate the dynamical effects of collisions. We find that we cannot reproduce the observed Solar System. In particular, Goldreich et al. [Goldreich, P., Lithwick, Y., Sari, R., 2004. Astrophys. J. 614, 497–507; Annu. Rev. Astron. Astrophys. 42, 549–601] and Chiang et al. [Chiang, E., Lithwick, Y., Murray-Clay, R., Buie, M., Grundy, W., Holman, M., 2007. In: Protostars and Planets V, pp. 895–911] argue that during the instability, all but two of the ice giants would be ejected from the Solar System by Jupiter and Saturn, leaving Uranus and Neptune behind. We find that ejections are actually rare and that instead the systems spread outward. This always leads to a configuration with too many planets that are too far from the Sun. Thus, we conclude that both Goldreich et al.''s scheme for the formation of Uranus and Neptune and Chiang et al.''s Kuiper belt formation scenario are not viable in their current forms. [Copyright &y& Elsevier]

Published

2007

26. The size–frequency distribution of dormant Jupiter family comets

Author

Whitman, Kathryn, Morbidelli, Alessandro, and Jedicke, Robert

Subjects

*ORBITS (Astronomy), *COMETS, *INNER planets, ORIGIN of the solar system

Abstract

Abstract: We estimate the total number and the slope of the size–frequency distribution (SFD) of dormant Jupiter family comets (JFCs) by fitting a one-parameter model to the known population. We first select 61 near-Earth objects (NEOs) that are likely to be dormant JFCs because their orbits are dynamically coupled to Jupiter [Bottke, W.F., Morbidelli, A., Jedicke, R., Petit, J., Levison, H.F., Michel, P., Metcalfe, T.S., 2002a. Icarus 156, 399–433]. Then, from the numerical simulations of Levison and Duncan [1997. Icarus 127, 13–32], we construct an orbit distribution model for JFCs in the NEO orbital element space. We assume an orbit-independent SFD for all JFCs, the slope of which is our unique free parameter. Finally, we compute observational biases for dormant JFCs using a calibrated NEO survey simulator [Jedicke, R., Morbidelli, A., Spahr, T., Petit, J., Bottke, W.F., 2003. Icarus 161, 17–33]. By fitting the biased model to the data, we estimate that there are ∼75 dormant JFCs with in the NEO region and that the slope of their cumulative SFD is . Our slope for the SFD of dormant JFCs is very close to that of active JFCs as determined by Weissman and Lowry [2003. Lunar Planet. Sci. 34. Abstract 2003]. Thus, we argue that when JFCs fade they are likely to become dormant rather than to disrupt and that the fate of faded comets is size-independent. Our results imply that the size distribution of the JFC progenitors—the scattered disk trans-neptunian population—either (i) has a similar and shallow SFD or () is slightly steeper and physical processes acting on the comets in a size-dependent manner creates the shallower active comet SFD. Our measured slope, typical of collisionally evolved populations with a size-dependent impact strength [Benz, W., Asphaug, E., 1999. Icarus 142, 5–20], suggests that scattered disk bodies reached collisional equilibrium inside the protoplanetary disk prior to their removal from the planetary region. [Copyright &y& Elsevier]

Published

2006

27. Iron meteorites as remnants of planetesimals formed in the terrestrial planet region.

Author

Bottke, William F., Nesvorný, David, Grimm, Robert E., Morbidelli, Alessandro, and O'Brien, David P.

