Evidence for Fluctuating Wind in Shaping an Ancient Martian Dune Field: The Stimson Formation at the Greenheugh Pediment, Gale Crater

Temporal fluctuations of wind strength and direction can influence aeolian bedform morphology and orientation, which can be encoded into the architecture of aeolian deposits. These strata represent a direct record of atmospheric processes and can be used to understand ancient Martian atmospheric pro...

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Bibliographic Details
Published in:Journal of geophysical research. Planets 2022-09, Vol.127 (9), p.n/a
Main Authors: Banham, Steven G., Gupta, Sanjeev, Rubin, David M., Bedford, Candice C., Edgar, Lauren A., Bryk, Alex B., Dietrich, William E., Fedo, Christopher M., Williams, Rebecca M., Caravaca, Gwénaël, Barnes, Robert, Paar, Gerhard, Ortner, Thomas, Vasavada, Ashwin R.
Format: Article
Language:English
Subjects:
aeolian
Air flow
Atmospheric circulation
Atmospheric models
Atmospheric processes
Bedforms
climate
Climate control
Climate models
Dunes
Eolian deposits
Flow control
Fluctuations
Gale crater
Habitability
Intervals
Landforms
Mars
Mars atmosphere
Mars craters
Mars science laboratory
Morphology
Orientation
Planetary geology
Sandstone
Sciences of the Universe
Sediment transport
Sedimentary structures
Strata
stratigraph
Temporal resolution
Transport processes
Wind
Wind direction
Wind fluctuations
Wind regime
Wind variations
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Summary:Temporal fluctuations of wind strength and direction can influence aeolian bedform morphology and orientation, which can be encoded into the architecture of aeolian deposits. These strata represent a direct record of atmospheric processes and can be used to understand ancient Martian atmospheric processes as well as those on Earth. The strata can: give insight to ancient atmospheric circulation, how the atmosphere evolved in response to global changes in habitability, and how ancient processes differ from modern processes. The Stimson formation at the Greenheugh pediment (Gale crater) records evidence of fluctuating wind across multiple temporal scales. The strata can be subdivided into three intervals–Gleann Beag, Ladder, and Edinburgh intervals. Internally, the intervals record changes of dune morphology and orientation, correlatable to wind fluctuations at multiple temporal scales. The basal Gleann Beag interval comprises compound cross‐strata, deposited by oblique compound dunes. These dunes record a bimodal wind regime, resulting in net sediment transport toward the north. The Ladder interval records a reversal of sediment transport to the south, where straight‐crested simple‐dunes shaped by a seasonally variable winds formed. Finally, the Edinburgh interval records sediment transport to the west, where a unimodal wind formed sinuous‐crested simple dunes. These observations demonstrate active and variable atmospheric circulation in Gale crater during the accumulation of the Stimson dune field, at multiple temporal scales from seasonally driven winds to much longer time‐frames, during the Hesperian. These observations can be used to further understand ancient atmospheric conditions and processes, at a high temporal resolution on Mars. Plain Language Summary The direction and strength of the wind varies, but typically follows predictable patterns over a variety of time‐scales ranging from the course of a day or a year through to decades or millennia. Within a dune field, these patterns of air flow control the shape, size and orientation of aeolian landforms‐such as dunes and ripples–and in‐turn be recorded in the rock record, where sediment accumulates over time. These deposits form a record of ancient atmospheric processes, and can be found on Mars, as well as Earth. On Mars, within the Stimson sandstone, evidence for short‐ and long‐term wind trends are identified in these strata deposited by ancient dunes. This partial record–resulting from episodic
ISSN:2169-9097
2169-9100
DOI:10.1029/2021JE007023