Constraints on deformation conditions and the origin of oceanic detachments: The Mid‐Atlantic Ridge core complex at 15°45′N

Escartı́n, J.; Mével, Catherine; MacLeod, C. J.; McCaig, A. M.

doi:10.1029/2002gc000472

Cited by 251 publications

(311 citation statements)

References 71 publications

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“…Location of cored sites (RD2 and MeBo) overlain on multibeam bathymetry acquired during Expedition 357 (multibeam resolution = 50 m reoriented using borehole wall imagery demonstrate that the Atlantis Massif footwall has undergone a bulk tectonic rotation of at least 46° ± 6° around a ridge-parallel (011°-trending) axis, consistent with a "rolling hinge" flexural unloading model for the detachment fault system (Morris et al, 2009). Together, these results challenge the commonly held hypothesis that the bulk rheology of slow-spreading lithosphere is primarily controlled by cooling of a simple thermal structure and instead suggest that strain localization favored by lithologic contrasts and hydrous alteration are also important, as well as perhaps highly heterogeneous cooling around large hydrothermal systems (Boschi et al, 2006;Karson et al, 2006;Escartín et al, 2003;McCaig et al, 2010).…”

Section: Central Dome Of Atlantis Massifmentioning

confidence: 46%

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Früh-Green¹,

Orcutt²,

Green³

et al. 2017

Proceedings of the International Ocean Discovery Program

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Contents AbstractInternational Ocean Discovery Program (IODP) Expedition 357 successfully cored an east-west transect across the southern wall of Atlantis Massif on the western flank of the Mid-Atlantic Ridge (MAR) to study the links between serpentinization processes and microbial activity in the shallow subsurface of highly altered ultramafic and mafic sequences that have been uplifted to the seafloor along a major detachment fault zone. The primary goals of this expedition were to (1) examine the role of serpentinization in driving hydrothermal systems, sustaining microbial communities, and sequestering carbon; (2) characterize the tectonomagmatic processes that lead to lithospheric heterogeneities and detachment faulting; and (3) assess how abiotic and biotic processes change with variations in rock type and progressive exposure on the seafloor. To accomplish these objectives, we developed a coring and sampling strategy centered on the use of seabed drills-the first time that such systems have been used in the scientific ocean drilling programs. This technology was chosen in the hope of achieving high recovery of the carbonate cap sequences and intact contact and deformation relationships. The expedition plans also included several engineering developments to assess geochemical parameters during drilling; sample bottom water before, during, and after drilling; supply synthetic tracers during drilling for contamination assessment; acquire in situ electrical resistivity and magnetic susceptibility measurements for assessing fractures, fluid flow, and extent of serpentinization; and seal boreholes to provide opportunities for future experiments.Seventeen holes were drilled at nine sites across Atlantis Massif, with two sites on the eastern end of the southern wall (Sites M0068 and M0075), three sites in the central section of the southern wall north of the Lost City hydrothermal field (Sites M0069, M0072, and M0076), two sites on the western end (Sites M0071 and M0073), and two sites north of the southern wall in the direction of the central dome of the massif and Integrated Ocean Drilling Program Site U1309 (Sites M0070 and M0074). Use of seabed drills enabled collection of more than 57 m of core, with borehole penetration ranging from 1.30 to 16.44 meters below seafloor and core recoveries as high as 74.76% of total penetration. This high level of recovery of shallow mantle sequences is unprecedented in the history of ocean drilling. The cores recovered along the southern wall of Atlantis Massif have highly heterogeneous lithologies, types of alteration, and degrees of deformation. The ultramafic rocks are dominated by harzburgites with intervals of dunite and minor pyroxenite veins, as well as gabbroic rocks occurring as melt impregnations and veins, all of which provide information about early magmatic processes and the magmatic evolution in the southernmost portion of Atlantis Massif. Dolerite dikes and basaltic rocks represent the latest stage of magmatic activity. Overall, the ultramafic rocks recovered ...