Subjects

IRON meteorites, IRON, ASTEROIDS, CHONDRITES, SOLAR system, RADIOISOTOPES

Abstract

Iron meteorites are core fragments from differentiated and subsequently disrupted planetesimals. The parent bodies are usually assumed to have formed in the main asteroid belt, which is the source of most meteorites. Observational evidence, however, does not indicate that differentiated bodies or their fragments were ever common there. This view is also difficult to reconcile with the fact that the parent bodies of iron meteorites were as small as 20 km in diameter and that they formed 1–2 Myr earlier than the parent bodies of the ordinary chondrites. Here we show that the iron-meteorite parent bodies most probably formed in the terrestrial planet region. Fast accretion times there allowed small planetesimals to melt early in Solar System history by the decay of short-lived radionuclides (such as 26Al, 60Fe). The protoplanets emerging from this population not only induced collisional evolution among the remaining planetesimals but also scattered some of the survivors into the main belt, where they stayed for billions of years before escaping via a combination of collisions, Yarkovsky thermal forces, and resonances. We predict that some asteroids are main-belt interlopers (such as (4) Vesta). A select few may even be remnants of the long-lost precursor material that formed the Earth. [ABSTRACT FROM AUTHOR]

Published

2006

28. Asteroid families.

Author

Nesvorný, David, Bottke, William F., Vokrouhlický, David, Morbidelli, Alessandro, and Jedicke, Robert

Abstract

An asteroid family is a group of asteroids with similar orbits and spectra that was produced by a collisional breakup of a large parent body. To identify asteroid families, researchers look for clusters of asteroid positions in the space of proper orbital elements. These elements, being more constant over time than osculating orbital elements, provide a dynamical criterion of whether a group of bodies has a common ancestor. More than fifty asteroid families have been identified to date. Their analysis produced several important insights into the physics of large scale collisions, dynamical processes affecting small bodies in the Solar System, and surface and interior properties of asteroids. [ABSTRACT FROM PUBLISHER]

Published

2005

29. Origin and dynamics of Near Earth Objects

Author

Michel, Patrick, Morbidelli, Alessandro, and Bottke, William F.

Subjects

*EARTH'S orbit, *ASTEROIDS, *NUMERICAL integration, *GRAVITY, *COLLISIONS (Physics)

Abstract

Abstract: The population of Near-Earth Objects (NEOs) evolves on orbits which can cross the orbit of the Earth. Most NEOs come from the asteroid belt via unstable zones associated with powerful or diffusive resonances. Their evolutionary paths and the statistical properties of their dynamics have been determined by massive numerical integrations. A steady-state model of their orbital and magnitude distributions has been elaborated which indicates that 1000 NEOs are kilometre-size with an impact frequency with the Earth around 0.5 Myr. A non-gravitational mechanism, the Yarkovsky thermal drag, plays the dominant role in delivering material in the NEO source regions, explaining how this population is maintained in a steady-state and why its size distribution is shallower than expected if NEOs were created through the direct injection of fresh fragments from collisional break ups into resonances. To cite this article: P. Michel et al., C. R. Physique 6 (2005). [Copyright &y& Elsevier]

Published

2005

30. Contamination of the asteroid belt by primordial trans-Neptunian objects.

Author

Levison, Harold F., Bottke, William F., Gounelle, Matthieu, Morbidelli, Alessandro, Nesvorný, David, and Tsiganis, Kleomenis

Subjects

ASTEROIDS, SOLAR system, NEAR-Earth objects, SUN, NEPTUNIAN theory, IGNEOUS rocks, METEORITES, ACHONDRITES, METEORS, PLANETS

Abstract

The main asteroid belt, which inhabits a relatively narrow annulus ∼2.1–3.3 au from the Sun, contains a surprising diversity of objects ranging from primitive ice–rock mixtures to igneous rocks. The standard model used to explain this assumes that most asteroids formed in situ from a primordial disk that experienced radical chemical changes within this zone. Here we show that the violent dynamical evolution of the giant-planet orbits required by the so-called Nice model leads to the insertion of primitive trans-Neptunian objects into the outer belt. This result implies that the observed diversity of the asteroid belt is not a direct reflection of the intrinsic compositional variation of the proto-planetary disk. The dark captured bodies, composed of organic-rich materials, would have been more susceptible to collisional evolution than typical main-belt asteroids. Their weak nature makes them a prodigious source of micrometeorites—sufficient to explain why most are primitive in composition and are isotopically different from most macroscopic meteorites. [ABSTRACT FROM AUTHOR]

