Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch

Richard J. Soare; F. Costard; Jean-Pierre Williams; Colman Gallagher; Adam J. Hepburn; D. Stillman; Michelle Koutnik; S. J. Conway; M. Philippe; Frances E. G. Butcher; Lauren E. Mc Keown; E. Godin

doi:10.1016/B978-0-323-99324-1.00008-0

Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch

Richard J. Soare, F. Costard, Jean-Pierre Williams, Colman Gallagher, Adam J. Hepburn, D. Stillman, Michelle Koutnik, S. J. Conway, M. Philippe, Frances E. G. Butcher, Lauren E. Mc Keown, E. Godin

Department of Geography & Earth Sciences

Research output: Chapter in Book/Report/Conference proceeding › Chapter

2 Citations (Scopus)

Abstract

Absent of a humanly wielded pick and shovel digging beneath the surface, the identification of ground (interstitial) ice on Mars formed by the freeze–thaw cycling of water has largely been inferred from presumed periglacial analogues on Earth. Here, we reach beyond the looks-like therefore-must-be paradigm and seek to validate this presumption by two means: (1) Presenting diverse data sets, tools, scales (temporal and spatial), and case studies that point, collectively, to the plausibility of periglacial processes having occurred at the northern mid-latitudes of Mars through the Late Amazonian Epoch. (2) Suggesting that and showing why the litmus test of periglacial plausibility ought not to be derived from current boundary conditions on Mars or models derived therefrom. Towards these twinned ends, we draw upon an admixture of recently published and new work by this chapter’s authors.

Original language	English
Title of host publication	Ices in the Solar-System
Subtitle of host publication	A Volatile-Driven Journey from the Inner Solar System to its Far Reaches
Editors	Richard J. Soare, Jean-Pierre Williams, Caitlin J. Ahrens, Frances E. G. Butcher, Mohamed Ramy El-Maarry
Publisher	Elsevier
Chapter	5
Pages	143-192
Number of pages	50
ISBN (Electronic)	9780323993241
ISBN (Print)	9780323993258
DOIs	https://doi.org/10.1016/B978-0-323-99324-1.00008-0
Publication status	Published - 24 Jan 2024

Keywords

Climate
Freeze–thaw cycling of water and periglaciation
Glacial/periglacial stades
Mars

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10.1016/B978-0-323-99324-1.00008-0

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Soare, R. J., Costard, F., Williams, J.-P., Gallagher, C., Hepburn, A. J., Stillman, D., Koutnik, M., Conway, S. J., Philippe, M., Butcher, F. E. G., Mc Keown, L. E., & Godin, E. (2024). Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch. In R. J. Soare, J.-P. Williams, C. J. Ahrens, F. E. G. Butcher, & M. R. El-Maarry (Eds.), Ices in the Solar-System: A Volatile-Driven Journey from the Inner Solar System to its Far Reaches (pp. 143-192). Elsevier. https://doi.org/10.1016/B978-0-323-99324-1.00008-0

Soare, Richard J. ; Costard, F. ; Williams, Jean-Pierre et al. / Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch. Ices in the Solar-System: A Volatile-Driven Journey from the Inner Solar System to its Far Reaches. editor / Richard J. Soare ; Jean-Pierre Williams ; Caitlin J. Ahrens ; Frances E. G. Butcher ; Mohamed Ramy El-Maarry. Elsevier, 2024. pp. 143-192

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abstract = "Absent of a humanly wielded pick and shovel digging beneath the surface, the identification of ground (interstitial) ice on Mars formed by the freeze–thaw cycling of water has largely been inferred from presumed periglacial analogues on Earth. Here, we reach beyond the looks-like therefore-must-be paradigm and seek to validate this presumption by two means: (1) Presenting diverse data sets, tools, scales (temporal and spatial), and case studies that point, collectively, to the plausibility of periglacial processes having occurred at the northern mid-latitudes of Mars through the Late Amazonian Epoch. (2) Suggesting that and showing why the litmus test of periglacial plausibility ought not to be derived from current boundary conditions on Mars or models derived therefrom. Towards these twinned ends, we draw upon an admixture of recently published and new work by this chapter{\textquoteright}s authors.",

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author = "Soare, \{Richard J.\} and F. Costard and Jean-Pierre Williams and Colman Gallagher and Hepburn, \{Adam J.\} and D. Stillman and Michelle Koutnik and Conway, \{S. J.\} and M. Philippe and Butcher, \{Frances E. G.\} and \{Mc Keown\}, \{Lauren E.\} and E. Godin",

