Exoplanet atmospheres

No evidence of phosphine in the atmosphere of Venus from independent analyses

Nature Astronomy Springer Nature 5:7 (2021) 631-635

Authors:

Geronimo Villanueva, Martin Cordiner, Patrick Irwin, Imke De Pater, B Butler, M Gurwell, SN Milam, Conor Nixon, Statia Luszcz-Cook, Colin Wilson, V Kofman, G Liuzzi, S Faggi, T Fauchez, M Lippi, R Cosentino, A Thelen, A Moullet, P Hartogh, E Molter, S Charnley, G Arney, A Mandell, N Biver, A Vandaele, KR de Kleer, R Kopparapu

Decomposing the iron cross-correlation signal of the ultra-hot Jupiter WASP-76b in transmission using 3D Monte Carlo radiative transfer

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 506:1 (2021) 1258-1283

Authors:

Joost P Wardenier, Vivien Parmentier, Elspeth KH Lee, Michael R Line, Ehsan Gharib-Nezhad

Spitzer phase curve observations and circulation models of the inflated ultra-hot Jupiter WASP-76b

(2021)

Authors:

Erin M May, Thaddeus D Komacek, Kevin B Stevenson, Eliza M-R Kempton, Jacob L Bean, Matej Malik, Jegug Ih, Megan Mansfield, Arjun B Savel, Drake Deming, Jean-Michel Desert, Y Katherina Feng, Jonathan J Fortney, Tiffany Kataria, Nikole Lewis, Caroline Morley, Emily Rauscher, Adam Showman

Simulating gas giant exoplanet atmospheres with Exo-FMS: comparing semigrey, picket fence, and correlated-k radiative-transfer schemes

Monthly Notices of the Royal Astronomical Society Royal Astronomical Society 506:2 (2021) 2695-2711

Authors:

Elspeth KH Lee, Vivien Parmentier, Mark Hammond, Simon L Grimm, Daniel Kitzmann, Xianyu Tan, Shang-Min Tsai, Raymond T Pierrehumbert

Abstract:

Radiative-transfer (RT) is a fundamental part of modelling exoplanet atmospheres with general circulation models (GCMs). An accurate RT scheme is required for estimates of the atmospheric energy transport and for gaining physical insight from model spectra. We implement three RT schemes for Exo-FMS: semigrey, non-grey ‘picket fence’, and real gas with correlated-k. We benchmark the Exo-FMS GCM, using these RT schemes to hot Jupiter simulation results from the literature. We perform a HD 209458b-like simulation with the three schemes and compare their results. These simulations are then post-processed to compare their observable differences. The semigrey scheme results show qualitative agreement with previous studies in line with variations seen between GCM models. The real gas model reproduces well the temperature and dynamical structures from other studies. After post-processing our non-grey picket fence scheme compares very favourably with the real gas model, producing similar transmission spectra, emission spectra, and phase curve behaviours. Exo-FMS is able to reliably reproduce the essential features of contemporary GCM models in the hot gas giant regime. Our results suggest the picket fence approach offers a simple way to improve upon RT realism beyond semigrey schemes.

How does thermal scattering shape the infrared spectra of cloudy exoplanets? A theoretical framework and consequences for atmospheric retrievals in the JWST era

Monthly Notices of the Royal Astronomical Society Oxford University Press 506:1 (2021) 1309-1332

Authors:

Jake Taylor, Vivien Parmentier, Michael R Line, Graham KH Lee, Patrick GJ Irwin, Suzanne Aigrain

Abstract:

Observational studies of exoplanets are suggestive of a ubiquitous presence of clouds. The current modelling techniques used in emission to account for the clouds tend to require prior knowledge of the cloud condensing species and often do not consider the scattering effects of the cloud. We explore the effects that thermal scattering has on the emission spectra by modelling a suite of hot Jupiter atmospheres with varying cloud single-scattering albedos (SSAs) and temperature profiles. We examine cases ranging from simple isothermal conditions to more complex structures and physically driven cloud modelling. We show that scattering from nightside clouds would lead to brightness temperatures that are cooler than the real atmospheric temperature if scattering is unaccounted for. We show that scattering can produce spectral signatures in the emission spectrum even for isothermal atmospheres. We identify the retrieval degeneracies and biases that arise in the context of simulated JWST spectra when the scattering from the clouds dominates the spectral shape. Finally, we propose a novel method of fitting the SSA spectrum of the cloud in emission retrievals, using a technique that does not require any prior knowledge of the cloud chemical or physical properties.