Published

2009

31. Dating the Solar SystemÕs giant planet orbital instability using enstatite meteorites.

Author

Avdellidou, Chrysa, Delbo, Marco, Nesvorný, David, Walsh, Kevin J., and Morbidelli, Alessandro

Subjects

*GAS giants, *SOLAR system, *ASTEROIDS, *METEORITES, *ENSTATITE, *INNER planets

Abstract

The giant planets of the Solar System formed on initially compact orbits, which transitioned to the current wider configuration by means of an orbital instability. The timing of that instability is poorly constrained. In this work, we use dynamical simulations to demonstrate that the instability implanted planetesimal fragments from the terrestrial planet region into the asteroid main belt. We use meteorite data to show that the implantation occurred >60 million years (Myr) after the Solar System began to form. Combining this constraint with a previous upper limit derived from JupiterÕs trojan asteroids, we conclude that the orbital instability occurred 60 to 100 Myr after the beginning of Solar System formation. The giant impact that formed the Moon occurred within this range, so it might be related to the giant planet instability. [ABSTRACT FROM AUTHOR]

Published

2024

32. Yarkovsky V-shape identification of asteroid families.

Author

Bolin, Bryce T., Delbo, Marco, Morbidelli, Alessandro, and Walsh, Kevin J.

Subjects

*YARKOVSKY effect, *PLANETARY orbits, *ASTEROIDS, *ASTROPHYSICAL collisions, *HIERARCHICAL clustering (Cluster analysis), *STATISTICAL correlation

Abstract

There are only a few known main belt (MB) asteroid families with ages greater than 2 Gyr (Brož et al., 2013; Spoto et al., 2015). Estimates based on the family producing collision rate suggest that the lack of > 2 Gyr-old families may be due to a selection bias in current techniques used to identify families. Family fragments disperse in their orbital elements, semi-major axis, a , eccentricity, e , and inclination, i , due to secular resonances, close encounters with massive asteroids and the non-gravitational Yarkovsky force. This causes the family fragments to be indistinguishable from the background of the main belt making them more difficult to identify with the hierarchical clustering method (HCM) with increasing family age. The discovery of the Eulalia and new Polana families in the inner belt relied on new techniques because Yarkovsky spreading made them too disperse to be identified using the classical HCM. The techniques used to discover the new Polana and Eulalia families are modified here to identify asteroid families by searching for correlations between a and asteroid diameter, D , or absolute magnitude, H . A group of asteroids is identified as a collisional family if its boundary in the a vs. 1 D or a vs. H planes has a characteristic V-shape which is due to the size dependent Yarkovsky spreading. The V-shape boundary is identified with two separate techniques. The first technique identifies a border by measuring a steep drop between the number of objects inside and outside of the border. The second technique identifies the V-shape border by measuring a peak in the number density of objects in a vs. 1 D , H space. Families are identified with just one or both V-shape identifying techniques. The V-shape techniques are demonstrated on the known families of Erigone, Vesta, Koronis, and families difficult to identify by HCM such as Flora, Baptistina, new Polana, Eulalia and Karin. Future applications of the technique, such as in a large scale search for > 2 Gyr-old families throughout the MB, are discussed. [ABSTRACT FROM AUTHOR]

Published

2017

33. Constraining the cratering chronology of Vesta.

Author

O׳Brien, David P., Marchi, Simone, Morbidelli, Alessandro, Bottke, William F., Schenk, Paul M., Russell, Christopher T., and Raymond, Carol A.

