Geological context and vents morphology of the ultramafic‐hosted Ashadze hydrothermal areas (Mid‐Atlantic Ridge 13°N)

Ondréas, Hélène; Cannat, Mathilde; Fouquet, Yves; Normand, Alain

doi:10.1029/2012gc004433

Cited by 31 publications

(20 citation statements)

References 81 publications

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“…Our observations in the Ashadze region suggest that slope failure in the ultramafic rocks that form the axial valley wall limits the overall slope to ~18° when the angle of emergence of the exhumation fault exceeds this value. Such a low equilibrium angle could be due to the combined effects of three factors: (1) the abundance of weak hydrous minerals such as serpentine and talc present in the exhumed ultramafic rocks [ Picazo et al ., ]; (2) sub‐surface active hydrothermal processes promoting in situ mineral alteration and high temperatures [ Ondréas et al ., ]; and (3) weakness zones created by the landslide sliding surfaces and fractures (Figure a). At this point, we do not have constraints on which of these factors are preeminent, and we lack similar high‐resolution mapping for ultramafic slopes in other regions of the Mid‐Atlantic Ridge.…”

Section: Discussionmentioning

confidence: 98%

High‐resolution bathymetry reveals contrasting landslide activity shaping the walls of the Mid‐Atlantic Ridge axial valley

Cannat

Mangeney

Ondréas

et al. 2013

Geochem Geophys Geosyst

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[1] Axial valleys are found along most slow-spreading mid-ocean ridges and are one of the most prominent topographic features on Earth. In this paper, we present the first deep-tow swath bathymetry for the axial valley walls of the Mid-Atlantic Ridge. These data allow us to analyze axial valley wall morphology with a very high resolution (0.5 to 1 m compared to ≥ 50 m for shipboard multibeam bathymetry), revealing the role played by landslides. Slow-spreading ridge axial valleys also commonly expose mantle-derived serpentinized peridotites in the footwalls of large offset normal faults (detachments). In our map of the Ashadze area (lat. 13 N), ultramafic outcrops have an average slope of 18 and behave as sliding deformable rock masses, with little fragmentation. By contrast, the basaltic seafloor in the Krasnov area (lat. 16 38 0 N) has an average slope of 32 and the erosion of the steep basaltic rock faces leads to extensive fragmentation, forming debris with morphologies consistent with noncohesive granular flow. Comparison with laboratory experiments suggests that the repose angle for this basaltic debris is > 25. We discuss the interplay between the normal faults that bound the axial valley and the observed mass wasting processes. We propose that, along axial valley walls where serpentinized peridotites are exposed by detachment faults, mass wasting results in average slopes ≤ 20 , even in places where the emergence angle of the detachment is larger.

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Section: Discussionmentioning

confidence: 98%

High‐resolution bathymetry reveals contrasting landslide activity shaping the walls of the Mid‐Atlantic Ridge axial valley

Cannat

Mangeney

Ondréas

et al. 2013

Geochem Geophys Geosyst

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“…Furthermore, it should be noted that not all sulfide deposits spatially associated with detachment faults and oceanic core complexes are located on the hanging wall; some are perched high above the axial valley on the exposed fault surface (e.g., the Logatchev (14°45'N, MidAtlantic Ridge) and Ashadze (13°N, Mid-Atlantic Ridge) hydrothermal fields (Petersen et al, 2010;Ondréas et al, 2012). Given the importance of detachment faulting for crustal extension at slow spreading ridges, the fundamental question that needs to be addressed is: How do detachment fault systems, and the structure at depth associated with these systems (e.g., presence of plutons and/or high permeability zones), influence the pattern of hydrothermal circulation, mineral deposition, and fluid chemistry, both in space and time, within slowly accreted ocean crust?…”

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confidence: 99%

The Trans-Atlantic Geotraverse hydrothermal field: A hydrothermal system on an active detachment fault

