Exoplanet atmospheres

Vertical distribution of water vapour for Martian northern hemisphere summer in Mars year 28 from Mars Climate Sounder

Icarus Elsevier 386 (2022) 115141

Authors:

R Lolachi, Patrick Irwin, Na Teanby

Abstract:

We present, for the first time, retrievals of the vertical distribution of water vapour from Mars Climate Sounder (MCS) aboard Mars Reconnaissance Orbiter (MRO), an original goal of the mission compromised by channel filter performance issues. To work around this problem a two-stage retrieval has been developed and was applied to MCS observations for MY28 NH summer (L_s=111–173°, 26 September 2006 to 27 January 2007). Retrievals were consistent with observations by other instruments for both column abundances (e.g., peak NH summer column abundance of 70 pr. μm compared with 50 pr. μm in the literature) and vertical profiles. Other key results are nightside vertical profiles of water vapour (retrieved for the first time) and interaction of atmospheric water vapour with the aphelion cloud belt. Seasonal changes in the hygropause (a proxy for condensation level) are reflected in changes in the cloud belt. During late northern summer, when the hygropause level is high at the equator and tropics, the cloudbase is higher (increasing by ≈ 10 km from 25 to 35 km) and the belt is weaker.

Evolution of a dark vortex on Neptune with transient secondary features

Icarus Elsevier 387 (2022) 115123

Authors:

Michael H Wong, Lawrence Sromovsky, Patrick Fry, Agustín Sánchez-Lavega, Ricardo Hueso, Jon Legarreta, Amy A Simon, Raúl Morales-Juberías, Joshua Tollefson, Imke de Pater, Patrick Irwin

Abstract:

Dark spots on Neptune observed by Voyager and the Hubble Space Telescope are thought to be anticyclones with lifetimes of a few years, in contrast with very long-lived anticyclones in Jupiter and Saturn. The full life cycle of any Neptune dark spot has not been captured due to limited temporal coverage, but our Hubble observations of a recent feature, NDS-2018, provide the most complete long-term observational history of any dark vortex on Neptune. Past observations suggest some dark spots meet their demise by fading and dissipating without migrating meridionally. On the other hand, simulations predict a second pathway with equatorward migration and disruption. Our HST observations suggest NDS-2018 is following the second pathway. Some of the HST observations reveal transient dark features with widths of about 4000 to 9000 km, at latitudes between NDS-2018 and the equator. The secondary dark features appeared before changes in the meridional migration of NDS-2018 were seen. These features have somewhat smaller size and much smaller contrast compared to the main dark spot. Discrete secondary dark features of this scale have never been seen near previous dark spots, but global-scale dark bands are associated with several previous dark spots in addition to NDS-2018. The absolute photometric contrast of NDS-2018 (as large as 19%) is greater than previous dark spots, including the Great Dark Spot seen by Voyager. New simulations suggest that vortex internal circulation is weak relative to the background vorticity, presenting a clearly different case from stronger anticyclones observed on Jupiter and Saturn.

A New Analysis of Eight Spitzer Phase Curves and Hot Jupiter Population Trends: Qatar-1b, Qatar-2b, WASP-52b, WASP-34b, and WASP-140b

The Astronomical Journal American Astronomical Society 163:6 (2022) 256

Authors:

EM May, KB Stevenson, Jacob L Bean, Taylor J Bell, Nicolas B Cowan, Lisa Dang, Jean-Michel Desert, Jonathan J Fortney, Dylan Keating, Eliza M-R Kempton, Thaddeus D Komacek, Nikole K Lewis, Megan Mansfield, Caroline Morley, Vivien Parmentier, Emily Rauscher, Mark R Swain, Robert T Zellem, Adam Showman

Confirmation of Water Absorption in the Thermal Emission Spectrum of the Hot Jupiter WASP-77Ab with HST/WFC3

The Astronomical Journal American Astronomical Society 163:6 (2022) 261

Authors:

Megan Mansfield, Lindsey Wiser, Kevin B Stevenson, Peter Smith, Michael R Line, Jacob L Bean, Jonathan J Fortney, Vivien Parmentier, Eliza M-R Kempton, Jacob Arcangeli, Jean-Michel Désert, Brian Kilpatrick, Laura Kreidberg, Matej Malik

The impact of ultraviolet heating and cooling on the dynamics and observability of lava planet atmospheres

Monthly Notices of the Royal Astronomical Society Oxford University Press 513:4 (2022) 6125-6133

Authors:

T Giang Nguyen, Nicolas B Cowan, Raymond T Pierrehumbert, Roxana E Lupu, John E Moores

Abstract:

Lava planets have non-global, condensible atmospheres similar to icy bodies within the Solar system. Because they depend on interior dynamics, studying the atmospheres of lava planets can lead to understanding unique geological processes driven by their extreme environment. Models of lava planet atmospheres have thus far focused on either radiative transfer or hydrodynamics. In this study, we couple the two processes by introducing ultraviolet (UV) and infrared (IR) radiation to a turbulent boundary layer model. We also test the effect of different vertical temperature profiles on atmospheric dynamics. Results from the model show that UV radiation affects the atmosphere much more than IR. UV heating and cooling work together to produce a horizontally isothermal atmosphere away from the substellar point regardless of the vertical temperature profile. We also find that stronger temperature inversions induce stronger winds and hence cool the atmosphere. Our simulated transmission spectra of the bound atmosphere show a strong SiO feature in the UV that would be challenging to observe in the planet’s transit spectrum due to the precision required. Our simulated emission spectra are more promising, with significant SiO spectral features at 4.5 and 9 μm that can be observed with the James Webb Space Telescope. Different vertical temperature profiles produce discernible dayside emission spectra, but not in the way one would expect.