High albedos of low inclination Classical Kuiper belt objects

Brucker, M. J.; Grundy, W. M.; Stansberry, J.; Spencer, J. R.; Sheppard, Scott S.; Chiang, Eugene; Buie, M. W.

doi:10.1016/j.icarus.2008.12.040

Cited by 120 publications

(179 citation statements)

References 59 publications

(68 reference statements)

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“…The apparent visual magnitude was then calculated, assuming observation at opposition, from (Trujillo & Brown 2001) m v = m −2.5 log[pr 2 ]+2.5 log(2.25×10 16 R 2 (R−1) 2 ), (5) where m = −26.75 is the apparent V magnitude of the sun, p the albedo, r the radius of the body, and R the heliocentric distance. The albedo was assumed to be 6% for all bodies, consistent with the CFEPS model, but likely an underestimate by a factor of ∼2-4 for the cold classical KBOs (Brucker et al 2009). …”

Section: Methodsmentioning

confidence: 99%

“…The first of these is the classical belt, consisting of a dynamically cold population at low inclination and a dynamically excited (hot) population at inclinations larger than ∼5 • . Besides evidence for these two populations in the inclination distribution (Brown 2001), they are also apparently distinct in eccentricity ), color (Peixinho et al 2008), absolute magnitude (Levison & Stern 2001), albedos (Brucker et al 2009), binary fraction (Noll et al 2008), and differential size distribution (Fraser et al 2010). A second population is inherently unstable on ∼Gyr timescales and is known as scattered disk objects, since they are in orbits that are scattering off of Neptune, usually with perihelia below ∼35-40 AU.…”

Section: Introductionmentioning

confidence: 99%

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Identifying Collisional Families in the Kuiper Belt

Marcus

Ragozzine

Murray-Clay

et al. 2011

ApJ

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The identification and characterization of numerous collisional families-clusters of bodies with a common collisional origin-in the asteroid belt has added greatly to the understanding of asteroid belt formation and evolution. More recent study has also led to an appreciation of physical processes that had previously been neglected (e.g., the Yarkovsky effect). Collisions have certainly played an important role in the evolution of the Kuiper Belt as well, though only one collisional family has been identified in that region to date, around the dwarf planet Haumea. In this paper, we combine insights into collisional families from numerical simulations with the current observational constraints on the dynamical structure of the Kuiper Belt to investigate the ideal sizes and locations for identifying collisional families. We find that larger progenitors (r ∼ 500 km) result in more easily identifiable families, given the difficulty in identifying fragments of smaller progenitors in magnitude-limited surveys, despite their larger spread and less frequent occurrence. However, even these families do not stand out well from the background. Identifying families as statistical overdensities is much easier than characterizing families by distinguishing individual members from interlopers. Such identification seems promising, provided the background population is well known. In either case, families will also be much easier to study where the background population is small, i.e., at high inclinations. Overall, our results indicate that entirely different techniques for identifying families will be needed for the Kuiper Belt, and we provide some suggestions.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Identifying Collisional Families in the Kuiper Belt

Marcus

Ragozzine

Murray-Clay

et al. 2011

ApJ

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“…Obtaining size/albedo values for a larger sample is best achieved from thermal radiometry, whereby thermal and optical observations are combined within a thermal model. After the pioneering measurements on two objects from ISO (Thomas et al 2000) and ground-based observations on a few others (see Stansberry et al 2008, and references therein), Spitzer provided the first large such dataset, with about 60 Centaurs/KBOs measured at 24 and/or 70 μm (Cruikshank et al 2005;Grundy et al 2005Grundy et al , 2007Stansberry et al 2006Stansberry et al , 2008Brucker et al 2009). This approach (multi-wavelength photometry) also constrains the thermal regime of the object, phenomenologically described by the "beaming factor" (Jones & Morrison 1974;Lebofsky & Spencer 1989;Harris 1998).…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, correlations between size, albedo, color, composition and orbital parameters may provide diagnostics on the dynamical, collisional and physical history of KBOs. The size distribution of TNOs is also a diagnostic relating to that history, but in the absence of measured sizes the distribution has typically been estimated from the luminosity function and an assumed albedo, an uncertain step given that the average albedos seem to be different for the different dynamical populations (Grundy et al 2005;Brucker et al 2009). Instead, and to constrain Kuiper belt formation/evolution models it is desirable to directly determine the size distribution of the different populations, and infer their individual total masses.…”

