📝 SummarXiv

Abstract

JWST has provided critical mid-infrared data for cold brown dwarfs. It has also provided low-resolution near-infrared spectra, and for faint sources these are the first spectra at these wavelengths. We use these data and other literature sources to synthesize near-infrared photometry on the MKO system for 19 T and Y dwarfs, on the Euclid system for 44 T and Y dwarfs, and on the Roman system for 48 T and Y dwarfs. We also synthesize Euclid I_E magnitudes for 15 T and Y dwarfs. Using the Beiler et al. 2024 observational effective temperatures (T_eff), together with ATMO 2020++ model colors, we show that the absolute 4.6um magnitude can be used as a proxy for T_eff. We present a polynomial fit to the M_W2:T_eff relationship for cool dwarfs with 250 < T_eff K < 1000. We select five Y dwarfs with 275 < T_eff K < 400 which have a range in near- to mid-infrared colors. Comparison of the JWST spectral energy distribution to ATMO 2020++ models indicate that Y dwarfs which are bluer in J - W2 are lower gravity or more metal-rich than their redder counterparts, with stronger CO and CO_2 absorption at 4.2 < lambda um < 4.9. The near-infrared color diagrams show significant scatter, with complex dependencies on T_eff, metallicity and gravity. In order to disentangle these effects, opacity sources for cool model atmospheres need to be more complete at lambda < 1um.