Climate Forcing of Ripple Migration and Crest Alignment in the Last 400 kyr in Meridiani Planum, Mars

Fenton, L. K.; Carson, Helen; Michaels, Timothy I.

doi:10.1002/2017je005503

Cited by 18 publications

(26 citation statements)

References 55 publications

(106 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Given the scale of the paleo‐dune field discussed in this work, and the consistency in preserved transport direction over >100 km, the ~90° difference between modern and ancient transport requires a regional‐scale difference in atmospheric conditions between today and ancient Mars at the time of this paleo‐dune field. Regional‐scale changes in the dominant sand‐transporting winds could be caused by changes in obliquity, atmospheric density, composition, or solar insolation (Fenton et al, ; Newman et al, ).…”

Section: Discussionmentioning

confidence: 99%

Ancient Stratigraphy Preserving a Wet‐to‐Dry, Fluvio‐Lacustrine to Aeolian Transition Near Barth Crater, Arabia Terra, Mars

2019

View full text Add to dashboard Cite

Ancient lacustrine and aeolian sediments have been separately identified in a variety of locations on Mars. In this work, we interpret the depositional history of Barth crater and its surrounding area in Arabia Terra where exposed geologic units preserve a record of lacustrine and aeolian interaction. Aeolian sandstone in the study area overlies lacustrine strata and is interbedded with easily eroded interdune deposits. The aeolian sandstone preserves dune strata with structures that indicate paleo‐sediment transport toward the northwest. The aeolian unit also preserves a transition up‐section from separated barchan dunes to continuous transverse dunes, capturing the development of the ancient dune field from sediment limited to sediment rich. Inverted fluvial channels provide evidence that water was delivered to the area at the same time the dune field was present, providing a simple mechanism, via wetting and cementation, for aeolian strata preservation. This example of wet‐system aeolian accumulation preserves an upward drying sequence in the sedimentary record that may have been coincident with the widely hypothesized global climate transition. The terrains described in this work provide a framework for interpreting similar aeolian units in elsewhere on Mars, even where cross‐strata cannot be easily resolved.

show abstract

Section: Discussionmentioning

confidence: 99%

Ancient Stratigraphy Preserving a Wet‐to‐Dry, Fluvio‐Lacustrine to Aeolian Transition Near Barth Crater, Arabia Terra, Mars

2019

View full text Add to dashboard Cite

show abstract

“…These boundary conditions can change over time and create shifting cryospheric and aeolian environments (e.g., Brothers & Kocurek, 2018). For example, studies have turned to variations in orbital parameters of Mars to explain climate change; Martian obliquity, which varies with a periodicity of 10 4 -10 5 years and which can strongly influence insolation and change atmospheric density and wind strengths (Brothers & Kocurek, 2018;Haberle et al, 2003;Head et al, 2003;Laskar et al, 2004), likely serves as a cyclical climate forcing agent influencing the formation and stabilization of dune fields and sand sheets (e.g., Ayoub et al, 2014;Brothers & Kocurek, 2018;Fenton et al, 2018;Laskar et al, 2004;. Since we can assume that these dune fields originally accumulated in an environment in which sand availability and wind transport capacity allowed sand saltation and dune accumulation, we can also interpret, in accordance with Fenton and Hayward (2010), the morphological shift to SI values >1 as a potential indicator of climate change postdating the formation of the dune fields.…”

Section: 1029/2018je005747mentioning

confidence: 99%

“…Thus, our combined observations of high-latitude dune mobility and modification may reflect a recent shift in the climate to activate or stabilize these dune fields. For example, studies have turned to variations in orbital parameters of Mars to explain climate change; Martian obliquity, which varies with a periodicity of 10 4 -10 5 years and which can strongly influence insolation and change atmospheric density and wind strengths (Brothers & Kocurek, 2018;Haberle et al, 2003;Head et al, 2003;Laskar et al, 2004), likely serves as a cyclical climate forcing agent influencing the formation and stabilization of dune fields and sand sheets (e.g., Ayoub et al, 2014;Brothers & Kocurek, 2018;Fenton et al, 2018;Laskar et al, 2004;.…”

Section: 1029/2018je005747mentioning

confidence: 99%

“…Multiple studies have now revealed present-day movement of sand by the wind and migration of bedforms (dunes and ripples collectively) in some environments in the current Martian climate and~6-mbar atmosphere (e.g., Banks et al, 2015;Banks et al, 2017;Bourke et al, 2008;Bridges et al, 2010Bridges et al, , 2012Bridges et al, , 2013Chojnacki et al, 2011Chojnacki et al, , 2014Chojnacki et al, , 2015Chojnacki et al, , 2017Chojnacki et al, , 2018aChojnacki et al, , 2018bFenton, 2006;Silvestro et al, 2010Silvestro et al, , 2011Silvestro et al, , 2013Silvestro et al, , 2016Sullivan et al, 2008). Dune field and sand sheet formation, activity, and stabilization, on both Earth and Mars, are driven by factors such as sediment availability and wind transport capacity, potentially initiated by changes in climatic conditions (e.g., Ayoub et al, 2014;Fenton et al, 2015Fenton et al, , 2018Kocurek, 1998;Kocurek et al, 2007;Kocurek & Lancaster, 1999;Runyon, Bridges, Ayoub, et al, 2017;Silvestro et al, 2015).…”

