The 0.8-14.5 micron Spectra of Mid-L to Mid-T Dwarfs: Diagnostics of Effective Temperature, Grain Sedimentation, Gas Transport, and Surface Gravity

TL;DR

This study analyzes mid-L to mid-T dwarf spectra across 0.8-14.5 microns to understand their atmospheric parameters, revealing how sedimentation and gravity influence cloud dispersal and spectral features.

Contribution

It provides detailed spectral modeling of L-T dwarfs, constraining key atmospheric parameters and elucidating cloud evolution during the L-T transition.

Findings

Sedimentation efficiency (fsed) increases rapidly between T0 and T4.

The L-T transition occurs between 1400 K and 1100 K.

Lower gravity dwarfs transition to dust-free atmospheres at lower temperatures.

Abstract

We present new 5.2-14.5 micron low-resolution spectra of 14 mid-L to mid-T dwarfs, as well as 3.0-4.1 micron spectra for five of these dwarfs. These data are supplemented by existing red and near-infrared spectra (0.6-2.5 micron), as well as red through mid-infrared spectroscopy of seven other L and T dwarfs presented by Cushing et al. (2008). We compare these spectra to those generated from the model atmospheres of Saumon & Marley (2008). The models reproduce the observed spectra well, except in the case of one very red L3.5 dwarf, 2MASS J22244381-0158521. The broad wavelength coverage allows us to constrain almost independently the four parameters used to describe these photospheres in our models: effective temperature (Teff), surface gravity, grain sedimentation efficiency (fsed) and vertical gas transport efficiency (Kzz). The sample of L3.5 to T5.5 dwarfs spans the range 1800 < Teff < 1000 K, with an L-T transition (spectral types L7-T4) that lies between 1400 K and 1100K for dwarfs with typical near-infrared colors; bluer and redder dwarfs can be 100 K warmer or cooler, respectively, when using infrared spectral types. In this model analysis, fsed increases rapidly between types T0 and T4, indicating that increased sedimentation can explain the rapid disappearance of clouds at this stage of brown dwarf evolution. There is a suggestion that the transition to dust-free atmospheres happens at lower temperatures for lower gravity dwarfs.