Subjects

*CRATERING, *METEORITES, *EVOLUTIONARY theories, *CHRONOLOGY, *ASTEROID belt, *VESTA (Asteroid)

Abstract

Vesta has a complex cratering history, with ancient terrains as well as recent large impacts that have led to regional resurfacing. Crater counts can help constrain the relative ages of different units on Vesta׳s surface, but converting those crater counts to absolute ages requires a chronology function. We present a cratering chronology based on the best current models for the dynamical evolution of asteroid belt, and calibrate it to Vesta using the record of large craters on its surface. While uncertainties remain, our chronology function is broadly consistent with an ancient surface of Vesta as well as other constraints such as the bombardment history of the rest of the inner Solar System and the Ar–Ar age distribution of howardite, eucrite and diogenite (HED) meteorites from Vesta. [ABSTRACT FROM AUTHOR]

Published

2014

34. Asteroidal source of L chondrite meteorites

Author

Nesvorný, David, Vokrouhlický, David, Morbidelli, Alessandro, and Bottke, William F.

Subjects

*CHONDRITES, *ASTEROID orbits, *METEORITES, *BASALT, *ASTRONOMICAL spectroscopy, *RADIOACTIVE dating, *SOLAR system

Abstract

Abstract: Establishing connections between meteorites and their parent asteroids is an important goal of planetary science. Several links have been proposed in the past, including a spectroscopic match between basaltic meteorites and (4) Vesta, that are helping scientists understand the formation and evolution of the Solar System bodies. Here we show that the shocked L chondrite meteorites, which represent about two thirds of all L chondrite falls, may be fragments of a disrupted asteroid with orbital semimajor axis . This breakup left behind thousands of identified 1–15 km asteroid fragments known as the Gefion family. Fossil L chondrite meteorites and iridium enrichment found in an ≈467 Ma old marine limestone quarry in southern Sweden, and perhaps also ∼5 large terrestrial craters with corresponding radiometric ages, may be tracing the immediate aftermath of the family-forming collision when numerous Gefion fragments evolved into the Earth-crossing orbits by the 5:2 resonance with Jupiter. This work has major implications for our understanding of the source regions of ordinary chondrite meteorites because it implies that they can sample more distant asteroid material than was previously thought possible. [Copyright &y& Elsevier]

Published

2009

35. The origin of water on Mars

Author

Lunine, Jonathan I., Chambers, John, Morbidelli, Alessandro, and Leshin, Laurie A.

Subjects

*WATER, *MARS (Planet), *ASTEROIDS, *METEORITES

Abstract

This paper considers the origin of water on Mars, in the context of a dynamical model that accounts for most of the Earth''s water as a product of collisions between the growing Earth and planet-sized “embryos” from the asteroid belt. Mars'' history is found to be different; to explain the present mass of Mars requires that it suffer essentially no giant collisions and the bulk of its growth is through addition of smaller bodies. Asteroids and comets from beyond 2.5 AU provide the source of Mars'' water, which totals 6–27% of the Earth''s present ocean (1 Earth ocean≡1.5×1021 kg), equivalent to 600–2700-m depth on the martian surface. The D/H ratio of this material is 1.2–1.6 times Standard Mean Ocean Water, the smaller value obtaining for the larger amount of water accreted. The upper half of the range of total water accreted, while many times less than that acquired by the Earth, is consistent with geological data on Mars, and the D/H value is that derived for martian magmatic water from SNC meteorites. Both together are consistent with published interpretations of the high D/H in present-day martian atmospheric water in terms of water loss through atmospheric escape. [Copyright &y& Elsevier]

Published

2003

36. Identification of a primordial asteroid family constrains the original planetesimal population.

Author

Delbo, Marco, Walsh, Kevin, Bolin, Bryce, Avdellidou, Chrysa, and Morbidelli, Alessandro

Subjects

*ASTEROIDS, *PLANETESIMALS, *PROTOPLANETARY disks, *ORIGIN of planets, *SOLAR system

Abstract

A quarter of known asteroids is associated with more than 100 distinct asteroid families, meaning that these asteroids originate as impact fragments from the family parent bodies. The determination of which asteroids of the remaining population are members of undiscovered families, or accreted as planetesimals from the protoplanetary disk, would constrain a critical phase of planetary formation by unveiling the unknown planetesimal size distribution. We discovered a 4-billion-year-old asteroid family extending across the entire inner part of the main belt whose members include most of the dark asteroids previously unlinked to families. This allows us to identify some original planetesimals, which are all larger than 35 kilometers, supporting the view of asteroids being born big. Their number matches the known distinct meteorite parent bodies. [ABSTRACT FROM AUTHOR]

