Widespread Exposures of Extensive Clean Shallow Ice in the Midlatitudes of Mars

Colin M. Dundas; Michael T. Mellon; Susan J. Conway; Ingrid J. Daubar; Kaj E. Williams; Lujendra Ojha; James J. Wray; Ali M. Bramson; Shane Byrne; Alfred S. McEwen; Liliya V. Posiolova; Gunnar Speth; Donna Viola; Margaret E. Landis; Gareth A. Morgan; Asmin V. Pathare

doi:10.1029/2020JE006617

Widespread Exposures of Extensive Clean Shallow Ice in the Midlatitudes of Mars

Colin M. Dundas, Michael T. Mellon, Susan J. Conway, Ingrid J. Daubar, Kaj E. Williams, Lujendra Ojha, James J. Wray, Ali M. Bramson, Shane Byrne, Alfred S. McEwen, Liliya V. Posiolova, Gunnar Speth, Donna Viola, Margaret E. Landis, Gareth A. Morgan, Asmin V. Pathare

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

16 Scopus citations

Abstract

Although ice in the Martian midlatitudes is typically covered by a layer of dust or regolith, it is exposed in some locations by fresh impact craters or in erosional scarps. In both cases, the exposed ice is massive or excess ice with a low lithic content. We find that erosional scarps occur between 50° and 61° north and south latitude and that they are concentrated in and near Milankovič crater in the northern hemisphere and southeast of the Hellas basin in the southern hemisphere. These may represent locations of particularly thick or clean bodies of ice. Pits created by retreat of the scarps represent sublimation-thermokarst landforms that evolve in a manner distinct from other ice-loss landforms on Mars. New impact craters reveal that clean subsurface ice is widespread at middle- and high-latitudes in both hemispheres at depths less than 1 m. Both the depth to ice and the ice content appear to exhibit significant variability over tens to hundreds of meters. The lowest-latitude exposed ice is near 39°N and is at the edge of a region where impact exposures between 40° and 50°N are common, consistent with other indications of a high ice content. This lowest-latitude ice may be currently unstable and subliming. Impact craters on lineated valley fill excavate ice blocks that may represent the top of debris-covered glacial ice. Together, these landforms indicate widespread, clean subsurface ice at middle-latitudes on Mars. The distribution and properties of this ice could provide information about past climate conditions.

Original language	English (US)
Article number	e2020JE006617
Journal	Journal of Geophysical Research: Planets
Volume	126
Issue number	3
DOIs	https://doi.org/10.1029/2020JE006617
State	Published - Mar 2021

Keywords

Geomorphology
Mars
glaciers
impact craters
midlatitudes
subsurface ice

ASJC Scopus subject areas

Geophysics
Geochemistry and Petrology
Earth and Planetary Sciences (miscellaneous)
Space and Planetary Science

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10.1029/2020JE006617

Cite this

Dundas, C. M., Mellon, M. T., Conway, S. J., Daubar, I. J., Williams, K. E., Ojha, L., Wray, J. J., Bramson, A. M., Byrne, S., McEwen, A. S., Posiolova, L. V., Speth, G., Viola, D., Landis, M. E., Morgan, G. A., & Pathare, A. V. (2021). Widespread Exposures of Extensive Clean Shallow Ice in the Midlatitudes of Mars. Journal of Geophysical Research: Planets, 126(3), [e2020JE006617]. https://doi.org/10.1029/2020JE006617

Dundas, CM, Mellon, MT, Conway, SJ, Daubar, IJ, Williams, KE, Ojha, L, Wray, JJ, Bramson, AM, Byrne, S , McEwen, AS, Posiolova, LV, Speth, G, Viola, D, Landis, ME, Morgan, GA & Pathare, AV 2021, 'Widespread Exposures of Extensive Clean Shallow Ice in the Midlatitudes of Mars', Journal of Geophysical Research: Planets, vol. 126, no. 3, e2020JE006617. https://doi.org/10.1029/2020JE006617

