Escape of asteroids from the main belt

Granvik, Mikael; Morbidelli, Alessandro; Vokrouhlický, David; Bottke, W. F.; Nesvorný, David; Jedicke, Robert

doi:10.1051/0004-6361/201629252

Cited by 103 publications

(126 citation statements)

References 60 publications

(80 reference statements)

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“…Even if we consider the identifications of the compositions of Ceres and Themis to be unsettled, it is clear that there are important differences between their 3‐μm spectra and the CM meteorites and Ch asteroids, and those differences also can be seen among the eight large C‐complex asteroids we discuss and the meteorites. Objects are delivered to the near‐Earth object population from the entire asteroid belt, albeit with different efficiencies for different parts of the belt (Granvik et al, ). Given the relative abundance of these objects, it is not obvious why we should lack meteorites that are consistent with the Ceres and Themis types but have them from not only Pallas‐types but also, apparently, the high‐albedo objects >200 km (Vesta and howardite‐eucrite‐diogenite (HED) meteorites, and several S‐class asteroids and ordinary chondrites, mesosiderites, etc.…”

Section: Analysis and Resultsmentioning

confidence: 99%

Infrared Spectroscopy of Large, Low‐Albedo Asteroids: Are Ceres and Themis Archetypes or Outliers?

2019

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Low‐albedo, hydrated objects dominate the list of the largest asteroids. These objects have varied spectral shapes in the 3‐μm region, where diagnostic absorptions due to volatile species are found. Dawn's visit to Ceres has extended the view shaped by ground‐based observing and shown that world to be a complex one, potentially still experiencing geological activity. We present 33 observations from 2.2 to 4.0 μm of eight large (D > 200 km) asteroids from the C spectral complex, with spectra inconsistent with the hydrated minerals we see in meteorites. We characterize their absorption band characteristics via polynomial and Gaussian fits to test their spectral similarity to Ceres, the asteroid 24 Themis (thought to be covered in ice frost), and the asteroid 51 Nemausa (spectrally similar to the CM meteorites). We confirm most of the observations are inconsistent with what is seen in meteorites and require additional absorbers. We find clusters in band centers that correspond to Ceres‐ and Themis‐like spectra, but no hiatus in the distribution suitable for use to simply distinguish between them. We also find a range of band centers in the spectra that approaches what is seen on Comet 67P. Finally, variation is seen between observations for some objects, with the variation on 324 Bamberga consistent with hemispheric‐level difference in composition. Given the ubiquity of objects with 3‐μm spectra unlike what we see in meteorites, and the similarity of those spectra to the published spectra of Ceres and Themis, these objects appear much more to be archetypes than outliers.

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Section: Analysis and Resultsmentioning

confidence: 99%

Infrared Spectroscopy of Large, Low‐Albedo Asteroids: Are Ceres and Themis Archetypes or Outliers?

2019

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“…A model describing the evolution of small asteroids was developed that started with 92,449 test asteroids, distributed across the Main Belt (Granvik et al. , ). Of these, 70,708 evolved into NEO orbits.…”

Section: Discussionmentioning

confidence: 99%

“…In Main Belt, based only on size: possibly underestimated by factor of 3-5 (see text). developed that started with 92,449 test asteroids, distributed across the Main Belt (Granvik et al 2016(Granvik et al , 2017. Of these, 70,708 evolved into NEO orbits.…”

Section: Discussionmentioning

confidence: 99%

The Creston, California, meteorite fall and the origin of L chondrites

Jenniskens

Utas

Yin

et al. 2019

Meteorit & Planetary Scien

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It has been proposed that all L chondrites resulted from an ongoing collisional cascade of fragments that originated from the formation of the ~500 Ma old asteroid family Gefion, located near the 5:2 mean‐motion resonance with Jupiter in the middle Main Belt. If so, L chondrite pre‐atmospheric orbits should be distributed as expected for that source region. Here, we present contradictory results from the orbit and collisional history of the October 24, 2015, L6 ordinary chondrite fall at Creston, CA (here reclassified to L5/6). Creston's short 1.30 ± 0.02 AU semimajor axis orbit would imply a long dynamical evolution if it originated from the middle Main Belt. Indeed, Creston has a high cosmic ray exposure age of 40–50 Ma. However, Creston's small meteoroid size and low 4.23 ± 0.07° inclination indicate a short dynamical lifetime against collisions. This suggests, instead, that Creston originated most likely in the inner asteroid belt and was delivered via the ν6 resonance. The U‐Pb systematics of Creston apatite reveals a Pb‐Pb age of 4,497.1 ± 3.7 Ma, and an upper intercept U‐Pb age of 4,496.7 ± 5.8 Ma (2σ), circa 70 Ma after formation of CAI, as found for other L chondrites. The K‐Ar (age ~4.3 Ga) and U,Th‐He (age ~1 Ga) chronometers were not reset at ~500 Ma, while the lower intercept U‐Pb age is poorly defined as 770 ± 320 Ma. So far, the three known L chondrites that impacted on orbits with semimajor axes a <2.0 AU all have high (>3 Ga) K‐Ar ages. This argues for a source of some of our L chondrites in the inner Main Belt. Not all L chondrites originate in a continuous population of Gefion family debris stretching across the 3:1 mean‐motion resonance.

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“…Moreover, the Granvik et al (2016Granvik et al ( , 2017 NEO model predicts that the number of NEOs with 17 < H < 22 originating in the Phocaea region should be about 670, which represents about 3% of the entire NEO population. This is comparable to the fraction of objects originating in the outer main belt with a > 3 au (3.5%) and the Jupiter-family comets (2%).…”

Section: The Dynamical Evolution: Outcome Of Numerical Simulationsmentioning

confidence: 99%

A Dark Asteroid Family in the Phocaea Region

Novaković

Tsirvoulis

Granvik

et al. 2017

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We report the discovery of a new asteroid family among the dark asteroids residing in the Phocaea region the Tamara family. We make use of available physical data to separate asteroids in the region according to their surface reflectance properties, and establish the membership of the family. We determine the slope of the cumulative magnitude distribution of the family, and find it to be significantly steeper than the corresponding slope of all the asteroids in the Phocaea region. This implies that sub-kilometer dark Phocaeas are comparable in number to bright S-type objects, shedding light on an entirely new aspect of the composition of small Phocaea asteroids. We then use the Yarkovsky V-shape based method and estimate the age of the family to be 264 ± 43 Myr. Finally, we carry out numerical simulations of the dynamical evolution of the Tamara family. The results suggest that up to 50 Tamara members with absolute magnitude H < 19.4 may currently be found in the near-Earth region. Despite their relatively small number in the near-Earth space, the rate of Earth impacts by small, dark Phocaeas is non-negligible.

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Escape of asteroids from the main belt

Cited by 103 publications

References 60 publications

Infrared Spectroscopy of Large, Low‐Albedo Asteroids: Are Ceres and Themis Archetypes or Outliers?

Infrared Spectroscopy of Large, Low‐Albedo Asteroids: Are Ceres and Themis Archetypes or Outliers?

The Creston, California, meteorite fall and the origin of L chondrites

A Dark Asteroid Family in the Phocaea Region

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