Planetary Climate Dynamics

Temperature–chemistry coupling in the evolution of gas giant atmospheres driven by stellar flares

Monthly Notices of the Royal Astronomical Society Oxford University Press 523:4 (2023) 5681-5702

Authors:

Harrison Nicholls, Olivia Venot

Abstract:

The effect of enhanced UV irradiation associated with stellar flares on the atmospheric composition and temperature of gas giant exoplanets was investigated. This was done using a 1D radiative-convective-chemical model with self-consistent feedback between the temperature and the non-equilibrium chemistry. It was found that flare-driven changes to chemical composition and temperature give rise to prolonged trends in evolution across a broad range of pressure levels and species. Allowing feedback between chemistry and temperature plays an important role in establishing the quiescent structure of these atmospheres, and determines their evolution due to flares. It was found that cooler planets are more susceptible to flares than warmer ones, seeing larger changes in composition and temperature, and that temperature–chemistry feedback modifies their evolution. Long-term exposure to flares changes the transmission spectra of gas giant atmospheres; these changes differed when the temperature structure was allowed to evolve self-consistently with the chemistry. Changes in spectral features due to the effects of flares on these atmospheres can be associated with changes in composition. The effects of flares on the atmospheres of sufficiently cool planets will impact observations made with JWST. It is necessary to use self-consistent models of temperature and chemistry in order to accurately capture the effects of flares on features in the transmission spectra of cooler gas giants, but this depends heavily on the radiation environment of the planet.

Dynamically coupled kinetic chemistry in brown dwarf atmospheres – I. Performing global scale kinetic modelling

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 523:3 (2023) 4477-4491

Authors:

Elspeth KH Lee, Xianyu Tan, Shang-Min Tsai

The Near Infrared Imager and Slitless Spectrograph for the James Webb Space Telescope -- III. Single Object Slitless Spectroscopy

ArXiv 2306.04572 (2023)

Authors:

Loic Albert, David Lafreniere, Rene Doyon, Etienne Artigau, Kevin Volk, Paul Goudfrooij, Andre R Martel, Michael Radica, Jason Rowe, Nestor Espinoza, Arpita Roy, Joseph C Filippazzo, Antoine Darveau-Bernier, Geert Jan Talens, Anand Sivaramakrishnan, Chris J Willott, Alexander W Fullerton, Stephanie LaMassa, John B Hutchings, Neil Rowlands, M Begona Vila, Julia Zhou, David Aldridge, Michael Maszkiewicz, Mathilde Beaulieu, Neil J Cook, Caroline Piaulet, Pierre-Alexis Roy, Pierrot Lamontagne, Kim Morel, William Frost, Salma Salhi, Louis-Philippe Coulombe, Bjorn Benneke, Ryan J MacDonald, Doug Johnstone, Jake D Turner, Marylou Fournier-Tondreau, Romain Allart, Lisa Kaltenegger

Temperature-chemistry coupling in the evolution of gas giant atmospheres driven by stellar flares

ArXiv 2306.03673 (2023)

Authors:

Harrison Nicholls, Eric Hébrard, Olivia Venot, Benjamin Drummond, Elise Evans

Effect of Mushball on Jupiter's Ammonia Distribution: a General Circulation Model Study

Copernicus Publications (2023)

Authors:

Xinmiao Hu, Peter Read, Vivien Parmentier, Greg Colyer

Abstract:

Recent Juno microwave observations have revealed puzzling features of Jupiter’s ammonia distribution, including an ammonia-poor layer extending down to levels of tens of bars outside the equatorial region to at least ±40° [Li et al. 2017]. Guillot et al. [2020] showed that ammonia-rich hail, or “mushballs”, formed during a powerful thunderstorm, can efficiently transport ammonia to the deeper atmosphere and hence could cause the observed ammonia depletion. However, this mechanism has not been tested in numerical simulations in which convective events are self-consistently determined. We have developed a simple parameterization scheme for the mushball process and implemented it into a Jupiter GCM [Young et al. 2019] that includes the following relevant parameterizations: a simple cloud microphysics model for water and ammonia, a water moist convection scheme that transports ammonia as a passive tracer, a dry convection scheme, and a two-stream, semi-grey radiative transfer scheme. In the two-dimensional setup of the aforementioned GCM, we show that mushball precipitation can produce an ammonia depletion qualitatively similar to the Juno observations.We present our preliminary results in three-dimensional simulations, in which a Jupiter-like zonal jet profile emerges spontaneously. We will show the role of different processes, including the mushball process, moist convection and meridional circulation in shaping ammonia distribution. Further, we compare our model output with Juno MWR result, and discuss the implication to future observations.