Your search keyword '"Corlies, P."' showing total 6 results

1. Clouds and Seasonality on Terrestrial Planets with Varying Rotation Rates

Author

Williams, Daniel A., Ji, Xuan, Corlies, Paul, and Lora, Juan M.

Subjects

Physics - Atmospheric and Oceanic Physics, Astrophysics - Earth and Planetary Astrophysics

Abstract

Using an idealised climate model incorporating seasonal forcing, we investigate the impact of rotation rate on the abundance of clouds on an Earth-like aquaplanet, and the resulting impacts upon albedo and seasonality. We show that the cloud distribution varies significantly with season, depending strongly on the rotation rate, and is well explained by the large-scale circulation and atmospheric state. Planetary albedo displays non-monotonic behaviour with rotation rate, peaking at around 1/2$\Omega_E$. Clouds reduce the surface temperature and total precipitation relative to simulations without clouds at all rotation rates, and reduce the dependence of total precipitation on rotation rate, causing non-monotonic behaviour and a local maximum around 1/8$\Omega_E$ ; these effects are related to the impacts of clouds on the net atmospheric and surface radiative energy budgets. Clouds also affect the seasonality. The influence of clouds on the extent of the winter Hadley cell and the intertropical convergence zone is relatively minor at slow rotation rates ($<$1/8$\Omega_E$ ), but becomes more pronounced at intermediate rotation rates, where clouds decrease their maximum latitudes. The timing of seasonal transitions varies with rotation rate, and the addition of clouds reduces the seasonal phase lag., Comment: 21 pages, 9 figures

Published

2024

2. Aeolian sediment transport on Io from lava-frost interactions

Author

McDonald, George D., Harper, Joshua Méndez, Ojha, Lujendra, Corlies, Paul, Dufek, Josef, Ewing, Ryan C., and Kerber, Laura

Subjects

Astrophysics - Earth and Planetary Astrophysics, Physics - Geophysics

Abstract

Surface modification on Jupiter's volcanically active moon, Io, has to date been attributed almost exclusively to lava emplacement and volcanic plume deposits. Here we demonstrate that wind-blown transport of sediment may also be altering the Ionian surface. Specifically, shallow subsurface interactions between lava and Io's widespread sulfur dioxide (SO$_2$) frost can produce localized sublimation vapor flows with sufficient gas densities to enable particle saltation. We calculate anticipated outgassing velocities from lava-SO$_2$ frost interactions, and compare these to the saltation thresholds predicted when accounting for the tenuous nature of the sublimated vapor. We find that saltation may occur if frost temperatures surpass 155 K. Finally we make the first measurements of the dimensions of linear features in images from the Galileo probe, previously termed "ridges", which demonstrate certain similarities to dunes on other planetary bodies. Io joins a growing list of bodies with tenuous and transient atmospheres where aeolian sediment transport may be an important control on the landscape., Comment: 17 pages, 6 figures. Published in Nature Communications

Published

2022

3. Titan: Earth-like on the Outside, Ocean World on the Inside

Author

MacKenzie, Shannon M., Birch, Samuel P. D., Horst, Sarah, Sotin, Christophe, Barth, Erika, Lora, Juan M., Trainer, Melissa G., Corlies, Paul, Malaska, Michael J., Sciamma-O'Brien, Ella, Thelen, Alexander E., Turtle, Elizabeth P., Radebaugh, Jani, Hanley, Jennifer, Solomonidou, Anezina, Newman, Claire, Regoli, Leonardo, Rodriguez, Sebastien, Seignovert, Benoit, Hayes, Alexander G., Journaux, Baptiste, Steckloff, Jordan, Nna-Mvondo, Delphine, Cornet, Thomas, Palmer, Maureen, Lopes, Rosaly M. C., Vinatier, Sandrine, Lorenz, Ralph, Nixon, Conor, Czaplinski, Ellen, Barnes, Jason W., Sittler, Ed, and Coates, Andrew

Subjects

Astrophysics - Earth and Planetary Astrophysics, Physics - Atmospheric and Oceanic Physics

Abstract

Thanks to the Cassini-Huygens mission, Titan, the pale orange dot of Pioneer and Voyager encounters has been revealed to be a dynamic, hydrologically-shaped, organic-rich ocean world offering unparalleled opportunities to explore prebiotic chemistry. And while Cassini-Huygens revolutionized our understanding of each of the three layers of Titan--the atmosphere, the surface, and the interior--we are only beginning to hypothesize how these realms interact. In this paper, we summarize the current state of Titan knowledge and discuss how future exploration of Titan would address some of the next decade's most compelling planetary science questions. We also demonstrate why exploring Titan, both with and beyond the Dragonfly New Frontiers mission, is a necessary and complementary component of an Ocean Worlds Program that seeks to understand whether habitable environments exist elsewhere in our solar system., Comment: Submitted to the PSJ Focus Issue on Ocean World Exploration

Published

2021

4. Modeling transmission windows in Titan's lower troposphere: Implications for infrared spectrometers aboard future aerial and surface missions

