Millimeter Spectral Indices and Dust Trapping By Planets in Brown Dwarf Disks

TL;DR

This study investigates dust grain sizes and distribution in brown dwarf disks using millimeter observations, finding that dust trapping by planets alone cannot explain the observed large grains, suggesting alternative mechanisms.

Contribution

It provides new millimeter observations of brown dwarf disks and evaluates dust trapping models, proposing alternative explanations for large grain presence.

Findings

Low millimeter spectral indices indicate large grains in BD disks.

Dust trapping by planets cannot fully explain the observations.

Alternative mechanisms like low gas mass or fluffy aggregate growth are suggested.

Abstract

Disks around brown dwarfs (BDs) are excellent laboratories to study the first steps of planet formation in cold and low-mass disk conditions. The radial-drift velocities of dust particles in BD disks are higher than in disks around more massive stars. Therefore, BD disks are expected to be more depleted in millimeter-sized grains compared to disks around T Tauri or Herbig Ae/Be stars. However, recent millimeter observations of BD disks revealed low millimeter spectral indices, indicating the presence of large grains in these disks and challenging models of dust evolution. We present 3\,mm photometric observations carried out with the IRAM/Plateau de Bure Interferometer (PdBI) of three BD disks in the Taurus star forming region, which have been observed with ALMA at 0.89\,mm. The disks were not resolved and only one was detected with enough confidence ($\sim3.5\sigma$) with PdBI. Based on these observations, we obtain the values and lower limits of the spectral index and find low values ($\alpha_{\rm{mm}}\lesssim 3.0$). We compare these observations in the context of particle trapping by an embedded planet, a promising mechanism to explain the observational signatures in more massive and warmer disks. We find, however, that this model cannot reproduce the current millimeter observations for BD disks, and multiple-strong pressure bumps globally distributed in the disk remain as a favorable scenario to explain observations. Alternative possibilities are that the gas masses in BD disk are very low ($\sim2\times10^{-3}\,M_{\rm{Jup}}$) such that the millimeter grains are decoupled and do not drift, or fast growth of fluffy aggregates.