The infrared colors of 51 Eridani b: micrometereoid dust or chemical disequilibrium?

We reanalyze near-infrared spectra of the young extrasolar giant planet 51 Eridani b which was originally presented in (Macintosh et al. 2015) and (Rajan et al. 2017) using modern atmospheric models which include a self-consistent treatment of disequilibrium chemistry due to turbulent vertical mixin...

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Bibliographic Details
Published in:arXiv.org 2023-04
Main Authors: Madurowicz, Alexander, Mukherjee, Sagnick, Batalha, Natasha, Macintosh, Bruce, Marley, Mark, Karalidi, Theodora
Format: Article
Language:English
Subjects:
Atmospheric models
Chemistry
Clouds
Diffusion coefficient
Dust
Extrasolar planets
Impactors
Infrared photometry
Infrared spectra
Macintosh personal computers
Near infrared radiation
Planetary atmospheres
Spectral energy distribution
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Summary:We reanalyze near-infrared spectra of the young extrasolar giant planet 51 Eridani b which was originally presented in (Macintosh et al. 2015) and (Rajan et al. 2017) using modern atmospheric models which include a self-consistent treatment of disequilibrium chemistry due to turbulent vertical mixing. In addition, we investigate the possibility that significant opacity from micrometeors or other impactors in the planet's atmosphere may be responsible for shaping the observed spectral energy distribution (SED). We find that disequilibrium chemistry is useful for describing the mid-infrared colors of the planet's spectra, especially in regards to photometric data at M band around 4.5 \(\mu\)m which is the result of super-equilibrium abundances of carbon monoxide, while the micrometeors are unlikely to play a pivotal role in shaping the SED. The best-fitting, micrometeroid-dust-free, disequilibrium chemistry, patchy cloud model has the following parameters: effective temperature \(T_\textrm{eff} = 681\) K with clouds (or without clouds, i.e. the grid temperature \(T_\textrm{grid}\) = 900 K), surface gravity \(g\) = 1000 m/s\(^2\), sedimentation efficiency \(f_\textrm{sed}\) = 10, vertical eddy diffusion coefficient \(K_\textrm{zz}\) = 10\(^3\) cm\(^2\)/s, cloud hole fraction \(f_\textrm{hole}\) = 0.2, and planet radius \(R_\textrm{planet}\) = 1.0 R\(_\textrm{Jup}\).
ISSN:2331-8422
DOI:10.48550/arxiv.2304.03850