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We compute the accretion efficiency of small solids, with radii 1 cm Rs 10 m, on planets embedded in gaseous disks. Planets have masses 3 Mp 20 Earth masses (Me) and orbit within 10 AU of a solar-mass star. Disk thermodynamics is modeled via three-dimensional radiation-hydrodynamic calculations that typically resolve the planetary envelopes. Both icy and rocky solids are considered, explicitly modeling their thermodynamic evolution. The maximum efficiencies of 1 Rs 100 cm particles are generally 10%, whereas 10 m solids tend to accrete efficiently or be segregated beyond the planet's orbit. A simplified approach is applied to compute the accretion efficiency of small cores, with masses Mp 1 Me and without envelopes, for which efficiencies are approximately proportional to Mp^ (2/3). The mass flux of solids, estimated from unperturbed drag-induced drift velocities, provides typical accretion rates dMp/dt 1e-5 Mearth/yr. In representative disk models with an initial gas-to-dust mass ratio of 70-100 and total mass of 0. 05-0. 06 Msun, solids' accretion falls below 1e-6 Mearth/yr after 1-1. 5 million years (Myr). The derived accretion rates, as functions of time and planet mass, are applied to formation calculations that compute dust opacity self-consistently with the delivery of solids to the envelope. Assuming dust-to-solid coagulation times of approximately 0. 3 Myr and disk lifetimes of approximately 3. 5 Myr, heavy-element inventories in the range 3-7 Me require that approximately 90-150 Me of solids cross the planet's orbit. The formation calculations encompass a variety of outcomes, from planets a few times the Earth mass, predominantly composed of heavy elements, to giant planets. The peak luminosities during the epoch of solids' accretion range from 1e-7 to 1e-6 times the solar luminosity.
D’Angelo et al. (Mon,) studied this question.
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