Published

2017

37. Is the Grand Tack model compatible with the orbital distribution of main belt asteroids?

Author

Deienno, Rogerio, Gomes, Rodney S., Walsh, Kevin J., Morbidelli, Alessandro, and Nesvorný, David

Subjects

*ASTEROIDS, *NEBULAR hypothesis, *CONSTRAINTS (Physics), *INNER planets, *SOLAR system

Abstract

The Asteroid Belt is characterized by the radial mixing of bodies with different physical properties, a very low mass compared to Minimum Mass Solar Nebula expectations and has an excited orbital distribution, with eccentricities and inclinations covering the entire range of values allowed by the constraints of dynamical stability. Models of the evolution of the Asteroid Belt show that the origin of its structure is strongly linked to the process of terrestrial planet formation. The Grand Tack model presents a possible solution to the conundrum of reconciling the small mass of Mars with the properties of the Asteroid Belt, including the mass depletion, radial mixing and orbital excitation. However, while the inclination distribution produced in the Grand Tack model is in good agreement with the one observed, the eccentricity distribution is skewed towards values larger than those found today. Here, we evaluate the evolution of the orbital properties of the Asteroid Belt from the end of the Grand Tack model (at the end of the gas nebula phase when planets emerge from the dispersing gas disk), throughout the subsequent evolution of the Solar System including an instability of the Giant Planets approximately 400 Myr later. Before the instability, the terrestrial planets were modeled on dynamically cold orbits with Jupiter and Saturn locked in a 3:2 mean motion resonance. The model continues for an additional 4.1 Gyr after the giant planet instability. Our results show that the eccentricity distribution obtained in the Grand Tack model evolves towards one very similar to that currently observed, and the semimajor axis distribution does the same. The inclination distribution remains nearly unchanged with a slight preference for depletion at low inclination; this leads to the conclusion that the inclination distribution at the end of the Grand Tack is a bit over-excited. Also, we constrain the primordial eccentricities of Jupiter and Saturn, which have a major influence on the dynamical evolution of the Asteroid Belt and its final orbital structure. [ABSTRACT FROM AUTHOR]

Published

2016

38. Linking the collisional history of the main asteroid belt to its dynamical excitation and depletion

Author

Bottke, William F., Durda, Daniel D., Nesvorný, David, Jedicke, Robert, Morbidelli, Alessandro, Vokrouhlický, David, and Levison, Harold F.

Subjects

*SOLAR system, *ASTEROIDS, *ASTRONOMICAL perturbation, *SIZE reduction of materials

