Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars

When the Hale impact crater penetrated the martian cryosphere 1Ga, landforms indicating post-impact volatile mobilisation were generated. We have found landforms in the ejecta blanket of Hale Crater similar to ‘permafrost molards’ found in periglacial environments on Earth, and probably related to t...

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Main Authors: Morino, C., Conway, S., Philippe, M., Peignaux, C., Svennevig, K., Lucas, A., Noblet, A., Roberti, G., Butcher, F., Collins-May, J.
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier BV 2023
Subjects:
Canada
Greenland
Hale
Main Crater
Paatuut
Ice
permafrost
Online Access:https://eprints.whiterose.ac.uk/193955/
https://eprints.whiterose.ac.uk/193955/1/1-s2.0-S0019103522004559-main.pdf
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record_format openpolar
spelling ftleedsuniv:oai:eprints.whiterose.ac.uk:193955 2023-05-15T16:30:19+02:00 Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars Morino, C. Conway, S. Philippe, M. Peignaux, C. Svennevig, K. Lucas, A. Noblet, A. Roberti, G. Butcher, F. Collins-May, J. 2023-02 text https://eprints.whiterose.ac.uk/193955/ https://eprints.whiterose.ac.uk/193955/1/1-s2.0-S0019103522004559-main.pdf en eng Elsevier BV https://eprints.whiterose.ac.uk/193955/1/1-s2.0-S0019103522004559-main.pdf Morino, C., Conway, S., Philippe, M. et al. (7 more authors) (2023) Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars. Icarus, 391. 115363. ISSN 0019-1035 cc_by_4 CC-BY Article PeerReviewed 2023 ftleedsuniv 2023-01-30T22:51:17Z When the Hale impact crater penetrated the martian cryosphere 1Ga, landforms indicating post-impact volatile mobilisation were generated. We have found landforms in the ejecta blanket of Hale Crater similar to ‘permafrost molards’ found in periglacial environments on Earth, and probably related to the past or present presence of volatiles at/near the surface. Permafrost molards are conical mounds of debris associated with landslide deposits, resulting from the degradation of blocks of ice-rich material mobilised by a landslide in periglacial terrains. Here we analyse the spatial and topographic distribution of conical mounds around the Hale crater at regional and local scales, and compare them to those of molards on the deposits of the Mount Meager debris avalanche in Canada. Hale Crater's conical mounds are located at the distal boundary of the thickest ejecta blanket, which is the closest to the main crater. We observe a similar spatial arrangement of molards along the distal parts of the terminal lobe of the Mount Meager debris avalanche. We then compare the morphology and morphometrics of the conical mounds on Hale Crater to those of terrestrial molards on the Paatuut and Niiortuut rock avalanches in western Greenland. We find that morphology and setting of conical mounds within Hale Crater ejecta are consistent with the formation pathway of molards on Earth. We infer that they originated from blocks of ice-cemented regolith that were produced by the Hale-crater-forming impact, transported by the ejecta flows, and finally degraded to cones of debris (molards) on loss of the interstitial ice. The similarities in distribution between the ejecta flows of Hale and Mount Meager debris avalanche on Earth suggest that the mounds resulted from the rheological separation of the ejecta flows, with a relatively fluid-poor phase that allowed the volatile-rich blocks to survive transport. This supports the prevailing hypothesis that the Hale impact event penetrated the martian cryosphere, providing important constraints ... Article in Journal/Newspaper Greenland Ice permafrost White Rose Research Online (Universities of Leeds, Sheffield & York) Canada Greenland Hale ENVELOPE(-86.317,-86.317,-78.067,-78.067) Main Crater ENVELOPE(167.167,167.167,-77.533,-77.533) Paatuut ENVELOPE(-52.750,-52.750,70.250,70.250)
institution Open Polar
collection White Rose Research Online (Universities of Leeds, Sheffield & York)
op_collection_id ftleedsuniv
language English
description When the Hale impact crater penetrated the martian cryosphere 1Ga, landforms indicating post-impact volatile mobilisation were generated. We have found landforms in the ejecta blanket of Hale Crater similar to ‘permafrost molards’ found in periglacial environments on Earth, and probably related to the past or present presence of volatiles at/near the surface. Permafrost molards are conical mounds of debris associated with landslide deposits, resulting from the degradation of blocks of ice-rich material mobilised by a landslide in periglacial terrains. Here we analyse the spatial and topographic distribution of conical mounds around the Hale crater at regional and local scales, and compare them to those of molards on the deposits of the Mount Meager debris avalanche in Canada. Hale Crater's conical mounds are located at the distal boundary of the thickest ejecta blanket, which is the closest to the main crater. We observe a similar spatial arrangement of molards along the distal parts of the terminal lobe of the Mount Meager debris avalanche. We then compare the morphology and morphometrics of the conical mounds on Hale Crater to those of terrestrial molards on the Paatuut and Niiortuut rock avalanches in western Greenland. We find that morphology and setting of conical mounds within Hale Crater ejecta are consistent with the formation pathway of molards on Earth. We infer that they originated from blocks of ice-cemented regolith that were produced by the Hale-crater-forming impact, transported by the ejecta flows, and finally degraded to cones of debris (molards) on loss of the interstitial ice. The similarities in distribution between the ejecta flows of Hale and Mount Meager debris avalanche on Earth suggest that the mounds resulted from the rheological separation of the ejecta flows, with a relatively fluid-poor phase that allowed the volatile-rich blocks to survive transport. This supports the prevailing hypothesis that the Hale impact event penetrated the martian cryosphere, providing important constraints ...
format Article in Journal/Newspaper
author Morino, C.
Conway, S.
Philippe, M.
Peignaux, C.
Svennevig, K.
Lucas, A.
Noblet, A.
Roberti, G.
Butcher, F.
Collins-May, J.
spellingShingle Morino, C.
Conway, S.
Philippe, M.
Peignaux, C.
Svennevig, K.
Lucas, A.
Noblet, A.
Roberti, G.
Butcher, F.
Collins-May, J.
Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars
author_facet Morino, C.
Conway, S.
Philippe, M.
Peignaux, C.
Svennevig, K.
Lucas, A.
Noblet, A.
Roberti, G.
Butcher, F.
Collins-May, J.
author_sort Morino, C.
title Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars
title_short Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars
title_full Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars
title_fullStr Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars
title_full_unstemmed Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars
title_sort permafrost molards as an analogue for ejecta-ice interactions at hale crater, mars
publisher Elsevier BV
publishDate 2023
url https://eprints.whiterose.ac.uk/193955/
https://eprints.whiterose.ac.uk/193955/1/1-s2.0-S0019103522004559-main.pdf
long_lat ENVELOPE(-86.317,-86.317,-78.067,-78.067)
ENVELOPE(167.167,167.167,-77.533,-77.533)
ENVELOPE(-52.750,-52.750,70.250,70.250)
geographic Canada
Greenland
Hale
Main Crater
Paatuut
geographic_facet Canada
Greenland
Hale
Main Crater
Paatuut
genre Greenland
Ice
permafrost
genre_facet Greenland
Ice
permafrost
op_relation https://eprints.whiterose.ac.uk/193955/1/1-s2.0-S0019103522004559-main.pdf
Morino, C., Conway, S., Philippe, M. et al. (7 more authors) (2023) Permafrost molards as an analogue for ejecta-ice interactions at Hale Crater, Mars. Icarus, 391. 115363. ISSN 0019-1035
op_rights cc_by_4
op_rightsnorm CC-BY
_version_ 1766020032010125312

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