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According to the sequential accretion model, giant planet formation is based first on the formation of a solid core which, when massive enough, can gravitationally bind gas from the nebula to form the envelope. In order to trigger the…

Earth and Planetary Astrophysics · Physics 2015-06-11 A. Fortier , Y. Alibert , F. Carron , W. Benz , K. -M. Dittkrist

In the core-accretion model, gas-giant planets form solid cores which then accrete gaseous envelopes. Tidal interactions with disk gas cause a core to undergo inward type-I migration in 10^4 to 10^5 years. Cores must form faster than this…

Astrophysics · Physics 2009-11-11 J. E. Chambers

We investigate accretion of solid materials onto circumplanetary disks from heliocentric orbits rotating in protoplanetary disks, which is a key process for the formation of regular satellite systems. In the late stage of gas-capturing…

Earth and Planetary Astrophysics · Physics 2015-06-18 Takayuki Tanigawa , Akito Maruta , Masahiro N. Machida

We investigate the radiation pressure feedback in the formation of massive stars in 1, 2, and 3D radiation hydrodynamics simulations of the collapse of massive pre-stellar cores. In contrast to previous research, we consider frequency…

Solar and Stellar Astrophysics · Physics 2011-02-18 Rolf Kuiper , Hubert Klahr , Henrik Beuther , Thomas Henning

One of the main scenarios of planet formation is the core accretion model where a massive core forms first and then accretes a gaseous envelope. This core forms by accreting solids, either planetesimals, or pebbles. A key constraint in this…

Earth and Planetary Astrophysics · Physics 2018-11-21 Natacha Brügger , Yann Alibert , Sareh Ataiee , Willy Benz

We study a solid protoplanetary core of 1-10 earth masses migrating through a disk. We suppose the core luminosity is generated as a result of planetesimal accretion and calculate the structure of the gaseous envelope assuming equilibrium.…

Astrophysics · Physics 2009-10-31 J. Papaloizou , C. Terquem

It is widely held that the first step in forming the gas giant planets, such as Jupiter and Saturn, is to form solid `cores' of roughly 10 M$_\oplus$. Getting the cores to form before the solar nebula dissipates ($\sim\!1-10\,$Myr) has been…

Earth and Planetary Astrophysics · Physics 2015-10-09 Harold F. Levison , Katherine A. Kretke , Martin J. Duncan

Pebble accretion has become a popular component to core accretion models of planet formation, and is especially relevant to the formation of compact, resonant terrestrial planetary systems. Pebbles initially form in the inner protoplanetary…

Earth and Planetary Astrophysics · Physics 2019-03-06 Duncan H Forgan

A large fraction of giant planets have gaseous envelopes that are limited to about 10 % of their total mass budget. Such planets are present in the Solar System (Uranus, Neptune) and are frequently observed in short periods around other…

Earth and Planetary Astrophysics · Physics 2017-11-01 Michiel Lambrechts , Elena Lega

Proto-planets embedded in their natal disks acquire hot envelopes as they grow and accrete solids. This ensures that the material they accrete - pebbles, as well as (small) planetesimals - will vaporize to enrich their atmospheres.…

Earth and Planetary Astrophysics · Physics 2020-02-05 M. G. Brouwers , C. W. Ormel

We demonstrate that planet formation via pebble accretion is sensitive to external photoevaporation of the outer disc. In pebble accretion, planets grow by accreting from a flux of solids (pebbles) that radially drift inwards from the…

Earth and Planetary Astrophysics · Physics 2023-04-12 Lin Qiao , Gavin A. L. Coleman , Thomas J. Haworth

To date, there is no core accretion simulation that can successfully account for the formation of Uranus or Neptune within the observed 2-3 Myr lifetimes of protoplanetary disks. Since solid accretion rate is directly proportional to the…

Massive stars may form in or be captured into AGN disks. Recent 1D studies employing stellar-evolution codes have demonstrated the potential for rapid growth of such stars through accretion up to a few hundred $M_\odot$. We perform 3D…

High Energy Astrophysical Phenomena · Physics 2024-08-23 Yi-Xian Chen , Yan-Fei Jiang , Jeremy Goodman , Douglas N. C. Lin

The accretion of pebbles on planetary cores has been widely studied in recent years and is found to be a highly effective mechanism for planetary growth. While most studies assume planetary cores as an initial condition in their simulation,…

Earth and Planetary Astrophysics · Physics 2021-02-10 Oliver Voelkel , Rogerio Deienno , Katherine Kretke , Hubert Klahr

We develop a simple model for computing planetary formation based on the core instability model for the gas accretion and the oligarchic growth regime for the accretion of the solid core. In this model several planets can form…

Astrophysics · Physics 2009-11-13 Yamila Miguel , Adrian Brunini

The growth of a planetary core by pebble accretion stops at the so called pebble isolation mass, when the core generates a pressure bump that traps drifting pebbles outside its orbit. If the isolation mass is very small, then gas accretion…

Earth and Planetary Astrophysics · Physics 2018-04-18 Bertram Bitsch , Alessandro Morbidelli , Anders Johansen , Elena Lega , Michiel Lambrechts , Aurélien Crida

Axisymmetric dust rings containing tens to hundreds of Earth masses of solids have been observed in protoplanetary discs with (sub-)millimetre imaging. Here, we investigate the growth of a planetary embryo in a massive (150M$_\oplus$)…

Earth and Planetary Astrophysics · Physics 2022-07-06 Daniel P. Cummins , James E. Owen , Richard A. Booth

In the core accretion model, gas-giant planets first form a solid core, which then accretes gas from a protoplanetary disk when the core exceeds a critical mass. Here, we model the atmosphere of a core that grows by accreting ice-rich…

Earth and Planetary Astrophysics · Physics 2017-11-08 John Chambers

Thanks to ``dust-to-planet'' simulations (DTPSs), which treat the collisional evolution directly from dust to giant-planet cores in a protoplanetary disk, we showed that giant-planet cores are formed in $\lesssim 10\,$au in several $10^5$…

Earth and Planetary Astrophysics · Physics 2023-07-31 Hiroshi Kobayashi , Hidekazu Tanaka

Close-in super-Earths having radii 1--4 $R_\oplus$ may possess hydrogen atmospheres comprising a few percent by mass of their rocky cores. We determine the conditions under which such atmospheres can be accreted by cores from their parent…

Earth and Planetary Astrophysics · Physics 2015-06-22 Eve J. Lee , Eugene Chiang , Chris W. Ormel