Abstract

Abstract: The main belt is believed to have originally contained an Earth mass or more of material, enough to allow the asteroids to accrete on relatively short timescales. The present-day main belt, however, only contains Earth masses. Numerical simulations suggest that this mass loss can be explained by the dynamical depletion of main belt material via gravitational perturbations from planetary embryos and a newly-formed Jupiter. To explore this scenario, we combined dynamical results from Petit et al. [Petit, J. Morbidelli, A., Chambers, J., 2001. The primordial excitation and clearing of the asteroid belt. Icarus 153, 338–347] with a collisional evolution code capable of tracking how the main belt undergoes comminution and dynamical depletion over 4.6 Gyr [Bottke, W.F., Durda, D., Nesvorny, D., Jedicke, R., Morbidelli, A., Vokrouhlický, D., Levison, H., 2005. The fossilized size distribution of the main asteroid belt. Icarus 175, 111–140]. Our results were constrained by the main belt''s size–frequency distribution, the number of asteroid families produced by disruption events from diameter parent bodies over the last 3–4 Gyr, the presence of a single large impact crater on Vesta''s intact basaltic crust, and the relatively constant lunar and terrestrial impactor flux over the last 3 Gyr. We used our model to set limits on the initial size of the main belt as well as Jupiter''s formation time. We find the most likely formation time for Jupiter was after the onset of fragmentation in the main belt. These results are consistent with the estimated mean disk lifetime of 3 Myr predicted by Haisch et al. [Haisch, K.E., Lada, E.A., Lada, C.J., 2001. Disk frequencies and lifetimes in young clusters. Astrophys. J. 553, L153–L156]. The post-accretion main belt population, in the form of diameter planetesimals, was likely to have been times the current main belt''s mass. This corresponds to Earth masses, only a small fraction of the total mass thought to have existed in the main belt zone during planet formation. The remaining mass was most likely taken up by planetary embryos formed in the same region. Our results suggest that numerous planetesimals disrupted early in Solar System history, but only a small fraction of their fragments survived the dynamical depletion event described above. We believe this may explain the limited presence of iron-rich M-type, olivine-rich A-type, and non-Vesta V-type asteroids in the main belt today. The collisional lifetimes determined for main belt asteroids agree with the cosmic ray exposure ages of stony meteorites and are consistent with the limited collisional evolution detected among large Koronis family members. Using the same model, we investigated the near-Earth object (NEO) population. We show the shape of the NEO size distribution is a reflection of the main belt population, with main belt asteroids driven to resonances by Yarkovsky thermal forces. We used our model of the NEO population over the last 3 Gyr, which is consistent with the current population determined by telescopic and satellite data, to explore whether the majority of small craters () formed on Mercury, the Moon, and Mars were produced by primary impacts or by secondary impacts generated by ejecta from large craters. Our results suggest that most small craters formed on these worlds were a by-product of secondary rather than primary impacts. [Copyright &y& Elsevier]

Published

2005

39. The fossilized size distribution of the main asteroid belt

Author

Bottke, William F., Durda, Daniel D., Nesvorný, David, Jedicke, Robert, Morbidelli, Alessandro, Vokrouhlický, David, and Levison, Hal

Subjects

*ASTEROIDS, *SOLAR system, *SIZE reduction of materials, *RESONANCE, *NUCLEAR reactions

Abstract

Abstract: Planet formation models suggest the primordial main belt experienced a short but intense period of collisional evolution shortly after the formation of planetary embryos. This period is believed to have lasted until Jupiter reached its full size, when dynamical processes (e.g., sweeping resonances, excitation via planetary embryos) ejected most planetesimals from the main belt zone. The few planetesimals left behind continued to undergo comminution at a reduced rate until the present day. We investigated how this scenario affects the main belt size distribution over Solar System history using a collisional evolution model (CoEM) that accounts for these events. CoEM does not explicitly include results from dynamical models, but instead treats the unknown size of the primordial main belt and the nature/timing of its dynamical depletion using innovative but approximate methods. Model constraints were provided by the observed size frequency distribution of the asteroid belt, the observed population of asteroid families, the cratered surface of differentiated Asteroid (4) Vesta, and the relatively constant crater production rate of the Earth and Moon over the last 3 Gyr. Using CoEM, we solved for both the shape of the initial main belt size distribution after accretion and the asteroid disruption scaling law . In contrast to previous efforts, we find our derived function is very similar to results produced by numerical hydrocode simulations of asteroid impacts. Our best fit results suggest the asteroid belt experienced as much comminution over its early history as it has since it reached its low-mass state approximately 3.9–4.5 Ga. These results suggest the main belt''s wavy-shaped size-frequency distribution is a “fossil” from this violent early epoch. We find that most diameter asteroids are primordial, with their physical properties likely determined during the accretion epoch. Conversely, most smaller asteroids are byproducts of fragmentation events. The observed changes in the asteroid spin rate and lightcurve distributions near are likely to be a byproduct of this difference. Estimates based on our results imply the primordial main belt population (in the form of bodies) was 150–250 times larger than it is today, in agreement with recent dynamical simulations. [Copyright &y& Elsevier]

Published

2005