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Published June 2022 | Accepted Version + Published
Journal Article Open

Orbital and In‐Situ Investigation of Periodic Bedrock Ridges in Glen Torridon, Gale Crater, Mars

Stack, Kathryn M. ORCID icon
Dietrich, William E.
Lamb, Michael P. ORCID icon
Sullivan, Robert J. ORCID icon
Christian, John R. ORCID icon
Newman, Claire E. ORCID icon
O'Connell‐Cooper, Catherine D. ORCID icon
Sneed, Jonathan W. ORCID icon
Day, Mackenzie ORCID icon
Baker, Mariah ORCID icon
Arvidson, Raymond E. ORCID icon
Fedo, Christopher M. ORCID icon
Khan, Sabrina ORCID icon
Williams, Rebecca M. E. ORCID icon
Bennett, Kristen A. ORCID icon
Bryk, Alexander B. ORCID icon
Cofield, Shannon
Edgar, Lauren A. ORCID icon
Fox, Valerie K. ORCID icon
Fraeman, Abigail A. ORCID icon
House, Christopher H. ORCID icon
Rubin, David M. ORCID icon
Sun, Vivian Z. ORCID icon
Beek, Jason K. ORCID icon

Abstract

Gale crater, the field site for NASA's Mars Science Laboratory Curiosity rover, contains a diverse and extensive record of aeolian deposition and erosion. This study focuses on a series of regularly spaced, curvilinear, and sometimes branching bedrock ridges that occur within the Glen Torridon region on the lower northwest flank of Aeolis Mons, the central mound within Gale crater. During Curiosity's exploration of Glen Torridon between sols ∼2300–3080, the rover drove through this field of ridges, providing the opportunity for in situ observation of these features. This study uses orbiter and rover data to characterize ridge morphology, spatial distribution, compositional and material properties, and association with other aeolian features in the area. Based on these observations, we find that the Glen Torridon ridges are consistent with an origin as wind-eroded bedrock ridges, carved during the exhumation of Mount Sharp. Erosional features like the Glen Torridon ridges observed elsewhere on Mars, termed periodic bedrock ridges (PBRs), have been interpreted to form transverse to the dominant wind direction. The size and morphology of the Glen Torridon PBRs are consistent with transverse formative winds, but the orientation of nearby aeolian bedforms and bedrock erosional features raise the possibility of PBR formation by a net northeasterly wind regime. Although several formation models for the Glen Torridon PBRs are still under consideration, and questions persist about the nature of PBR-forming paleowinds, the presence of PBRs at this site provides important constraints on the depositional and erosional history of Gale crater.

Additional Information

© 2022 Jet Propulsion Laboratory. California Institute of Technology. Government sponsorship acknowledged. This is an open access article under the terms of the Creative Commons Attribution-NonCommercial License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited and is not used for commercial purposes. Issue Online: 26 May 2022; Version of Record online: 26 May 2022; Accepted manuscript online: 16 May 2022; Manuscript accepted: 07 May 2022; Manuscript revised: 03 May 2022; Manuscript received: 18 October 2021. This effort was carried out in part at the Jet Propulsion Laboratory, California Institute of Technology, and at the home institutions of the named co-authors under a contract with the National Aeronautics and Space Administration. The authors would like to acknowledge the scientists and engineers of the MSL Curiosity and MRO missions for acquiring and providing the data used in this study. Mastcam mosaics were processed by the Mastcam team at Malin Space Science Systems. Fred Calef provided context on the orbiter basemaps used in this study and provided guidance regarding impact craters and crater retention ages. Laura Kerber shared her expertise on yardangs and other aeolian erosion features. The authors would like to thank and acknowledge Dr. Elena Favaro and two anonymous reviewers of this manuscript whose comments substantially improved this paper. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. government. Data Availability Statement: All Mars Science Laboratory Curiosity data products and data sets, including Mars Descent Imager (Malin, 2013a), Mastcam (Malin, 2013b), Rear Hazcam (Maki, 2013a), and Navcam (Maki, 2013b) images and Alpha Particle X-ray Spectrometer (Gellert, 2013) data are archived at the NASA Planetary Data Systems and are available at https://pds-geosciences.wustl.edu/missions/msl/. The High Resolution Imaging Science Experiment (HiRISE) digital elevation model (Calef & Parker, 2016b) is available at https://astrogeology.usgs.gov/search/map/Mars/MarsScienceLaboratory/Mosaics/MSL_Gale_DEM_Mosaic_10m. The HiRISE grayscale merged orthophoto (Calef & Parker, 2016a) on which the color mosaic is based, is available at https://astrogeology.usgs.gov/search/map/Mars/MarsScienceLaboratory/Mosaics/MSL_Gale_Orthophoto_Mosaic_10m_v3. Individual HiRISE images, including color images, are available at https://www.uahirise.org/ and are archived at the NASA Planetary Data Systems at https://pds-imaging.jpl.nasa.gov/volumes/mro.html. Compact Reconnaissance Imaging Spectrometer for Mars (CRISM) data (Murchie, 2006) is archived at the NASA Planetary Data Systems and are available at https://pds-geosciences.wustl.edu/missions/mro/crism.htm. All other data products related to the CRISM-derived thermal inertia values presented in this paper can be accessed through Christian et al. (2021; Digital Research Materials) and are available at https://doi.org/10.7936/jznj-s510. Glen Torridon ridge, transverse aeolian ridge, and ripple shapefiles, as well as shapefiles showing the locations of wavelength profiles and individual ridge topographic profiles are available from Stack (2021) at https://doi.org/10.5281/zenodo.6324330. The Mars Weather Research and Forecasting modeling outputs used in this paper are available at Newman (2022) at https://doi.org/10.5281/zenodo.6514934.

Attached Files

Published - JGR_Planets_-_2022_-_Stack_-_Orbital_and_In‐Situ_Investigation_of_Periodic_Bedrock_Ridges_in_Glen_Torridon__Gale_Crater_.pdf

Accepted Version - JGR_Planets_-_2022_-_Stack_-_Orbital_and_In‐Situ_Investigation_of_Periodic_Bedrock_Ridges_in_Glen_Torridon__Gale_Crater__acc.pdf

Files

JGR_Planets_-_2022_-_Stack_-_Orbital_and_In‐Situ_Investigation_of_Periodic_Bedrock_Ridges_in_Glen_Torridon__Gale_Crater_.pdf

Additional details

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August 22, 2023
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