Humphris

Tivey

2015

Deep Sea Research Part II: Topical Studies in Oceanography

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Over the last ten years, geophysical studies have revealed that the Trans-Atlantic Geotraverse (TAG) hydrothermal field (26°08'N on the Mid-Atlantic Ridge) is located on the hanging wall of an active detachment fault. This is particularly important in light of the recognition that detachment faulting accounts for crustal accretion/extension along a significant portion of the Mid-Atlantic Ridge, and that the majority of confirmed vent sites on this slow-spreading ridge are hosted on detachment faults. The TAG hydrothermal field is one of the largest sites of high-temperature hydrothermal activity and mineralization found to date on the seafloor, and is comprised of active and relict deposits in different stages of evolution. The episodic nature of hydrothermal activity over the last 140 ka provides strong evidence that the complex shape and geological structure of the active detachment fault system exerts first order, but poorly understood, influences on the hydrothermal circulation patterns, fluid chemistry, and mineral deposition. While hydrothermal circulation extracts heat from a deep source region, the location of the source region at TAG is unknown. Hydrothermal upflow is likely focused along the relatively permeable detachment fault interface at depth, and then the high temperature fluids leave the low-angle portion of the detachment fault and rise vertically through the highly fissured hanging wall to the seafloor. The presence of abundant anhydrite in the cone on the summit of the TAG active mound and in veins in the crust beneath provides evidence for a fluid circulation system that entrains significant amounts of seawater into the shallow parts of the mound and stockwork. Given the importance of detachment faulting for crustal extension at slow spreading ridges, the fundamental question that still needs to be addressed is: How do detachment fault systems, and the structure at depth associated with these systems (e.g., presence of plutons and/or high permeability zones) influence the pattern of hydrothermal circulation, mineral deposition, and fluid chemistry, both in space and time, within slowly accreted ocean crust?

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“…The first ultramafic‐hosted hydrothermal site to be discovered was Logatchev, located at 14°45′N on the MAR [ Bogdanov et al ., ]. Since then, several inactive and active ultramafic‐hosted sites have been identified along the MAR, including Menez Hom at 37°9′N, Saldanha at 36°34′N, Lost City at 30°N, Semyonov at 13°30′N, Ashadze at 12°58′N, and Nibelungen at 8.3°S [e.g., Barriga et al ., ; Beltenev et al ., ; Fouquet et al ., ; Kelley et al ., ; Melchert et al ., ; Ondréas et al ., ]. Active and inactive sites, some also likely hosted on an ultramafic basement, have been reported along the South‐West Indian Ridge (SWIR) [e.g., German et al ., ; Bach et al ., ], the Mid‐Cayman ridge [ German et al ., ], the Central Indian Ridge [ Kumagai et al ., ], and the Arctic Ridges [ Pedersen et al ., ].…”

Section: Introductionmentioning

confidence: 99%

Tectonic structure, lithology, and hydrothermal signature of the Rainbow massif (Mid-Atlantic Ridge 36°14′N)

Andréani

Escartı́n

Delacour

et al. 2014

Geochem. Geophys. Geosyst.

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Rainbow is a dome-shaped massif at the 36 14 0 N nontransform offset along the Mid-AtlanticRidge. It hosts three ultramafic-hosted hydrothermal sites: Rainbow is active and high temperature; Clamstone and Ghost City are fossil and low temperature. The MoMARDREAM cruises (2007, 2008) presented here provided extensive rock sampling throughout the massif that constrains the geological setting of hydrothermal activity. The lithology is heterogeneous with abundant serpentinites surrounding gabbros, troctolites, chromitites, plagiogranites, and basalts. We propose that a W dipping detachment fault, now inactive, uplifted the massif and exhumed these deep-seated rocks. Present-day deformation is accommodated by SSW-NNE faults and fissures, consistent with oblique teleseismic focal mechanisms and stress rotation across the discontinuity. Faults localize fluid flow and control the location of fossil and active hydrothermal fields that appear to be ephemeral and lacking in spatiotemporal progression. Markers of high-temperature hydrothermal activity (350 C) are restricted to some samples from the active field while a more diffuse, lower temperature hydrothermal activity (<220 C) is inferred at various locations through anomalously high As, Sb, and Pb contents, attributed to element incorporation in serpentines or microscalesulfide precipitation. Petrographic and geochemical analyses show that the dominant basement alteration is pervasive peridotite serpentinization at 160-260 C, attributed to fluids chemically similar to those venting at Rainbow, and controlled by concomitant alteration of mafic-ultramafic units at depth. Rainbow provides a model for fluid circulation, possibly applicable to hydrothermalism at oceanic detachments elsewhere, where both low-temperature serpentinization and magmatic-driven high-temperature outflow develop contemporaneously, channeled by faults in the footwall and not along the detachment fault.

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Geological context and vents morphology of the ultramafic‐hosted Ashadze hydrothermal areas (Mid‐Atlantic Ridge 13°N)

Cited by 31 publications

References 81 publications

High‐resolution bathymetry reveals contrasting landslide activity shaping the walls of the Mid‐Atlantic Ridge axial valley

High‐resolution bathymetry reveals contrasting landslide activity shaping the walls of the Mid‐Atlantic Ridge axial valley

The Trans-Atlantic Geotraverse hydrothermal field: A hydrothermal system on an active detachment fault

Tectonic structure, lithology, and hydrothermal signature of the Rainbow massif (Mid-Atlantic Ridge 36°14′N)

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