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Understanding the atmospheric properties and chemical composition of the ultra-hot Jupiter HAT-P-7b
Author
Helling, Ch.Iro, N.
Corrales, L.
Samra, D.
Ohno, K.
Alam, M. K.
Steinrueck, M.
Lew, B.
Molaverdikhani, K.
MacDonald, R. J.
Herbort, O.
Woitke, P.
Parmentier, V.
Affiliation
Univ Arizona, Lunar & Planetary Lab,Issue Date
2019-10-25
Metadata
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EDP SCIENCES S ACitation
Helling, C., Iro, N., Corrales, L., Samra, D., Ohno, K., Alam, M. K., … Parmentier, V. (2019). Understanding the atmospheric properties and chemical composition of the ultra-hot Jupiter HAT-P-7b. Astronomy & Astrophysics, 631, A79. https://doi.org/10.1051/0004-6361/201935771 Journal
ASTRONOMY & ASTROPHYSICSRights
Copyright © ESO 2019.Collection Information
This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.Abstract
Context. Of the presently known approximate to 3900 exoplanets, sparse spectral observations are available for approximate to 100. Ultra-hot Jupiters have recently attracted interest from observers and theoreticians alike, as they provide observationally accessible test cases. Confronting detailed theoretical models with observations is of preeminent importance in preparation for upcoming space-based telescopes. Aims. We aim to study cloud formation on the ultra-hot Jupiter HAT-P-7b, the resulting composition of the local gas phase, and how their global changes affect wavelength-dependent observations utilised to derive fundamental properties of the planet. Methods. We apply a hierarchical modelling approach as a virtual laboratory to study cloud formation and gas-phase chemistry. We utilise 97 vertical 1D profiles of a 3D GCM for HAT-P-7b to evaluate our kinetic cloud formation model consistently with the local equilibrium gas-phase composition. We use maps and slice views to provide a global understanding of the cloud and gas chemistry. Results. The day/night temperature difference on HAT-P-7b (Delta T approximate to 2500 K) causes clouds to form on the nightside (dominated by H-2/He) while the dayside (dominated by H/He) retains cloud-free equatorial regions. The cloud particles vary in composition and size throughout the vertical extension of the cloud, but also globally. TiO2[s]/Al2O3[s]/CaTiO3[s]-particles of cm-sized radii occur in the higher dayside-latitudes, resulting in a dayside dominated by gas-phase opacity. The opacity on the nightside, however, is dominated by 0.01 ... 0.1 mu m particles made of a material mix dominated by silicates. The gas pressure at which the atmosphere becomes optically thick is similar to 10(-4) bar in cloudy regions, and similar to 0.1 bar in cloud-free regions. Conclusions. HAT-P-7b features strong morning/evening terminator asymmetries, providing an example of patchy clouds and azimuthally-inhomogeneous chemistry. Variable terminator properties may be accessible by ingress/egress transmission photometry (e.g., CHEOPS and PLATO) or spectroscopy. The large temperature differences of approximate to 2500 K result in an increasing geometrical extension from the night- to the dayside. The H2O abundance at the terminator changes by <1 dex with altitude and less than or similar to 0.3 dex (a factor of 2) across the terminator for a given pressure, indicating that H2O abundances derived from transmission spectra can be representative of the well-mixed metallicity at P greater than or similar to 10 bar. We suggest the atmospheric C/O as an important tool to trace the presence and location of clouds in exoplanet atmospheres. The atmospheric C/O can be sub- and supersolar due to cloud formation. Phase curve variability of HAT-P-7b is unlikely to be caused by dayside clouds.ISSN
0004-6361Version
Final published versionae974a485f413a2113503eed53cd6c53
10.1051/0004-6361/201935771