Yarkovsky-O’Keefe-Radzievskii-Paddack effect on tumbling objects

Breiter, S.; Rożek, A.; Vokrouhlický, David

doi:10.1111/j.1365-2966.2011.19411.x

Cited by 18 publications

(14 citation statements)

References 32 publications

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“…Thus the dynamical mechanisms are usually divided into two categories: the net propulsion force changing the orbital motion (the Yarkovsky effect), and the net torque affecting the rotational dynamics (the Yarkovsky-O'Keefe-Radzievskii-Paddack or YORP effect). Both have been observed directly (Chesley 2003;Kaasalainen et al 2007;Lowry et al 2007;Ďurech et al 2008, and there is clear indirect evidence of their long-term role in the evolution of asteroid orbits and spin states (Bottke et al 2001;Vokrouhlický et al 2003Vokrouhlický et al , 2006.…”

Section: Introductionmentioning

confidence: 94%

“…For example, it is easy to identify the enigmatic YORP instability with the "trash coefficients" of a Laplace series, and to show that, while quadrantsymmetric bodies have no secular YORP torques for zero thermal inertia (K = 0), they acquire a nonvanishing component for K 0. Breiter et al (2011;hereafter BRV11) arrive at some of the results of Sect. 3 (K = 0) by a different context and approach.…”

Section: Introductionmentioning

confidence: 99%

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Compact YORP formulation and stability analysis

Kaasalainen

Nortunen

2013

A&A

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We present a concise analytical formulation of the YORP effect, with exact formulae for torques on convex bodies and motionaveraged components applicable to any shapes. We analyze the main features of the secular torques for zero and nonzero thermal inertia that are function series dependent on only a few coefficients. Using these, we investigate the stability of the YORP effect against shape perturbations with analytical and numerical estimates. We define a quantity describing the YORP capacity of any shape, and estimate YORP stability with it.

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Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Compact YORP formulation and stability analysis

Kaasalainen

Nortunen

2013

A&A

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“…This neglects the possibility of a free precession of the angular velocity vector in the body frame (that is, tumbling), which is frequently seen at the slow-rotation state (e.g., Pravec et al 2005). It is very likely that YORP itself naturally drives asteroids to slow rotation and directly triggers the tumbling state (e.g., Vokrouhlický et al 2007;Cicalò & Scheeres 2010;Breiter et al 2011). While it would be too computationally challenging to implement such a complex evolution for the purpose of this paper, we admit that its omission necessarily produces some uncertainty in our work (see below).…”

Section: More Advanced Implementations: the Yarkovsky And Yorp Effectsmentioning

confidence: 99%

Escape of asteroids from the main belt

Granvik

Morbidelli

Vokrouhlický

et al. 2017

A&A

103

115

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Aims. We locate escape routes from the main asteroid belt, particularly into the near-Earth-object (NEO) region, and estimate the relative fluxes for different escape routes as a function of object size under the influence of the Yarkovsky semimajor-axis drift. Methods. We integrated the orbits of 78 355 known and 14 094 cloned main-belt objects and Cybele and Hilda asteroids (hereafter collectively called MBOs) for 100 Myr and recorded the characteristics of the escaping objects. The selected sample of MBOs with perihelion distance q > 1.3 au and semimajor axis a < 4.1 au is essentially complete, with an absolute magnitude limit ranging from H V < 15.9 in the inner belt (a < 2.5 au) to H V < 14.4 in the outer belt (2.5 au < a < 4.1 au). We modeled the semimajor-axis drift caused by the Yarkovsky force and assigned four different sizes (diameters of 0.1, 0.3, 1.0, and 3.0 km) and random spin obliquities (either 0 deg or 180 deg) for each test asteroid. Results. We find more than ten obvious escape routes from the asteroid belt to the NEO region, and they typically coincide with low-order mean-motion resonances with Jupiter and secular resonances. The locations of the escape routes are independent of the semimajor-axis drift rate and thus are also independent of the asteroid diameter. The locations of the escape routes are likewise unaffected when we added a model for Yarkovsky-O'Keefe-Radzievskii-Paddack (YORP) cycles coupled with secular evolution of the rotation pole as a result of the solar gravitational torque. A Yarkovsky-only model predicts a flux of asteroids entering the NEO region that is too high compared to the observationally constrained flux, and the discrepancy grows larger for smaller asteroids. A combined Yarkovsky and YORP model predicts a flux of small NEOs that is approximately a factor of 5 too low compared to an observationally constrained estimate. This suggests that the characteristic timescale of the YORP cycle is longer than our canonical YORP model predicts.

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“…This simple model sidesteps known issues with how an asteroid's rotational dynamics evolves when it gets to a slow spin rate. Previous investigations have detected a statistically larger number of slowly rotating asteroids [28,33], which could be a signature of more complex rotational evolution and a slow-down in the rate at which a body's spin rate varies [51,7,3]. We do not pursue this topic here, however, and instead use a simple model which could be adjusted by a scale factor, once a consistent theory for the evolution of a slowly-rotating and tumbling asteroid is developed.…”

Section: Time Between Fission Eventsmentioning

confidence: 99%

Disaggregation of small, cohesive rubble pile asteroids due to YORP

Scheeres

2018

Icarus

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The implication of small amounts of cohesion within relatively small rubble pile asteroids is investigated with regard to their evolution under the persistent presence of the YORP effect. We find that below a characteristic size, which is a function of cohesive strength, density and other properties, rubble pile asteroids can enter a "disaggregation phase" in which they are subject to repeated fissions after which the formation of a stabilizing binary system is not possible. Once this threshold is passed rubble pile asteroids may be disaggregated into their constituent components within a finite time span. These constituent components will have their own spin limits -albeit potentially at a much higher spin rate due to the greater strength of a monolithic body. The implications of this prediction are discussed and include modification of size distributions, prevalence of monolithic bodies among meteoroids and the lifetime of small rubble pile bodies in the solar system. The theory is then used to place constraints on the strength of binary asteroids characterized as a function of their type.

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Yarkovsky-O’Keefe-Radzievskii-Paddack effect on tumbling objects

Cited by 18 publications

References 32 publications

Compact YORP formulation and stability analysis

Compact YORP formulation and stability analysis

Escape of asteroids from the main belt

Disaggregation of small, cohesive rubble pile asteroids due to YORP

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