Active Ground Patterns Near Mars' Equator in the Glen Torridon Region of Gale Crater

Bernard Hallet; Ronald S. Sletten; Michael Malin; Nicolas Mangold; Robert J. Sullivan; Alberto G. Fairén; Germán Martínez; Mariah Baker; Juergen Schieber; Javier Martin-Torres; Maria Paz Zorzano

doi:10.1029/2021JE007126

Active Ground Patterns Near Mars' Equator in the Glen Torridon Region of Gale Crater

Bernard Hallet^*, Ronald S. Sletten^*, Michael Malin, Nicolas Mangold, Robert J. Sullivan, Alberto G. Fairén, Germán Martínez, Mariah Baker, Juergen Schieber, Javier Martin-Torres, Maria Paz Zorzano

^*Corresponding author for this work

Planetary Sciences, Geography

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

On Mars, near the equator, much of the terrain in Gale Crater consists of bedrock outcrops separated by relatively smooth, uniform regolith surfaces. In scattered sites, however, distinct patterns—in the form and texture of the ground surface—contrast sharply with the typical terrain and with eolian bedforms. This paper focuses on these diverse, intriguing ground patterns. They include ∼1 to >10 m-long linear disruptions of uniform regolith surfaces, alignments, and other arrangements of similar-sized rock fragments and shallow, ∼0.1 m-wide sandy troughs 1–10 m in length. Similar features were recognized early in the Mars Science Laboratory (MSL) mission, but they received only limited attention until Curiosity, the MSL rover, encountered striking examples in the Glen Torridon region. Herein, the ground patterns are illustrated with rover images. Potential mechanisms are briefly discussed in the context of the bedrock composition and atmospheric conditions documented by Curiosity. The evidence suggests that the patterns are active forms of spontaneous granular organization. It leads to the hypothesis that the patterns arise and develop from miniscule, inferred cyclic expansion and contraction of the bedrock and regolith, likely driven by oscillating transfers of energy and moisture between the atmosphere and the terrain. The hypothesis has significant implications for studies of contemporary processes on Mars on both sides of the atmosphere-lithosphere interface. The ground patterns, as well as ripples and dunes formed by the wind, constitute remarkable extra-terrestrial examples of granular self-organization, complex phenomena well known in diverse systems on Earth.

Original language	English
Article number	e2021JE007126
Number of pages	25
Journal	Journal of Geophysical Research: Planets
Volume	127
Issue number	10
DOIs	https://doi.org/10.1029/2021JE007126
Publication status	Published - Oct 2022

Bibliographical note

The authors are grateful for NASA's support of the Mars Science Laboratory (MSL) mission and for the efforts of the large team of talented and dedicated scientists and engineers who made this work possible. The authors thank, in particular, Jason Van Beek and Tex Kubacki for their astute observations and, together with their Malin Space Science Systems colleagues, for their critical roles in acquiring the images. The authors also thank Michelle Minitti, Tim Olson, and Ken Edgett for their observations and help in obtaining instructive images. The authors appreciate insightful discussions with Doug Jerolmack, Nakul Deshpande, Lucas Goehring, Lu Liu, Quan-Xing Liu, Zhenpeng Ge, Allan Treiman, and Kevin Lewis, which benefitted this paper. The authors thank J. Levy and an anonymous reviewer for their careful evaluations and detailed comments that substantially improved the manuscript.

Data Availability Statement

NASA Mars rover camera images used for this study are openly available in the NASA Planetary Data System (PDS; https://pds.nasa.gov/). The REMS data are publicly available from the PDS Atmospheres Node (REMS: Mars Science Laboratory Rover Environmental Monitoring Station RDR Data V1.0, MSL-M-REMS-4-ENVEDR-V1.0, https://atmos.nmsu.edu/PDS/data/mslrem_1001. All raw images used in this paper can be found online at https://mars.nasa.gov/msl/multimedia/raw-images). Filters are provided to select particular dates and/or periods (MSL sol numbers) and cameras (M100 and M34).

Keywords

active regolith processes
atmosphere-regolith interactions
granular systems
patterned ground
self-organization
sorted patterns

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Cite this

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title = "Active Ground Patterns Near Mars' Equator in the Glen Torridon Region of Gale Crater",