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Soare, RJ, Costard, F, Williams, J-P, Gallagher, C, Hepburn, AJ, Stillman, D, Koutnik, M, Conway, SJ, Philippe, M, Butcher, FEG, Mc Keown, LE & Godin, E 2024, Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch. in RJ Soare, J-P Williams, CJ Ahrens, FEG Butcher & MR El-Maarry (eds), Ices in the Solar-System: A Volatile-Driven Journey from the Inner Solar System to its Far Reaches. Elsevier, pp. 143-192. https://doi.org/10.1016/B978-0-323-99324-1.00008-0

Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch. / Soare, Richard J.; Costard, F.; Williams, Jean-Pierre et al.
Ices in the Solar-System: A Volatile-Driven Journey from the Inner Solar System to its Far Reaches. ed. / Richard J. Soare; Jean-Pierre Williams; Caitlin J. Ahrens; Frances E. G. Butcher; Mohamed Ramy El-Maarry. Elsevier, 2024. p. 143-192.

Research output: Chapter in Book/Report/Conference proceeding › Chapter

TY - CHAP

T1 - Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch

AU - Soare, Richard J.

AU - Costard, F.

AU - Williams, Jean-Pierre

AU - Gallagher, Colman

AU - Hepburn, Adam J.

AU - Stillman, D.

AU - Koutnik, Michelle

AU - Conway, S. J.

AU - Philippe, M.

AU - Butcher, Frances E. G.

AU - Mc Keown, Lauren E.

AU - Godin, E.

PY - 2024/1/24

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N2 - Absent of a humanly wielded pick and shovel digging beneath the surface, the identification of ground (interstitial) ice on Mars formed by the freeze–thaw cycling of water has largely been inferred from presumed periglacial analogues on Earth. Here, we reach beyond the looks-like therefore-must-be paradigm and seek to validate this presumption by two means: (1) Presenting diverse data sets, tools, scales (temporal and spatial), and case studies that point, collectively, to the plausibility of periglacial processes having occurred at the northern mid-latitudes of Mars through the Late Amazonian Epoch. (2) Suggesting that and showing why the litmus test of periglacial plausibility ought not to be derived from current boundary conditions on Mars or models derived therefrom. Towards these twinned ends, we draw upon an admixture of recently published and new work by this chapter’s authors.

AB - Absent of a humanly wielded pick and shovel digging beneath the surface, the identification of ground (interstitial) ice on Mars formed by the freeze–thaw cycling of water has largely been inferred from presumed periglacial analogues on Earth. Here, we reach beyond the looks-like therefore-must-be paradigm and seek to validate this presumption by two means: (1) Presenting diverse data sets, tools, scales (temporal and spatial), and case studies that point, collectively, to the plausibility of periglacial processes having occurred at the northern mid-latitudes of Mars through the Late Amazonian Epoch. (2) Suggesting that and showing why the litmus test of periglacial plausibility ought not to be derived from current boundary conditions on Mars or models derived therefrom. Towards these twinned ends, we draw upon an admixture of recently published and new work by this chapter’s authors.

KW - Climate

KW - Freeze–thaw cycling of water and periglaciation

KW - Glacial/periglacial stades

KW - Mars

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DO - 10.1016/B978-0-323-99324-1.00008-0

M3 - Chapter

AN - SCOPUS:85189595620

SN - 9780323993258

SP - 143

EP - 192

BT - Ices in the Solar-System

A2 - Soare, Richard J.

A2 - Williams, Jean-Pierre

A2 - Ahrens, Caitlin J.

A2 - Butcher, Frances E. G.

A2 - El-Maarry, Mohamed Ramy

PB - Elsevier

ER -

Soare RJ, Costard F, Williams JP, Gallagher C, Hepburn AJ, Stillman D et al. Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch. In Soare RJ, Williams JP, Ahrens CJ, Butcher FEG, El-Maarry MR, editors, Ices in the Solar-System: A Volatile-Driven Journey from the Inner Solar System to its Far Reaches. Elsevier. 2024. p. 143-192 doi: 10.1016/B978-0-323-99324-1.00008-0

Evidence, arguments, and cold-climate geomorphology that favour periglacial cycling at the Martian mid-to-high latitudes in the Late Amazonian Epoch

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