Section: Introductionmentioning

confidence: 99%

“TNOs are Cool”: A survey of the trans-Neptunian region

Santos-Sanz

Lellouch

Fornasier

et al. 2012

A&A

145

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Context. Physical characterization of trans-Neptunian objects, a primitive population of the outer solar system, may provide constraints on their formation and evolution. Aims. The goal of this work is to characterize a set of 15 scattered disk (SDOs) and detached objects, in terms of their size, albedo, and thermal properties. Methods. Thermal flux measurements obtained with the Herschel-PACS instrument at 70, 100 and 160 μm, and whenever applicable, with Spitzer-MIPS at 24 and 70 μm, are modeled with radiometric techniques, in order to derive the objects' individual size, albedo and when possible beaming factor. Error bars are obtained from a Monte-Carlo approach. We look for correlations between these and other physical and orbital parameters. Results. Diameters obtained for our sample range from 100 to 2400 km, and the geometric albedos (in V band) vary from 3.8% to 84.5%. The unweighted mean V geometric albedo for the whole sample is 11.2% (excluding Eris); 6.9% for the SDOs, and 17.0% for the detached objects (excluding Eris). We obtain new bulk densities for three binary systems: Ceto/Phorcys, Typhon/Echidna and Eris/Dysnomia. Apart from correlations clearly due to observational bias, we find significant correlations between albedo and diameter (more reflective objects being bigger), and between albedo, diameter and perihelion distance (brighter and bigger objects having larger perihelia). We discuss possible explanations for these correlations.

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“…Orbit of a satellite: From optical or radar images of the components of the system, their mutual orbit can be determined and the mass derived with Kepler's third law (see, for instance, Petit et al 1997; Merline et al 1999 Merline et al , 2002 Margot et al 2002; Marchis et al 2005b Marchis et al , 2008aBrown et al 2005Brown et al , 2010Carry et al 2011;Fang et al 2011). The 28 mass estimates available for TNOs were derived from optical imaging with the Hubble space telescope or large ground-based telescopes equipped with adaptiveoptics cameras (e.g., Grundy et al 2009;Dumas et al 2011). Similarly, the 17 mass estimates for NEAs were all derived from radar (e.g., Ostro et al 2006; Shepard et al 2006), with the exception of Itokawa which was the target of the Hayabusa sample-return mission (Fujiwara et al 2006).…”

mentioning

confidence: 99%

Density of asteroids

Carry

2012

Planetary and Space Science

517

444

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The small bodies of our solar system are the remnants of the early stages of planetary formation. A considerable amount of information regarding the processes that occurred during the accretion of the early planetesimals is still present among this population. A review of our current knowledge of the density of small bodies is presented here. Density is indeed a fundamental property for the understanding of their composition and internal structure. Intrinsic physical properties of small bodies are sought by searching for relationships between the dynamical and taxonomic classes, size, and density. Mass and volume estimates for 287 small bodies (asteroids, comets, and transneptunian objects) are collected from the literature. The accuracy and biases affecting the methods used to estimate these quantities are discussed and best-estimates are strictly selected. Bulk densities are subsequently computed and compared with meteorite density, allowing to estimate the macroporosity (i.e., amount of voids) within these bodies. Dwarf-planets apparently have no macroporosity, while smaller bodies (<400 km) can have large voids. This trend is apparently correlated with size: C and S-complex asteroids tends to have larger density with increasing diameter. The average density of each Bus-DeMeo taxonomic classes is computed (DeMeo et al., 2009, Icarus 202). S-complex asteroids are more dense on average than those in the C-complex that in turn have a larger macroporosity, although both complexes partly overlap. Within the C-complex asteroids, B-types stand out in albedo, reflectance spectra, and density, indicating a unique composition and structure. Asteroids in the Xcomplex span a wide range of densities, suggesting that many compositions are included in the complex. Comets and TNOs have high macroporosity and low density, supporting the current models of internal structures made of icy aggregates. Although the number of density estimates sky-rocketed during last decade from a handful to 287, only a third of the estimates are more precise than 20%. Several lines of investigation to refine this statistic are contemplated, including observations of multiple systems, 3-D shape modeling, and orbital analysis from Gaia astrometry.Keywords: Minor planets, Mass, Volume, Density, Porosity Small bodies as remnants of planetesimalsThe small bodies of our solar System are the left-overs of the building blocks that accreted to form the planets, some 4.6 Gyr ago. They represent the most direct witnesses of the conditions that reigned in the proto-planetary nebula (Bottke et al. 2002a). Indeed, terrestrial planets have thermally evolved and in some cases suffered erosion (e.g., plate tectonic, volcanism) erasing evidence of their primitive composition. For most small bodies, however, their small diameter limited the amount of radiogenic nuclides in their interior, and thus the amount of energy for internal heating. The evolution of small bodies is therefore mainly exogenous, through eons of collisions, external heating, and bombardm...

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High albedos of low inclination Classical Kuiper belt objects

Cited by 120 publications

References 59 publications

Identifying Collisional Families in the Kuiper Belt

Identifying Collisional Families in the Kuiper Belt

“TNOs are Cool”: A survey of the trans-Neptunian region

Density of asteroids

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