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title = "Widespread Exposures of Extensive Clean Shallow Ice in the Midlatitudes of Mars",

abstract = "Although ice in the Martian midlatitudes is typically covered by a layer of dust or regolith, it is exposed in some locations by fresh impact craters or in erosional scarps. In both cases, the exposed ice is massive or excess ice with a low lithic content. We find that erosional scarps occur between 50° and 61° north and south latitude and that they are concentrated in and near Milankovi{\v c} crater in the northern hemisphere and southeast of the Hellas basin in the southern hemisphere. These may represent locations of particularly thick or clean bodies of ice. Pits created by retreat of the scarps represent sublimation-thermokarst landforms that evolve in a manner distinct from other ice-loss landforms on Mars. New impact craters reveal that clean subsurface ice is widespread at middle- and high-latitudes in both hemispheres at depths less than 1 m. Both the depth to ice and the ice content appear to exhibit significant variability over tens to hundreds of meters. The lowest-latitude exposed ice is near 39°N and is at the edge of a region where impact exposures between 40° and 50°N are common, consistent with other indications of a high ice content. This lowest-latitude ice may be currently unstable and subliming. Impact craters on lineated valley fill excavate ice blocks that may represent the top of debris-covered glacial ice. Together, these landforms indicate widespread, clean subsurface ice at middle-latitudes on Mars. The distribution and properties of this ice could provide information about past climate conditions.",

keywords = "Geomorphology, Mars, glaciers, impact craters, midlatitudes, subsurface ice",

author = "Dundas, {Colin M.} and Mellon, {Michael T.} and Conway, {Susan J.} and Daubar, {Ingrid J.} and Williams, {Kaj E.} and Lujendra Ojha and Wray, {James J.} and Bramson, {Ali M.} and Shane Byrne and McEwen, {Alfred S.} and Posiolova, {Liliya V.} and Gunnar Speth and Donna Viola and Landis, {Margaret E.} and Morgan, {Gareth A.} and Pathare, {Asmin V.}",

note = "Funding Information: Icy scarp analysis was funded by the NASA Solar System Workings Program agreement 80HQTR19T0019, and assessment of HiRISE observations of ice‐exposing craters was funded by the Mars Subsurface Water Ice Mapping project (JPL subcontract JPL1639821). S. J. Conway is grateful to the French Space Agency CNES for supporting her HiRISE‐related work. I. J. Daubar was funded by NASA Solar System Workings grant 80NSSC20K0789. CTX, HiRISE, and CRISM targeting was funded by the Mars Reconnaissance Orbiter Project, and the authors thank the project operations teams for their work to acquire the data used in this study. The CTX operations team planned many images to search for new impacts and identified locations of candidates for HiRISE targeting. Jay Dickson and Mathieu Vincendon provided detailed and helpful reviews. Marc Hunter assisted with preparation of the USGS Data Release. Funding Information: Icy scarp analysis was funded by the NASA Solar System Workings Program agreement 80HQTR19T0019, and assessment of HiRISE observations of ice-exposing craters was funded by the Mars Subsurface Water Ice Mapping project (JPL subcontract JPL1639821). S. J. Conway is grateful to the French Space Agency CNES for supporting her HiRISE-related work. I. J. Daubar was funded by NASA Solar System Workings grant 80NSSC20K0789. CTX, HiRISE, and CRISM targeting was funded by the Mars Reconnaissance Orbiter Project, and the authors thank the project operations teams for their work to acquire the data used in this study. The CTX operations team planned many images to search for new impacts and identified locations of candidates for HiRISE targeting. Jay Dickson and Mathieu Vincendon provided detailed and helpful reviews. Marc Hunter assisted with preparation of the USGS Data Release. Publisher Copyright: {\textcopyright} 2021. American Geophysical Union. This article has been contributed to by US Government employees and their work is in the public domain in the USA.",

year = "2021",

month = mar,

doi = "10.1029/2020JE006617",

language = "English (US)",

volume = "126",

journal = "Journal of Geophysical Research: Planets",

issn = "2169-9097",

number = "3",

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TY - JOUR

T1 - Widespread Exposures of Extensive Clean Shallow Ice in the Midlatitudes of Mars

AU - Dundas, Colin M.

AU - Mellon, Michael T.

AU - Conway, Susan J.

AU - Daubar, Ingrid J.

AU - Williams, Kaj E.

AU - Ojha, Lujendra

AU - Wray, James J.

AU - Bramson, Ali M.

AU - Byrne, Shane

AU - McEwen, Alfred S.

AU - Posiolova, Liliya V.

AU - Speth, Gunnar

AU - Viola, Donna

AU - Landis, Margaret E.

AU - Morgan, Gareth A.

AU - Pathare, Asmin V.

