Origin, Internal Structure and Evolution of 4 Vesta

Zuber, M. T.; McSween, H. Y.; Binzel, Richard P.; Elkins-Tanton, Linda T.; Konopliv, Alexander S.; Pieters, C. M.; Smith, David E.

doi:10.1007/s11214-011-9806-8

Cited by 55 publications

(43 citation statements)

References 98 publications

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“…As discussed in section 2.2 the determination of the three moments of inertia of Vesta (Eq. 1) is underestimated from the two gravity coefficients C 20 and C 22 obtained by Dawn, and we develop a two-layer model as suggested by Zuber et al (2011) and Russell et al (2012) to fix the value of the polar moment of inertia C/MR 2 . The value of C/MR 2 ranges between 0.38 and 0.42 (∼ 10%) depending on the size of the core and the jump density between the core and the mantle.…”

Section: Geophysical Discussionmentioning

confidence: 99%

“…We compute the polar moment of inertia of Vesta for two sets of interior models: ρ c = 7100 kg/m 3 , r c = 113 km and ρ c = 7800 kg/m 3 , r c = 107 km (Russell et al 2012). By conserving the mass, we obtain a density for the mantle of 3148.2 kg/m 3 and 3148.4 kg/m 3 that is in the range of mantle density determined in Zuber et al (2011). The resulting polar moment of inertia is C/MR 2 = 0.4168 and C/MR 2 = 0.4161, which are very close.…”

Section: Gravity Field and Interior Modelmentioning

confidence: 99%

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The rotational motion of Vesta

Rambaux

2013

A&A

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Context. Vesta is the second largest body of the main asteroid belt, and it has been studied recently in great detail by the Dawn mission. It was the first time that this asteroid, or protoplanet, has been explored by a space mission, and it revealed a differentiated body. The knowledge of the rotational motion and, especially, its precession-nutation and length-of-day variations may add precious information on its interior. Aims. The objective of this paper is to present the first rotational model of Vesta based on the data acquired by the Dawn mission. The Dawn mission determined the orientation of Vesta with 0.01 degree accuracy, as well as the second degree of the gravity coefficients with a few percent accuracy [Russell et al. 2012]. Methods. We built a semi-analytical model of the rotational motion of Vesta based on the orbital perturbations and the large triaxial shape of Vesta. The rotational motion is then described through the polar motion, precession, nutation, and length-of-day variations. The sensitivity of the precession-nutation is given as a function of the polar moment of inertia, which has not yet been determined. Results. We find that the amplitude of the nutation is about 2000 milli-arcseconds at the semi-annual period, whereas the amplitude of the length-of-day variation is about 3 mas/days, in the semi-diurnal period. Finally, we show that the signature of the polar moment of inertia, which is crucial for constraining geophysical model, is on the order of 200 milli-arcseconds for the semi-annual nutations for two extrema of polar moment with inertia values of 0.38-0.42.

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Section: Geophysical Discussionmentioning

confidence: 99%

Section: Gravity Field and Interior Modelmentioning

confidence: 99%

The rotational motion of Vesta

Rambaux

2013

A&A

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“…This connection, if confirmed, would imply that the asteroid is differentiated (see e.g. Drake 2001; Keil 2002, and references therein and the chapters by McSween et al 2010 andZuber et al 2011). Moreover, the 40 Ar-39 Ar ages of the oldest HED meteorites (see Keil 2002; Table 1 Collisional erosion of Vesta due to primordial planetesimals formed in quiescent (Coradini et al 1981) and turbulent disks (Morbidelli et al 2009;Chambers 2010) and due to collisionally evolved planetesimals (Morbidelli et al 2009) in the four migration scenarios of Jupiter considered by Turrini et al (2011).…”

Section: The Jovian Early Bombardmentmentioning

confidence: 92%

“…Federico et al 2011). Several attempts were made in order to model the thermal evolution of Vesta: we refer the readers to Keil (2002) and to the chapter by Zuber et al (2011) for a detailed discussion. Based on geochemical and mineralogical observations, generally it is assumed that Vesta underwent an extensive differentiation, and that was completely melted and homogenized.…”

Section: Thermal Evolution Of Vesta and Ceresmentioning

confidence: 99%

Vesta and Ceres: Crossing the History of the Solar System

et al. 2011

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The evolution of the Solar System can be schematically divided into three different phases: the Solar Nebula, the Primordial Solar System and the Modern Solar System. These three periods were characterized by very different conditions, both from the point of view of the physical conditions and from that of the processes there were acting through them. Across the Solar Nebula phase, planetesimals and planetary embryos were forming and differentiating due to the decay of short-lived radionuclides. At the same time, giant planets formed their cores and accreted the nebular gas to reach their present masses. After the gas dispersal, the Primordial Solar System began its evolution. In the inner Solar System, planetary embryos formed the terrestrial planets and, in combination with the gravitational perturbations of the giant planets, depleted the residual population of planetesimals. In the outer Solar System, giant planets underwent a violent, chaotic phase of orbital rearrangement which caused the Late Heavy Bombardment. Then the rapid and fierce evolution of the young Solar System left place to the more regular secular evolution of the Modern Solar System. Vesta, through its connection with HED meteorites, and plausibly Ceres too were between the first bodies to form in the history of the Solar System. Here we discuss the timescale of their formation and evolution and how they would have been affected by their passage through the different phases of the history of the Solar System, in order to draw a reference framework to interpret the data that Dawn mission will supply on them.

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“…The layers size and density are constrained to the model of internal structures of Vesta discussed in Park et al (2014); Konopliv et al (2014) and Zuber et al (2011). We preserve the total mass of Lutetia by fixing the medium density at 3.4 g.cm −3 .…”

Section: The Four-layers Internal Modelmentioning

confidence: 99%

The dynamical environment of asteroid 21 Lutetia according to different internal models

Aljbaae

Chanut

Carruba

et al. 2016

Mon. Not. R. Astron. Soc.

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One of the most accurate models currently used to represent the gravity field of irregular bodies is the polyhedral approach. In this model, the mass of the body is assumed to be homogeneous, which may not be true for a real object. The main goal of the present paper is to study the dynamical effects induced by three different internal structures (uniform, three-and four-layers) of asteroid (21) Lutetia, an object that recent results from space probe suggest being at least partially differentiated. The Mascon gravity approach used in the present work, consists of dividing each tetrahedron into eight parts to calculate the gravitational field around the asteroid. The zero-velocity curves show that the greatest displacement of the equilibrium points occurs in the position of the E4 point for the four-layers structure and the smallest one occurs in the position of the E3 point for the three-layers structure. Moreover, stability against impact shows that the planar limit gets slightly closer to the body with the four-layered structure.We then investigated the stability of orbital motion in the equatorial plane of (21) Lutetia and propose numerical stability criteria to map the region of stable motions. Layered structures could stabilize orbits that were unstable in the homogeneous model.

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Origin, Internal Structure and Evolution of 4 Vesta

Cited by 55 publications

References 98 publications

The rotational motion of Vesta

The rotational motion of Vesta

Vesta and Ceres: Crossing the History of the Solar System

The dynamical environment of asteroid 21 Lutetia according to different internal models

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