Thermochemical modelling of brown dwarf disks

A. J. Greenwood, I. Kamp, L. B. F. M. Waters, P. Woitke, W. -F. Thi, Ch. Rab, G. Aresu, M. Spaans

Published 2017-02-15Version 1

The physical properties of brown dwarf disks, in terms of their shapes and sizes, are still largely unexplored by observations. To what extent brown dwarf disks are similar to scaled-down T Tauri disks is poorly known, and this work is a step towards understanding these differences. We use observations of the brown dwarf disk $\rho$ Oph 102 to infer a fiducial model around which we build a small grid of brown dwarf disk models, in order to model the CO, HCN, and HCO+ line fluxes and the chemistry which drives their abundances. These are the first brown dwarf models to be published which relate detailed, 2D radiation thermochemical disk models to observational data. We predict that moderately extended ALMA antenna configurations will spatially resolve CO line emission around brown dwarf disks, and that HCN and HCO+ will be detectable in integrated flux, following our conclusion that the flux ratios of these molecules to CO emission are comparable to that of T Tauri disks. These molecules have not yet been observed in sub-mm wavelengths in a brown dwarf disk, yet they are crucial tracers of the warm surface-layer gas and of ionization in the outer parts of the disk. We present the prediction that if the physical and chemical processes in brown dwarf disks are similar to those that occur in T Tauri disks -- as our models suggest -- then the same diagnostics that are used for T Tauri disks can be used for brown dwarf disks (such as HCN and HCO+ lines that have not yet been observed in the sub-mm), and that these lines should be observable with ALMA. Through future observations, either confirmation (or refutation) of these ideas about brown dwarf disk chemistry will have strong implications for our understanding of disk chemistry, structure, and subsequent planet formation in brown dwarf disks.