English

Explaining millimeter-sized particles in brown dwarf disks

Earth and Planetary Astrophysics 2013-05-20 v1

Abstract

Planets have been detected around a variety of stars, including low-mass objects, such as brown dwarfs. However, such extreme cases are challenging for planet formation models. Recent sub-millimeter observations of disks around brown dwarf measured low spectral indices of the continuum emission that suggest that dust grains grow to mm-sizes even in these very low mass environments. To understand the first steps of planet formation in scaled-down versions of T-Tauri disks, we investigate the physical conditions that can theoretically explain the growth from interstellar dust to millimeter-sized grains in disks around brown dwarf. We modeled the evolution of dust particles under conditions of low-mass disks around brown dwarfs. We used coagulation, fragmentation and disk-structure models to simulate the evolution of dust, with zero and non-zero radial drift. For the non-zero radial drift, we considered strong inhomogeneities in the gas surface density profile that mimic long-lived pressure bumps in the disk. We studied different scenarios that could lead to an agreement between theoretical models and the spectral slope found by millimeter observations. We find that fragmentation is less likely and rapid inward drift is more significant for particles in brown dwarf disks than in T-Tauri disks. We present different scenarios that can nevertheless explain millimeter-sized grains. As an example, a model that combines the following parameters can fit the millimeter fluxes measured for brown dwarf disks: strong pressure inhomogeneities of \sim 40% of amplitude, a small radial extent \sim 15 AU, a moderate turbulence strength αturb=103\alpha_{\mathrm{turb}}= 10^{-3}, and average fragmentation velocities for ices vf=10ms1v_f = 10 m s^{-1}.

Keywords

Cite

@article{arxiv.1304.6638,
  title  = {Explaining millimeter-sized particles in brown dwarf disks},
  author = {P. Pinilla and T. Birnstiel and M. Benisty and L. Ricci and A. Natta and C. P. Dullemond and C. Dominik and L. Testi},
  journal= {arXiv preprint arXiv:1304.6638},
  year   = {2013}
}

Comments

Accepted for publication in A\& A

R2 v1 2026-06-22T00:05:39.098Z