mentioning

confidence: 99%

See 1 more Smart Citation

Patterns in Mobility and Modification of Middle‐ and High‐Latitude Southern Hemisphere Dunes on Mars

et al. 2018

Self Cite

View full text Add to dashboard Cite

Change detection analyses of aeolian bedforms (dunes and ripples), using multitemporal images acquired by the Mars Reconnaissance Orbiter High Resolution Imaging Science Experiment (HiRISE), can reveal migration of bedforms on Mars. Here we investigated bedform mobility (evidence of wind‐driven migration or activity), from analysis of HiRISE temporal image pairs, and dune field modification (i.e., apparent presence/lack of changes or degradation due to nonaeolian processes) through use of a dune stability index or SI (1–6; higher numbers indicating increasing evidence of stability/modification). Combining mobility data and SI for 70 dune fields south of 40°S latitude, we observed a clear trend of decreasing bedform mobility with increasing SI and latitude. Both dunes and ripples were more commonly active at lower latitudes, although some high‐latitude ripples are migrating. Most dune fields with lower SIs (≤3) were found to be active while those with higher SIs were primarily found to be inactive. A shift in prevalence of active to apparently inactive bedforms and to dune fields with SI ≥ 2 occurs at ~60°S latitude, coincident with the edge of high concentrations of H2O‐equivalent hydrogen observed by the Mars Odyssey Neutron Spectrometer. This result is consistent with previous studies suggesting that stabilizing agents, such as ground ice, likely stabilize bedforms and limit sediment availability. Observations of active dune fields with morphologies indicative of stability (i.e., migrating ripples in SI = 3 dune fields) may have implications for episodic phases of reworking or dune building, and possibly geologically recent activation or stabilization corresponding to shifts in climate.

show abstract

“…The orientation of the interior mound and trough is also consistent with mesoscale atmospheric modeling over Endeavour that shows a dominant wind regime with winds coming from the east to the southeast for multiple hours each sol (Chojnacki et al, ; Fenton et al, ). In addition, Fenton et al (, ) have shown that longer‐term regional‐scale easterlies are predicted to be the dominant sediment‐moving winds, consistent with the north‐south oriented crest lines associated with wind‐blown ripples that cover much of the Meridiani plains (Arvidson et al, ).…”

Section: Regional Contextmentioning

confidence: 82%

Degradation of Endeavour Crater Based on Orbital and Rover‐Based Observations in Combination With Landscape Evolution Modeling

et al. 2019

View full text Add to dashboard Cite

Exploration of Endeavour crater's Shoemaker formation rim rocks by the Opportunity rover, combined with extensive observations from the Mars Express and Mars Reconnaissance Orbiters, provides unique and quantitative insights into the processes that have degraded this 22‐km diameter Noachian age impact crater. These insights are informed by comparisons between Endeavour and the relatively young, and morphologically fresh appearing, 19‐km diameter Bopolu crater located 65 km to the southwest. Analyses of rover and orbiter data, combined with landscape evolution modeling using Bopolu topography as a starting point, demonstrate that significant weathering and fluvial degradation of Endeavour occurred during the Noachian Period, with ~0.3 km of vertical rim removal, ~0.9‐km backwasting of the rim, and deposition of ~0.5 km of fluvial‐deltaic‐lacustrine sediments on the crater floor, sourced from rim erosion. Pediments formed on external rim segments, with characteristic thin regolith covers over graded bedrock. Late Noachian to Early Hesperian age Grasberg formation draping sediments, and Burns formation sulfate‐rich sandstones, subsequently embayed all but high standing Shoemaker formation rocks. Burns formation strata accumulated in the crater interior up to a depth of ~0.8 km. Subsequent wind erosion of the interior deposits is indicated by an interior mound and moat, together with yardangs carved into Shoemaker formation rocks, and graded topographic profiles from Grasberg and Burns formation rocks up and through the interior rim Shoemaker formation outcrops. Up to ~0.4 km of Burns formation rocks were exhumed from within the crater by wind erosion to produce the mound and moat.

show abstract

Climate Forcing of Ripple Migration and Crest Alignment in the Last 400 kyr in Meridiani Planum, Mars

Cited by 18 publications

References 55 publications

Ancient Stratigraphy Preserving a Wet‐to‐Dry, Fluvio‐Lacustrine to Aeolian Transition Near Barth Crater, Arabia Terra, Mars

Ancient Stratigraphy Preserving a Wet‐to‐Dry, Fluvio‐Lacustrine to Aeolian Transition Near Barth Crater, Arabia Terra, Mars

Patterns in Mobility and Modification of Middle‐ and High‐Latitude Southern Hemisphere Dunes on Mars

Degradation of Endeavour Crater Based on Orbital and Rover‐Based Observations in Combination With Landscape Evolution Modeling

Contact Info

Product

Resources

About