The Active Asteroids

Jewitt, David

doi:10.1088/0004-6256/143/3/66

Cited by 286 publications

(250 citation statements)

References 88 publications

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“…The main mechanisms that can induce a relevant mass loss for active (comet-like) or inactive asteroids are ice sublimation and impact ejection (Jewitt 2012). The latter process occurs when smaller asteroids impact larger ones 6 .…”

Section: Water Mass Loss Processmentioning

confidence: 99%

“…Therefore, we used an averaged albedo A 1 = A 2 =Ā = 0.05; − R is the distance to the star (primary or secondary) expressed in au; − θ is the angle between the incident light and the normal to the asteroid's surface. According to Jewitt (2012),ṁ is weaker for an isothermal surface than at the subsolar point of a nonrotating body. Again, to maximizeṁ, we consider the subsolar case with θ = 0 • ; − is the emissivity of the surface, ∼ 0.9; − σ = 5.67 × 10 −8 W m −2 K −4 is the Boltzmann constant; − T is the equilibrium temperature at the surface expressed in K; − L is the latent heat of sublimation in J kg −1 ; −ṁ is the surface mass loss rate in kg m −2 s −1 .…”

Section: Water Mass Loss Processmentioning

confidence: 99%

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Asteroid flux towards circumprimary habitable zones in binary star systems

Bancelin

Pilat-Lohinger

Eggl

et al. 2015

A&A

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Context. So far, more than 130 extrasolar planets have been found in multiple stellar systems. Dynamical simulations show that the outcome of the planetary formation process can lead to different planetary architecture (i.e. location, size, mass, and water content) when the star system is single or double. Aims. In the late phase of planetary formation, when embryo-sized objects dominate the inner region of the system, asteroids are also present and can provide additional material for objects inside the habitable zone (HZ). In this study, we make a comparison of several binary star systems and how efficient they are at moving icy asteroids from beyond the snow line into orbits crossing the HZ. Methods. We modelled a belt of 10 000 asteroids (remnants from the late phase of the planetary formation process) beyond the snow line. The planetesimals are placed randomly around the primary star and move under the gravitational influence of the two stars and a gas giant. As the planetesimals do not interact with each other, we divided the belt into 100 subrings which were integrated separately. In this statistical study, several double star configurations with a G-type star as primary are investigated. Results. Our results show that small bodies also participate in bearing a non-negligible amount of water to the HZ. The proximity of a companion moving on an eccentric orbit increases the flux of asteroids to the HZ, which could result in a more efficient water transport on a short timescale, causing a heavy bombardment. In contrast to asteroids moving under the gravitational perturbations of one G-type star and a gas giant, we show that the presence of a companion star not only favours a faster depletion of our disk of planetesimals, but can also bring 4-5 times more water into the whole HZ.

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Section: Water Mass Loss Processmentioning

confidence: 99%

Section: Water Mass Loss Processmentioning

confidence: 99%

Asteroid flux towards circumprimary habitable zones in binary star systems

Bancelin

Pilat-Lohinger

Eggl

et al. 2015

A&A

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“…Below, Figure 4 shows nine of the eleven active asteroids that have been discovered as of March 2012 (Jewitt, 2012). All of these objects, including P/2013 P5, resemble comets in their appearance, making the asteroid-comet categorization more complex.…”

Section: Small Bodiesmentioning

confidence: 99%

“…On the other hand, the concept of asteroids having a comet-like appearance was puzzling to astronomers who were unsure of how an asteroid, with a limited amount of volatile material, would begin to generate mass loss. Jewitt (2012) describes the eleven current explanations for how asteroids can lose mass. These explanations fall under three main processes related to collisional events, near-surface ice sublimation, and rotational fission.…”

Section: Reasons For Mass Lossmentioning

confidence: 99%

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Rotational Properties of the Extraordinary Multi-tailed Asteroid P/2013 P5

Gustafsson¹

2015

OURJ

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Observations made with the Hubble Space Telescope in September 2013 revealed that the asteroid known as P/2013 P5 appeared to have six comet-like tails. Jewitt et al. (2013) concluded that this extraordinary structure and activity could not be explained by traditional near-surface ice sublimation or collision events ejecting particles from the asteroid's surface. Instead, the most likely explanation is that this unusual object has been spun-up by solar radiation forces to a critical limit which has resulted in the rotational disruption of the asteroid causing the unique six-tail structure. This interpretation predicts that the nucleus of this comet-like asteroid should be in rapid rotation. In November 2013, broadband photometry of P/2013 P5 was obtained with Lowell Observatory's 4.3-meter Discovery Channel Telescope using the Large Monolithic Imager to investigate the possibility of rapid rotation. While the variation in the rotational light curve from these data was too small to be justifiable, morphological changes in the nucleus-coma system were observed.

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Study of the physical properties of selected active objects in the main belt and surrounding regions by broadband photometry

et al. 2020

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Dynamically different groups of comets and active asteroids with orbits at 2-5 a. u. show dust activity in varying degrees and forms. A photometric study and comparison of physical parameters can help to classify the mechanisms and nature of the activity for such objects. We present new observations using broadband photometry of 15 active objects in the main asteroid belt and surrounding regions obtained during 2012-2016. The study aims to compare the physical properties of main-belt comets (MBCs), quasi-Hilda comets (QHCs), and active asteroids (AAs). The observations were carried out with the 0.7-m telescope of the Kyiv Comet Station, Ukraine, and with the 1.23-m telescope at the Calar Alto Observatory, Spain, using Blue, Visual, Red (BVR) broadband filters. Upper limits for the nuclear radii, Afρ parameters, and color indices were measured. The results of 2012-2016 observations suggest that there exist systematic differences in the physical parameters of MBCs and QHCs.

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The Active Asteroids

Cited by 286 publications

References 88 publications

Asteroid flux towards circumprimary habitable zones in binary star systems

Asteroid flux towards circumprimary habitable zones in binary star systems

Rotational Properties of the Extraordinary Multi-tailed Asteroid P/2013 P5

Study of the physical properties of selected active objects in the main belt and surrounding regions by broadband photometry

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