Evolution of Mercury-like orbits: A numerical study

Warell, J.; Karlsson, O.; Skoglöv, Erik

doi:10.1051/0004-6361:20030902

Cited by 7 publications

(4 citation statements)

References 37 publications

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“…These results are consistent with those obtained by Gladman (2003) for slightly different initial conditions. Warrel et al (2003) found that hermeocentric and 1:1 Mercury mean motion resonance orbits can be stable for long time periods, but that ejecta with velocities only slightly greater than the escape velocity are likely to be reaccreted due to the necessity of successive close encounters with Mercury to achieve significant gravitational scattering. They did not, however, provide a numerical result.…”

Section: Collision Time and Gravitational Scatteringmentioning

confidence: 99%

The Origin of Mercury

et al. 2007

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Mercury's unusually high mean density has always been attributed to special circumstances that occurred during the formation of the planet or shortly thereafter, and due to the planet's close proximity to the Sun. The nature of these special circumstances is still being debated and several scenarios, all proposed more than 20 years ago, have been suggested. In all scenarios, the high mean density is the result of severe fractionation occurring between silicates and iron. It is the origin of this fractionation that is at the centre of the debate: is it due to differences in condensation temperature and/or in material characteristics (e.g. density, strength)? Is it because of mantle evaporation due to the close proximity to the Sun? Or is it due to the blasting off of the mantle during a giant impact?In this paper we investigate, in some detail, the fractionation induced by a giant impact on a proto-Mercury having roughly chondritic elemental abundances. We have extended the previous work on this hypothesis in two significant directions. First, we have considerably increased the resolution of the simulation of the collision itself. Second, we have addressed the fate of the ejecta following the impact by computing the expected reaccretion timescale and comparing it to the removal timescale from gravitational interactions with other planets (essentially Venus) and the Poynting-Robertson effect. To compute the latter, we have determined the expected size distribution of the condensates formed during the cooling of the expanding vapor cloud generated by the impact.We find that, even though some ejected material will be reaccreted, the removal of the mantle of proto-Mercury following a giant impact can indeed lead to the required long-term fractionation between silicates and iron and therefore account for the anomalously high mean density of the planet. Detailed coupled dynamical-chemical modeling of this formation mechanism should be carried out in such a way as to allow explicit testing of the giant impact hypothesis by forthcoming space missions (e.g. MESSENGER and BepiColombo).

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Section: Collision Time and Gravitational Scatteringmentioning

confidence: 99%

The Origin of Mercury

et al. 2007

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“…Mercury could have its own Trojan asteroids, though they would last only 20 kyr (Warell et al 2003) and does have its own magnetic field, for reasons that remain under discussion (Aharonson et al 2004, who have resurrected a fossil field). It used to have a chaotic relationship between its orbital and rotation periods, from which the 3 : 2 resonance was captured (Correia & Laskar 2004).…”

Section: The Major Planetsmentioning

confidence: 99%

Astrophysics in 2004

Trimble

Aschwanden

2005

PUBL ASTRON SOC PAC

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“…From the foregoing, therefore, it may be argued that there are at least two good reasons why the solar system might have supported a primordial population of Vulcanoid asteroids -either as the result of direct planetesimal growth, or via the destruction of two or more closely-packed planets. To these scenarios we can additionally add the process of Hermian Trojan capture [23], as well as the inward evolution of cometary nuclei, near-Earth asteroids and assorted collisional ejecta from the outer solar system [24].…”

Section: A Brief Historical Introductionmentioning

confidence: 99%

“…That the Vulcanoid zone is far from being a dynamically inactive region of the solar system is evidenced by the fact that both asteroids and cometary nuclei are regularly observed to pass through its borders in the modern era [23]. A search of the JPL Small-Body database, for example, reveals that at the present epoch there are 244 asteroids that cross the orbit of Mercury with perihelion distances located within the Vulcanoid zone.…”

Section: A Brief Historical Introductionmentioning

confidence: 99%

The Vulcanoid Asteroids: Past, Present and Future

Beech¹

2017

AJAA

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Abstract:A review and discussion of both the historical and contemporaneous ideas pertaining to the putative population of Vulcanoid asteroids is presented. Current observations indicate that no objects larger than between 5 to 10 km in diameter reside in the orbital stability zone between 0.06 and 0.2 AU from the Sun, and that, at best, only a small population of Vulcanoid asteroids might exist at the present epoch. We review the physical processes (sublimation mass loss, evolution of the Sun's luminosity, Poynting-Robertson drag, the Yarkovsky effect, the YORP effect, unipolar heating and collisions) that will control the lifetime against destruction of objects, either primordial or present-day, that chance to reside in the Vulcanoid region. It is argued that there are no overriding and/or absolute physical mechanisms that fully rule-out the present-day existence of a small Vulcanoid population, but we note that the gap between what the observations allow and what the theoretical models deem possible is closing rapidly.

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Evolution of Mercury-like orbits: A numerical study

Cited by 7 publications

References 37 publications

The Origin of Mercury

The Origin of Mercury

Astrophysics in 2004

The Vulcanoid Asteroids: Past, Present and Future

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