Prolonged Record of Hydroclimatic Changes at Antoniadi Crater, Mars

Creators: Zaki, A. S.^{1, 2}; Edgett, K. S.³; Pajola, M.⁴; Kite, E.⁵; Davis, J. M.⁶; Mangold, N.⁷; Madof, A. S.⁸; Lucchetti, A.⁴; Grindrod, P.⁹; Hughes, C. M.¹⁰; Sangwan, K.¹¹; Thomas, N.¹²; Schuster, M.¹³; Gupta, S.¹¹; Cremonese, G.⁴; Castelltort, S.¹

1. University of Geneva
2. California Institute of Technology
3. Malin Space Science Systems (United States)
4. Osservatorio Astronomico di Padova
5. University of Chicago
6. Birkbeck, University of London
7. Laboratoire de Planétologie et Géodynamique de Nantes
8. Chevron (United States)
9. Natural History Museum
10. University of Arkansas at Fayetteville
11. Imperial College London
12. University of Bern
13. UMR 7063, CNRS, Institut Terre et Environnement de Strasbourg, Université de Strasbourg, Strasbourg, France

Abstract

The first billion years of Martian geologic history consisted of surface environments and landscapes dramatically different from those seen today, with flowing liquid water sculpting river channels and ponding to form bodies of water. However, the hydro‐climatic context, the frequency, and the duration under which these systems existed remain uncertain. Addressing these fundamental questions may improve our understanding of early Mars climate. Here, we reconstruct a long‐lived archive consisting of an array of fluvial systems inside the Antoniadi crater––one of the largest lake basins on Mars (9.58 × 104 km2). We found that the fluvial activity occurred throughout four major intermittent active intervals during the Late Noachian to Early Amazonian (∼3.7 to >2.4 Ga). This resulted in at least two major lakes, which formed during periods of markedly increased surface runoff production. The record of these four riverine phases is preserved in fluvial ridges, valley networks, back‐stepping or down‐stepping fan‐shaped landforms, and terrace‐like formations within an outlet canyon. These morphologies point to lake‐controlled base‐level fluctuations suggestive of episodic precipitation‐fed surface runoff punctuated by intermittent catastrophic floods that were capable of breaching crater‐lake rims and incising outlet canyons. Fluvial‐deposit thickness, junction angles of channels, and lake morphometry suggest that riverine systems lasted at least 103–106 years and episodically occurred under primarily arid and semi‐arid climates. These findings place new regional constraints on the fluvial frequency, longevity, and climatic regime of one of the largest Martian lakes, thereby bolstering the hypothesis that episodic warming likely punctuated the planet's early history.

Copyright and License

© 2023. The Authors. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

Acknowledgement

This research was funded by a Swiss Confederation Ph.D. Grant (Nr: 2017.1006) to Abdallah S. Zaki. Additional funding came from the Department of Earth Sciences, University of Geneva. Abdallah Zaki thanks Caleb Fassett, Robin Wordsworth, Luis Valero, and Solmaz Adelia for the helpful discussion about the Antoniadi crater, early Mars climate models, and age models. We thank Bradley Thomson for handling the manuscript. The manuscript has benefited from the constructive comments of Rickbir S. Bahia, Vijayan S, and an anonymous reviewer. This study has been supported by the Italian Space Agency (ASI-INAF agreement no. 2020-17-HH.0). The authors wish to thank the ExoMars spacecraft and CaSSIS instrument engineering teams for the successful completion of the instrument. CaSSIS is a project of the University of Bern and funded through the Swiss Space Office via ESA PRODEX programme. The instrument hardware development was also supported by the Italian Space Agency (ASI) (ASI-INAF agreement no. 2020-17-HH.0), INAF/Astronomical Observatory of Padova, and the Space Research Center (CBK) in Warsaw. Support from SGF (Budapest), the University of Arizona (Lunar and Planetary Lab.) and NASA are also gratefully acknowledged. Operations support from the UK Space Agency under grant ST/R003025/1 is also acknowledged. E.S.K. acknowledges support from NASA (80NSSC20K0144). Open access funding provided by Universite de Geneve.

Data Availability

The following standard data products mentioned in the manuscript are freely accessible via NASA Planetary Data Systems. (a) CTX (Malin, 2007). (b) HiRISE (McEwen, 2007). (c) MOLA (Fergason et al., 2018; Neumann et al., 2003). (d) CaSSIS: CaSSIS data are available through the ESA Planetary Science Archive (accessed CaSSIS, 2023). DTMs, measurements, and calculations are archivedachieved in Zaki (2022).

Additional Information

Supporting information S1: 2022JE007606-sup-0001-Supporting Information SI-S01.pdf

Files

JGR Planets - 2023 - Zaki - Prolonged Record of Hydroclimatic Changes at Antoniadi Crater Mars.pdf

Files (19.6 MB)

Name	Size	Download all
2022je007606-sup-0001-supporting information si-s01.pdf md5:525ac030eb3d206513e48106316de238	1.6 MB	Preview Download
JGR Planets - 2023 - Zaki - Prolonged Record of Hydroclimatic Changes at Antoniadi Crater Mars.pdf md5:a4b1cdf474a3af364c084f5d874c47ec	18.0 MB	Preview Download

Additional details

	All versions	This version
Views	0	0
Downloads	0	0
Data volume	0 Bytes	0 Bytes