Neglected Clouds in T and Y Dwarf Atmospheres

TL;DR

This study investigates the impact of neglected sulfide and salt clouds on the atmospheres of T and Y dwarfs, showing that including their opacities improves spectral models and explains observed features.

Contribution

It introduces the first detailed modeling of sulfide and salt cloud opacities in T and Y dwarf atmospheres, enhancing spectral fits and physical parameter estimates.

Findings

Models with sulfide clouds match observed spectra better.

Sulfide clouds explain the 'cloudy' spectra of T and Y dwarfs.

Including condensate opacities is essential for accurate atmospheric characterization.

Abstract

As brown dwarfs cool, a variety of species condense in their atmospheres, forming clouds. Iron and silicate clouds shape the emergent spectra of L dwarfs, but these clouds dissipate at the L/T transition. A variety of other condensates are expected to form in cooler T dwarf atmospheres. These include Cr, MnS, Na2S, ZnS, and KCl, but the opacity of these optically thinner clouds has not been included in previous atmosphere models. Here, we examine their effect on model T and Y dwarf atmospheres. The cloud structures and opacities are calculated using the Ackerman & Marley (2001) cloud model, which is coupled to an atmosphere model to produce atmospheric pressure-temperature profiles in radiative-convective equilibrium. We generate a suite of models between Teff = 400 and 1300 K, log g=4.0 and 5.5, and condensate sedimentation efficiencies from fsed=2 to 5. Model spectra are compared to two red T dwarfs, Ross 458C and UGPS 0722-05; models that include clouds are found to match observed spectra significantly better than cloudless models. The emergence of sulfide clouds in cool atmospheres, particularly Na2S, may be a more natural explanation for the "cloudy" spectra of these objects, rather than the re-emergence of silicate clouds that wane at the L-to-T transition. We find that sulfide clouds provide a mechanism to match the near- and mid-infrared colors of observed T dwarfs. Our results indicate that including the opacity of condensates in T dwarf atmospheres is necessary to accurately determine the physical characteristics of many of the observed objects.