EXOPLINES: Molecular Absorption Cross-section Database for Brown Dwarf and Giant Exoplanet Atmospheres

Stellar, substellar, and planetary atmosphere models are all highly sensitive to the input opacities. Generational differences between various state-of-the-art stellar/planetary models arise primarily because of incomplete and outdated atomic/molecular line lists. Here we present a database of preco...

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Veröffentlicht in:	The Astrophysical journal. Supplement series 2021-06, Vol.254 (2), p.34
Hauptverfasser:	Gharib-Nezhad, Ehsan, Iyer, Aishwarya R., Line, Michael R., Freedman, Richard S., Marley, Mark S., Batalha, Natasha E.
Format:	Artikel
Sprache:	eng
Schlagworte:	Absorption Absorption cross sections Astronomical models Atmospheric models Brown dwarf stars Brown dwarfs Emission spectra Exoplanet atmospheres Exoplanet atmospheric composition Extrasolar planets Generational differences Hot Jupiters Jupiter Lists Molecular absorption Planetary atmosphere models Planetary atmospheres Red dwarf stars Spectral line lists Spectroscopy Spectrum analysis Stellar atmospheric opacity Stellar models Temperature range Thermal emission
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container_title	The Astrophysical journal. Supplement series
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creator	Gharib-Nezhad, Ehsan Iyer, Aishwarya R. Line, Michael R. Freedman, Richard S. Marley, Mark S. Batalha, Natasha E.
description	Stellar, substellar, and planetary atmosphere models are all highly sensitive to the input opacities. Generational differences between various state-of-the-art stellar/planetary models arise primarily because of incomplete and outdated atomic/molecular line lists. Here we present a database of precomputed absorption cross sections for all isotopologues of key atmospheric molecules relevant to late-type stellar, brown dwarf, and planetary atmospheres: MgH, AlH, CaH, TiH, CrH, FeH, SiO, TiO, VO, and H 2 O. The pressure and temperature ranges of the computed opacities are 10 −6 –3000 bar and 75–4000 K, and their spectral ranges are 0.25–330 μ m for many cases where possible. For cases with no pressure-broadening data, we use collision theory to bridge the gap. We also probe the effect of absorption cross sections calculated from different line lists in the context of ultrahot Jupiter and M-dwarf atmospheres. Using 1D self-consistent radiative–convective thermochemical equilibrium models, we report significant variations in the theoretical spectra and thermal profiles of substellar atmospheres. With a 2000 K representative ultrahot Jupiter, we report variations of up to 320 and 80 ppm in transmission and thermal emission spectra, respectively. For a 3000 K M-dwarf, we find differences of up to 125% in the spectra. We find that the most significant differences arise as a result of the choice of TiO line lists, primarily below 1 μ m. In summary, (1) we present a database of precomputed molecular absorption cross sections, and (2) we quantify biases that arise when characterizing substellar/exoplanet atmospheres as a result of differences in the line lists, therefore highlighting the importance of correct and complete opacities for eventual applications to high-precision spectroscopy and photometry.
doi_str_mv	10.3847/1538-4365/abf504
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We also probe the effect of absorption cross sections calculated from different line lists in the context of ultrahot Jupiter and M-dwarf atmospheres. Using 1D self-consistent radiative–convective thermochemical equilibrium models, we report significant variations in the theoretical spectra and thermal profiles of substellar atmospheres. With a 2000 K representative ultrahot Jupiter, we report variations of up to 320 and 80 ppm in transmission and thermal emission spectra, respectively. For a 3000 K M-dwarf, we find differences of up to 125% in the spectra. We find that the most significant differences arise as a result of the choice of TiO line lists, primarily below 1 μ m. 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Generational differences between various state-of-the-art stellar/planetary models arise primarily because of incomplete and outdated atomic/molecular line lists. Here we present a database of precomputed absorption cross sections for all isotopologues of key atmospheric molecules relevant to late-type stellar, brown dwarf, and planetary atmospheres: MgH, AlH, CaH, TiH, CrH, FeH, SiO, TiO, VO, and H 2 O. The pressure and temperature ranges of the computed opacities are 10 −6 –3000 bar and 75–4000 K, and their spectral ranges are 0.25–330 μ m for many cases where possible. For cases with no pressure-broadening data, we use collision theory to bridge the gap. We also probe the effect of absorption cross sections calculated from different line lists in the context of ultrahot Jupiter and M-dwarf atmospheres. Using 1D self-consistent radiative–convective thermochemical equilibrium models, we report significant variations in the theoretical spectra and thermal profiles of substellar atmospheres. With a 2000 K representative ultrahot Jupiter, we report variations of up to 320 and 80 ppm in transmission and thermal emission spectra, respectively. For a 3000 K M-dwarf, we find differences of up to 125% in the spectra. We find that the most significant differences arise as a result of the choice of TiO line lists, primarily below 1 μ m. 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subjects	Absorption Absorption cross sections Astronomical models Atmospheric models Brown dwarf stars Brown dwarfs Emission spectra Exoplanet atmospheres Exoplanet atmospheric composition Extrasolar planets Generational differences Hot Jupiters Jupiter Lists Molecular absorption Planetary atmosphere models Planetary atmospheres Red dwarf stars Spectral line lists Spectroscopy Spectrum analysis Stellar atmospheric opacity Stellar models Temperature range Thermal emission
title	EXOPLINES: Molecular Absorption Cross-section Database for Brown Dwarf and Giant Exoplanet Atmospheres
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