Constraining the detectability of water ice in debris disks

TL;DR

This study assesses the potential to detect water ice in debris disks by modeling ice destruction mechanisms, dust properties, and synthetic observables, highlighting key spectral features and the influence of physical conditions on detectability.

Contribution

It introduces a comprehensive modeling approach considering ice destruction processes and dust properties to evaluate water ice detectability in debris disks.

Findings

Water ice features at ~3 μm and 44 μm can be detected with JWST and SPICA.

Ice destruction mechanisms significantly influence debris disk observability.

Porous ice produces highly polarized radiation around 3 μm.

Abstract

Water ice is important for the evolution and preservation of life. Identifying the distribution of water ice in debris disks is therefore of great interest in the field of astrobiology. Furthermore, icy dust grains are expected to play important roles throughout the entire planet formation process. However, currently available observations only allow deriving weak conclusions about the existence of water ice in debris disks. We investigate whether it is feasible to detect water ice in typical debris disk systems. We take the following ice destruction mechanisms into account: sublimation of ice, dust production through planetesimal collisions, and photosputtering by UV-bright central stars. We consider icy dust mixture particles with various shapes consisting of amorphous ice, crystalline ice, astrosilicate, and vacuum inclusions. We calculated optical properties of inhomogeneous icy dust mixtures using effective medium theories, that is, Maxwell-Garnett rules. Subsequently, we generated synthetic debris disk observables, such as spectral energy distributions and spatially resolved thermal reemission and scattered light intensity and polarization maps with our code DMS. We find that the prominent $\sim$ 3 $\mu\rm{m}$ and 44 $\mu\rm{m}$ water ice features can be potentially detected in future observations of debris disks with the James Webb Space Telescope and the Space Infrared telescope for Cosmology and Astrophysics. We show that the sublimation of ice, collisions between planetesimals, and photosputtering caused by UV sources clearly affect the observational appearance of debris disk systems. In addition, highly porous ice tends to produce highly polarized radiation at around 3 $\mu\rm{m}$. Finally, the location of the ice survival line is determined by various dust properties such as a fractional ratio of ice versus dust, physical states of ice, and the porosity of icy grains.