R. Greeley scite author profile

[1] The ripple field known as ''El Dorado'' was a unique stop on Spirit's traverse where dust-raising, active mafic sand ripples and larger inactive coarse-grained ripples interact, illuminating several long-standing issues of Martian dust mobility, sand mobility, and the origin of transverse aeolian ridges. Strong regional wind events endured by Spirit caused perceptible migration of ripple crests in deposits SSE of El Dorado, erasure of tracks in sandy areas, and changes to dust mantling the site. Localized thermal vortices swept across El Dorado, leaving paths of reduced dust but without perceptibly damaging nearly cohesionless sandy ripple crests. From orbit, winds responsible for frequently raising clay-sized dust into the atmosphere do not seem to significantly affect dunes composed of (more easily entrained) sand-sized particles, a long-standing paradox. This disparity between dust mobilization and sand mobilization on Mars is due largely to two factors: (1) dust occurs on the surface as fragile, low-density, sand-sized aggregates that are easily entrained and disrupted, compared with clay-sized air fall particles; and (2) induration of regolith is pervasive. Light-toned bed forms investigated at Gusev are coarse-grained ripples, an interpretation we propose for many of the smallest linear, lighttoned bed forms of uncertain origin seen in high-resolution orbital images across Mars. On Earth, wind can organize bimodal or poorly sorted loose sediment into coarse-grained ripples. Coarse-grained ripples could be relatively common on Mars because development of durable, well-sorted sediments analogous to terrestrial aeolian quartz sand deposits is restricted by the lack of free quartz and limited hydraulic sediment processing.Citation: Sullivan, R., et al. (2008), Wind-driven particle mobility on Mars: Insights from Mars Exploration Rover observations at ''El Dorado'' and surroundings at Gusev Crater,

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Aeolian processes at the Mars Exploration Rover Meridiani Planum landing site

Sullivan

Banfield

Bell

et al. 2005

Nature

249

331

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The martian surface is a natural laboratory for testing our understanding of the physics of aeolian (wind-related) processes in an environment different from that of Earth. Martian surface markings and atmospheric opacity are time-variable, indicating that fine particles at the surface are mobilized regularly by wind'"'. Regolith (unconsolidated surface material) at the Mars Exploration Rover Opportunity's landing site has been affected greatly by wind, which has created and reoriented bedforms, sorted grains, and eroded bedrock. Aeolian features here preserve a unique record of changing wind direction and wind strength. Here we present an in situ examination of a martian bright wind streak, which provides evidence consistent with a previously proposed formational model'''^ for such features. We also show that a widely used criterion for distinguishing between aeolian saltation-and suspension-dominated grain behaviour is different on Mars, and that estimated wind friction speeds between 2 and 3ms~', most recently from the northwest, are associated with recent global dust storms, providing ground truth for climate model predictions.Pre-landing orbiter observations of Opportunity's landing site showed bright and dark streaks tapering away from craters on the Meridiani plains. From observations of similar features distributed across many locations on Mars, streak orientations indicate formative wind directions'""*. High-resolution images within the 117 km X 18 km landing ellipse obtained over several years show bright streak directions that indicate winds from the northwest and southeast'. What has not been recognized previously, however, is that this apparent bimodality of wind direction has a significant time dependence. Images obtained before the major 2001 dust storm are more likely to show bright streaks oriented in the opposite direction from images obtained after the storm waned. Rare overlapping image pairs provide two examples of an individual streak changing orientation after the intervening 2001 dust storm (Fig.

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The Opportunity Rover's Athena Science Investigation at Meridiani Planum, Mars

Squyres

Arvidson

Bell

et al. 2004

Science

518

340

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The Mars Exploration Rover Opportunity has investigated the landing site in Eagle crater and the nearby plains within Meridiani Planum. The soils consist of fine-grained basaltic sand and a surface lag of hematite-rich spherules, spherule fragments, and other granules. Wind ripples are common. Underlying the thin soil layer, and exposed within small impact craters and troughs, are flat-lying sedimentary rocks. These rocks are finely laminated, are rich in sulfur, and contain abundant sulfate salts. Small-scale cross-lamination in some locations provides evidence for deposition in flowing liquid water. We interpret the rocks to be a mixture of chemical and siliciclastic sediments formed by episodic inundation by shallow surface water, followed by evaporation, exposure, and desiccation. Hematite-rich spherules are embedded in the rock and eroding from them. We interpret these spherules to be concretions formed by postdepositional diagenesis, again involving liquid water.

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R. Greeley

Stratigraphy and sedimentology of a dry to wet eolian depositional system, Burns formation, Meridiani Planum, Mars

Wind‐driven particle mobility on Mars: Insights from Mars Exploration Rover observations at “El Dorado” and surroundings at Gusev Crater

Aeolian processes at the Mars Exploration Rover Meridiani Planum landing site

The Opportunity Rover's Athena Science Investigation at Meridiani Planum, Mars

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