N1 - Funding Information: Icy scarp analysis was funded by the NASA Solar System Workings Program agreement 80HQTR19T0019, and assessment of HiRISE observations of ice‐exposing craters was funded by the Mars Subsurface Water Ice Mapping project (JPL subcontract JPL1639821). S. J. Conway is grateful to the French Space Agency CNES for supporting her HiRISE‐related work. I. J. Daubar was funded by NASA Solar System Workings grant 80NSSC20K0789. CTX, HiRISE, and CRISM targeting was funded by the Mars Reconnaissance Orbiter Project, and the authors thank the project operations teams for their work to acquire the data used in this study. The CTX operations team planned many images to search for new impacts and identified locations of candidates for HiRISE targeting. Jay Dickson and Mathieu Vincendon provided detailed and helpful reviews. Marc Hunter assisted with preparation of the USGS Data Release. Funding Information: Icy scarp analysis was funded by the NASA Solar System Workings Program agreement 80HQTR19T0019, and assessment of HiRISE observations of ice-exposing craters was funded by the Mars Subsurface Water Ice Mapping project (JPL subcontract JPL1639821). S. J. Conway is grateful to the French Space Agency CNES for supporting her HiRISE-related work. I. J. Daubar was funded by NASA Solar System Workings grant 80NSSC20K0789. CTX, HiRISE, and CRISM targeting was funded by the Mars Reconnaissance Orbiter Project, and the authors thank the project operations teams for their work to acquire the data used in this study. The CTX operations team planned many images to search for new impacts and identified locations of candidates for HiRISE targeting. Jay Dickson and Mathieu Vincendon provided detailed and helpful reviews. Marc Hunter assisted with preparation of the USGS Data Release. Publisher Copyright: © 2021. American Geophysical Union. This article has been contributed to by US Government employees and their work is in the public domain in the USA.

PY - 2021/3

Y1 - 2021/3

N2 - Although ice in the Martian midlatitudes is typically covered by a layer of dust or regolith, it is exposed in some locations by fresh impact craters or in erosional scarps. In both cases, the exposed ice is massive or excess ice with a low lithic content. We find that erosional scarps occur between 50° and 61° north and south latitude and that they are concentrated in and near Milankovič crater in the northern hemisphere and southeast of the Hellas basin in the southern hemisphere. These may represent locations of particularly thick or clean bodies of ice. Pits created by retreat of the scarps represent sublimation-thermokarst landforms that evolve in a manner distinct from other ice-loss landforms on Mars. New impact craters reveal that clean subsurface ice is widespread at middle- and high-latitudes in both hemispheres at depths less than 1 m. Both the depth to ice and the ice content appear to exhibit significant variability over tens to hundreds of meters. The lowest-latitude exposed ice is near 39°N and is at the edge of a region where impact exposures between 40° and 50°N are common, consistent with other indications of a high ice content. This lowest-latitude ice may be currently unstable and subliming. Impact craters on lineated valley fill excavate ice blocks that may represent the top of debris-covered glacial ice. Together, these landforms indicate widespread, clean subsurface ice at middle-latitudes on Mars. The distribution and properties of this ice could provide information about past climate conditions.

AB - Although ice in the Martian midlatitudes is typically covered by a layer of dust or regolith, it is exposed in some locations by fresh impact craters or in erosional scarps. In both cases, the exposed ice is massive or excess ice with a low lithic content. We find that erosional scarps occur between 50° and 61° north and south latitude and that they are concentrated in and near Milankovič crater in the northern hemisphere and southeast of the Hellas basin in the southern hemisphere. These may represent locations of particularly thick or clean bodies of ice. Pits created by retreat of the scarps represent sublimation-thermokarst landforms that evolve in a manner distinct from other ice-loss landforms on Mars. New impact craters reveal that clean subsurface ice is widespread at middle- and high-latitudes in both hemispheres at depths less than 1 m. Both the depth to ice and the ice content appear to exhibit significant variability over tens to hundreds of meters. The lowest-latitude exposed ice is near 39°N and is at the edge of a region where impact exposures between 40° and 50°N are common, consistent with other indications of a high ice content. This lowest-latitude ice may be currently unstable and subliming. Impact craters on lineated valley fill excavate ice blocks that may represent the top of debris-covered glacial ice. Together, these landforms indicate widespread, clean subsurface ice at middle-latitudes on Mars. The distribution and properties of this ice could provide information about past climate conditions.

KW - Geomorphology

KW - Mars

KW - glaciers

KW - impact craters

KW - midlatitudes

KW - subsurface ice

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Widespread Exposures of Extensive Clean Shallow Ice in the Midlatitudes of Mars

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