abstract = "On Mars, near the equator, much of the terrain in Gale Crater consists of bedrock outcrops separated by relatively smooth, uniform regolith surfaces. In scattered sites, however, distinct patterns—in the form and texture of the ground surface—contrast sharply with the typical terrain and with eolian bedforms. This paper focuses on these diverse, intriguing ground patterns. They include ∼1 to >10 m-long linear disruptions of uniform regolith surfaces, alignments, and other arrangements of similar-sized rock fragments and shallow, ∼0.1 m-wide sandy troughs 1–10 m in length. Similar features were recognized early in the Mars Science Laboratory (MSL) mission, but they received only limited attention until Curiosity, the MSL rover, encountered striking examples in the Glen Torridon region. Herein, the ground patterns are illustrated with rover images. Potential mechanisms are briefly discussed in the context of the bedrock composition and atmospheric conditions documented by Curiosity. The evidence suggests that the patterns are active forms of spontaneous granular organization. It leads to the hypothesis that the patterns arise and develop from miniscule, inferred cyclic expansion and contraction of the bedrock and regolith, likely driven by oscillating transfers of energy and moisture between the atmosphere and the terrain. The hypothesis has significant implications for studies of contemporary processes on Mars on both sides of the atmosphere-lithosphere interface. The ground patterns, as well as ripples and dunes formed by the wind, constitute remarkable extra-terrestrial examples of granular self-organization, complex phenomena well known in diverse systems on Earth.",

keywords = "active regolith processes, atmosphere-regolith interactions, granular systems, patterned ground, self-organization, sorted patterns",

author = "Bernard Hallet and Sletten, {Ronald S.} and Michael Malin and Nicolas Mangold and Sullivan, {Robert J.} and Fair{\'e}n, {Alberto G.} and Germ{\'a}n Mart{\'i}nez and Mariah Baker and Juergen Schieber and Javier Martin-Torres and Zorzano, {Maria Paz}",

note = "The authors are grateful for NASA's support of the Mars Science Laboratory (MSL) mission and for the efforts of the large team of talented and dedicated scientists and engineers who made this work possible. The authors thank, in particular, Jason Van Beek and Tex Kubacki for their astute observations and, together with their Malin Space Science Systems colleagues, for their critical roles in acquiring the images. The authors also thank Michelle Minitti, Tim Olson, and Ken Edgett for their observations and help in obtaining instructive images. The authors appreciate insightful discussions with Doug Jerolmack, Nakul Deshpande, Lucas Goehring, Lu Liu, Quan-Xing Liu, Zhenpeng Ge, Allan Treiman, and Kevin Lewis, which benefitted this paper. The authors thank J. Levy and an anonymous reviewer for their careful evaluations and detailed comments that substantially improved the manuscript. ",

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AU - Hallet, Bernard

AU - Sletten, Ronald S.

AU - Malin, Michael

AU - Mangold, Nicolas

AU - Sullivan, Robert J.

AU - Fairén, Alberto G.

AU - Martínez, Germán

AU - Baker, Mariah

AU - Schieber, Juergen

AU - Martin-Torres, Javier

AU - Zorzano, Maria Paz

N1 - The authors are grateful for NASA's support of the Mars Science Laboratory (MSL) mission and for the efforts of the large team of talented and dedicated scientists and engineers who made this work possible. The authors thank, in particular, Jason Van Beek and Tex Kubacki for their astute observations and, together with their Malin Space Science Systems colleagues, for their critical roles in acquiring the images. The authors also thank Michelle Minitti, Tim Olson, and Ken Edgett for their observations and help in obtaining instructive images. The authors appreciate insightful discussions with Doug Jerolmack, Nakul Deshpande, Lucas Goehring, Lu Liu, Quan-Xing Liu, Zhenpeng Ge, Allan Treiman, and Kevin Lewis, which benefitted this paper. The authors thank J. Levy and an anonymous reviewer for their careful evaluations and detailed comments that substantially improved the manuscript.

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N2 - On Mars, near the equator, much of the terrain in Gale Crater consists of bedrock outcrops separated by relatively smooth, uniform regolith surfaces. In scattered sites, however, distinct patterns—in the form and texture of the ground surface—contrast sharply with the typical terrain and with eolian bedforms. This paper focuses on these diverse, intriguing ground patterns. They include ∼1 to >10 m-long linear disruptions of uniform regolith surfaces, alignments, and other arrangements of similar-sized rock fragments and shallow, ∼0.1 m-wide sandy troughs 1–10 m in length. Similar features were recognized early in the Mars Science Laboratory (MSL) mission, but they received only limited attention until Curiosity, the MSL rover, encountered striking examples in the Glen Torridon region. Herein, the ground patterns are illustrated with rover images. Potential mechanisms are briefly discussed in the context of the bedrock composition and atmospheric conditions documented by Curiosity. The evidence suggests that the patterns are active forms of spontaneous granular organization. It leads to the hypothesis that the patterns arise and develop from miniscule, inferred cyclic expansion and contraction of the bedrock and regolith, likely driven by oscillating transfers of energy and moisture between the atmosphere and the terrain. The hypothesis has significant implications for studies of contemporary processes on Mars on both sides of the atmosphere-lithosphere interface. The ground patterns, as well as ripples and dunes formed by the wind, constitute remarkable extra-terrestrial examples of granular self-organization, complex phenomena well known in diverse systems on Earth.

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Active Ground Patterns Near Mars' Equator in the Glen Torridon Region of Gale Crater

Abstract

Bibliographical note

Data Availability Statement

Keywords

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