Accretion in the Early Kuiper Belt. II. Fragmentation

Kenyon, Scott J.; Luu, Jane

doi:10.1086/300969

Cited by 176 publications

(254 citation statements)

References 85 publications

Supporting

Mentioning

235

Contrasting

Order By: Relevance

“…Most of them have diameters (D) larger than 100 km, while there are roughly a dozen giant objects with diameters of about 1000 km or more, such as Pluto 1 MPCs: http://www.cfa.harvard.edu/iau/lists/TNOs.html (D ≈ 2320 km) and 2003 UB313 (D ≈ 2400 km). Previous studies show that the current belt mass between 30 and 50 AU of less than 0.1 M ⊕ could not produce the KBOs in situ (Stern 1996;Stern & Colwell 1997;Kenyon & Luu 1998;Kenyon & Luu 1999). Thus, the KBOs should form in a denser region much closer to the Sun and were subsequently transported outwards to their present locations (Levison & Morbidelli 2003;Gomes 2003).…”

Section: Formation Of Kbo-sized Planetesimalsmentioning

confidence: 94%

Evolution of Jovian planets in a self-gravitating planetesimal disk

Zhou

Sun

2011

A&A

View full text Add to dashboard Cite

Aims. We explore the orbital evolution of the four Jovian planets embedded in a self-gravitating planetesimal disk, along with the simultaneous accretion of small bodies by proto-Uranus and proto-Neptune. Methods. We adopt the code NBODY4 running on the GRAPE-type special-purpose computer for numerically simulating the primordial evolution of the outer Solar System, where the total gravitational forces due to the Sun, the four Jovian planets, and the massive planetesimals are all taken into account.Results. There is no significant accretion of proto-Uranus and proto-Neptune during their migration stage, only on the order of 0.1 Earth mass. The self-gravitating disk can provide a new replenishment of planetesimals outside a few AU beyond Neptune into the scattering zone, resulting in larger radial displacement of Neptune than in the non-self-gravitating disk. The present location of Neptune requires an original planetesimal disk outer edge at ∼35 AU. The distribution of the surviving planetesimals is very similar to the observed Kuiper belt.

show abstract

Section: Formation Of Kbo-sized Planetesimalsmentioning

confidence: 94%

Evolution of Jovian planets in a self-gravitating planetesimal disk

Zhou

Sun

2011

A&A

View full text Add to dashboard Cite

show abstract

“…In Sections 9 and 10, we provide appropriate expressions for during oligarchy, an important stage of planet formation. However, at earlier times, must be obtained by solving an integro-differential equation ( Kenyon & Luu (1999) have proposed, it is a frozen image of the formation epoch. In the following, we treat as a free function.…”

Section: Two-groups Approximationmentioning

confidence: 99%

Planet Formation by Coagulation: A Focus on Uranus and Neptune

Goldreich

Lithwick

Sari

2004

Annu. Rev. Astron. Astrophys.

282

375

View full text Add to dashboard Cite

■ Abstract Planets form in the circumstellar disks of young stars. We review the basic physical processes by which solid bodies accrete each other and alter each others' random velocities, and we provide order-of-magnitude derivations for the rates of these processes. We discuss and exercise the two-groups approximation, a simple yet powerful technique for solving the evolution equations for protoplanet growth. We describe orderly, runaway, neutral, and oligarchic growth. We also delineate the conditions under which each occurs. We refute a popular misconception by showing that the outer planets formed quickly by accreting small bodies. Then we address the final stages of planet formation. Oligarchy ends when the surface density of the oligarchs becomes comparable to that of the small bodies. Dynamical friction is no longer able to balance viscous stirring and the oligarchs' random velocities increase. In the innerplanet system, oligarchs collide and coalesce. In the outer-planet system, some of the oligarchs are ejected. In both the inner-and outer-planet systems, this stage ends once the number of big bodies has been reduced to the point that their mutual interactions no longer produce large-scale chaos. Subsequently, dynamical friction by the residual small bodies circularizes and flattens their orbits. The final stage of planet formation involves the clean up of the residual small bodies. Clean up has been poorly explored.

show abstract

“…There are at least two reasons to question this assumption. First, conglomeration models (Kenyon & Luu 1999;Kenyon & Bromley 2001) typically require a few 10 7 years to produce Pluto-like bodies in a Kuiper-belt-like environment, with the timescale increasing as one moves away from the star. 7 This will delay the onset of the debris phase.…”

Section: Age Of the Debris Disk = Age Of The Star?mentioning

confidence: 99%

“…The value of q is then reduced to ≈4 (Morishima et al 2008). Using particles-in-a-box simulations and later hybrid simulations, Kenyon & Luu (1999) and Kenyon & Bromley (2004b followed the growth of planetesimals. They also found that q decreases with time after the runaway phase, finishing up with 3.75 q 4.5 for planetesimals of sizes between 10 and 1000 km.…”

Section: Introductionmentioning

confidence: 99%

Planetesimals in Debris Disks of Sun-Like Stars

Shannon

2011

ApJ

View full text Add to dashboard Cite

Observations of dusty debris disks can be used to test theories of planetesimal coagulation. Planetesimals of sizes up to a couple of thousand kilometers are embedded in these disks and their mutual collisions generate the small dust grains that are observed. The dust luminosities, when combined with information on the dust spatial extent and the system age, can be used to infer initial masses in the planetesimal belts. Carrying out such a procedure for a sample of debris disks around Sun-like stars, we reach the following two conclusions. First, if we assume that colliding planetesimals satisfy a primordial size spectrum of the form dn/ds ∝ s −q , observed disks strongly favor a value of q between 3.5 and 4, while both current theoretical expectations and statistics of Kuiper belt objects favor a somewhat larger value. Second, number densities of planetesimals are two to three orders of magnitude higher in detected disks than in the Kuiper belt, for comparably sized objects. This is a surprise for the coagulation models. It would require a similar increase in the disk surface density over that of the Minimum Mass Solar Nebula, which is unreasonable. Both of our conclusions are driven by the need to explain the presence of bright debris disks at a few gigayears of age.

show abstract

Accretion in the Early Kuiper Belt. II. Fragmentation

Cited by 176 publications

References 85 publications

Evolution of Jovian planets in a self-gravitating planetesimal disk

Evolution of Jovian planets in a self-gravitating planetesimal disk

Planet Formation by Coagulation: A Focus on Uranus and Neptune

Planetesimals in Debris Disks of Sun-Like Stars

Contact Info

Product

Resources

About