Author

Corlies, Paul, McDonald, George D., Hayes, Alexander G., Wray, James J., Adamkovics, Mate, Malaska, Michael J., Cable, Morgan L., Hofgartner, Jason D., Horst, Sarah M., Liuzzo, Lucas R., Buffo, Jacob J., Lorenz, Ralph D., and Turtle, Elizabeth P.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

From orbit, the visibility of Titan's surface is limited to a handful of narrow spectral windows in the near-infrared (near-IR), primarily from the absorption of methane gas. This has limited the ability to identify specific compounds on the surface -- to date Titan's bulk surface composition remains unknown. Further, understanding of the surface composition would provide insight into geologic processes, photochemical production and evolution, and the biological potential of Titan's surface. One approach to obtain wider spectral coverage with which to study Titan's surface is by decreasing the integrated column of absorbers (primarily methane) and scatterers between the observer and the surface. This is only possible if future missions operate at lower altitudes in Titan's atmosphere. Herein, we use a radiative transfer model to measure in detail the absorption through Titan's atmosphere from different mission altitudes, and consider the impacts this would have for interpreting reflectance measurements of Titan's surface. Over our modeled spectral range of 0.4 - 10 micron, we find that increases in the width of the transmission windows as large as 317% can be obtained for missions performing remote observations at the surface. However, any appreciable widening of the windows requires onboard illumination. Further, we make note of possible surface compounds that are not currently observable from orbit, but could be identified using the wider windows at low altitudes. These range from simple nitriles such as cyanoacetylene, to building blocks of amino acids such as urea. Finally, we discuss the implications that the identifications of these compounds would have for Titan science., Comment: 52 pages, 6 figures, Icarus 2020

Published

2020

5. Migrating Scarps as a Significant Driver for Cometary Surface Evolution

Author

Birch, Samuel, Hayes, Alexander, Umurhan, Orkan, Tang, Yuhui, Vincent, Jean-Baptiste, Oklay, Nilda, Bodewits, Dennis, Davidsson, Bjorn, Marschall, Raphael, Soderblom, Jason, Moore, Jeff, Corlies, Paul, and Squyres, Steven

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Rosetta observations of 67P/Churyumov-Gerasimenko (67P) reveal that most changes occur in the fallback-generated smooth terrains, vast deposits of granular material blanketing the comet's northern hemisphere. These changes express themselves both morphologically and spectrally across the nucleus, yet we lack a model that describes their formation and evolution. Here we present a self-consistent model that thoroughly explains the activity and mass loss from Hapi's smooth terrains. Our model predicts the removal of dust via re-radiated solar insolation localized within depression scarps that are substantially more ice-rich than previously expected. We couple our model with numerous Rosetta observations to thoroughly capture the seasonal erosion of Hapi's smooth terrains, where local scarp retreat gradually removes the uppermost dusty mantle. As sublimation-regolith interactions occur on rocky planets, comets, icy moons and KBOs, our coupled model and observations provide a foundation for future understanding of the myriad of sublimation-carved worlds., Comment: 14 pages, 4 figures, accepted GRL

Published

2019

6. Meridional variation in tropospheric methane on Titan observed with AO spectroscopy at Keck and VLT

Author

Ádámkovics, Máté, Mitchell, Jonathan L., Hayes, Alexander G., Rojo, Patricio M., Corlies, Paul, Barnes, Jason W., Ivanov, Valentin D., Brown, Robert H., Baines, Kevin H., Buratti, Bonnie J., Clark, Roger N., Nicholson, Philip D., and Sotin, Christophe

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

The spatial distribution of the tropospheric methane on Titan was measured using near-infrared spectroscopy. Ground-based observations at 1.5$\mu{\rm m}$ (H-band) were performed during the same night using instruments with adaptive optics at both the W. M. Keck Observatory and at the Paranal Observatory on 17 July 2014 UT. The integral field observations with SINFONI on the VLT covered the entire H-band at moderate resolving power, $R=\lambda/\Delta\lambda\approx1,500$, while the Keck observations were performed with NIRSPAO near 1.55254$\mu{\rm m}$ at higher resolution, $R\approx25,000$. The moderate resolution observations are used for flux calibration and for the determination of model parameters that can be degenerate in the interpretation of high resolution spectra. Line-by-line calculations of CH$_4$ and CH$_3$D correlated $k$ distributions from the HITRAN 2012 database were used, which incorporate revised line assignments near 1.5$\mu{\rm m}$. We fit the surface albedo and aerosol distributions in the VLT SINFONI observations that cover the entire H-band window and used these quantities to constrain the models of the high-resolution Keck NIRSPAO spectra when retrieving the methane abundances. Cassini VIMS images of the polar regions, acquired on 20 July 2014 UT, are used to validate the assumption that the opacity of tropospheric aerosol is relatively uniform below 10 km. We retrieved methane abundances at latitudes between 42$^{\circ}$ S and 80$^{\circ}$ N. The tropospheric methane in the Southern mid-latitudes was enhanced by a factor of $\sim$10--40% over the nominal profile that was measured using the GCMS on Huygens. The Northern hemisphere had $\sim$90% of the nominal methane abundance up to polar latitudes (80$^{\circ}$N). These measurements suggest that a source of saturated polar air is equilibrating with dryer conditions at lower latitudes., Comment: Accepted for publication in Icarus on May 22, 2015

Published

2015