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Section: Central Dome Of Atlantis Massifmentioning

confidence: 46%

Untitled

Früh-Green¹,

Orcutt²,

Green³

et al. 2017

Proceedings of the International Ocean Discovery Program

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“…The presence of serpentinite porphyroclasts whose veining structure is cut by fibrous tremolite shear zones requires that the shear zone formed after serpentinization of peridotite. These shear zones resemble metaperidotite ''fault schists'' described by Escartín et al [2003] from an oceanic detachment fault at 15°N on the Mid-Atlantic Ridge. Semibrittle shear zones consisting of intensely altered peridotite suggest strain localization via reaction softening processes.…”

Section: Amphibole-chlorite Schistmentioning

confidence: 99%

Strain localization on an oceanic detachment fault system, Atlantis Massif, 30°N, Mid‐Atlantic Ridge

Schroeder

John

2004

Geochem Geophys Geosyst

152

217

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[1] Microstructural observations, mineral chemistry, and the spatial distribution of deformation fabrics recorded in outcrop samples collected from Atlantis Massif, the active inside corner high at 30°N, MidAtlantic Ridge, suggest that strain is localized near the subhorizontal domal surface hypothesized to be an exposed detachment fault. Deformation textures in peridotite and gabbro indicate that high-temperature (>500°C) strain occurred via crystal-plastic flow and diffusive mass transfer. Low-temperature (<400°C) shear zones containing brittle and semibrittle microboudinage textures in which tremolite, chlorite, and/or talc replace fractured serpentine or hornblende cut earlier formed high-temperature deformation fabrics in peridotite. Textures indicate strain was localized by cataclasis and reaction softening into zones of intense greenschist and subgreenschist grade metamorphism. Gabbro is only weakly deformed below amphibolite facies (<500°C), indicating that strain was partitioned into altered peridotite at low temperature. There is a clear relationship between deformation intensity and structural depth beneath the subhorizontal surface of the Massif. Discontinuous high-intensity crystal-plastic deformation fabrics are found at all structural depths (0-520 m) beneath the surface, indicating that high-temperature, granulite-and amphibolite-grade deformation was not localized in a single shear zone. In contrast, semibrittle and brittle low-temperature shear zones are concentrated less than 90 m structurally beneath the surface, and the most intensely brittlely deformed samples concentrated in the upper 10 m. Localization of brittle deformation fabrics near the upper surface of the massif supports the hypothesis that it is the exposed footwall of a detachment fault. The structural evolution of Atlantis Massif is therefore analogous to a continental metamorphic core complex. Strain was localized onto the fault by reaction-softening and fluid-assisted fracturing during greenschist-and subgreenschist-grade hydrothermal alteration of olivine, clinopyroxene, serpentine, and hornblende to tremolite, chlorite, and/or talc.

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“…The footwall composition is debated, with models and evidence ranging from extensive serpentinite bodies, to mainly gabbro bodies capped by serpentinized rocks. The fault zone appears to be thin, possibly on the order of tens of meters or less [Escartín et al, 2003;Schroeder and John, 2004;Karson et al, 2006], and shows variable composition and degree of alteration (from talc schists to deformed mafic and ultramafic rocks). Some OCC models predict extensive serpentinite bodies while others suggest that serpentinites are essentially restricted to the fault that uplifts the gabbro footwall [Ildefonse et al, 2007].…”

Section: Introductionmentioning

confidence: 99%

“…[3] Competing models of OCC formation and evolution have been proposed, including the creation of low angle detachment faults [e.g., Cannat et al, 1997;Escartín et al, 2003;Buck et al, 2005;Tucholke et al, 2008]. In general, OCCs are thought to form when the reduction in magma supply crosses a threshold that triggers detachment formation.…”

Section: Introductionmentioning

confidence: 99%

A short electromagnetic profile across the Kane Oceanic Core Complex

Evans

Escartı́n

Cannat

2010

Geophysical Research Letters

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A short seafloor electromagnetic profile across part of the Kane Oceanic Core Complex shows a large variation in seafloor electrical properties (uppermost 30m) with a sharp transition from conductive to resistive seafloor over a distance of less than 350m. The transition is in a location consistent with a sharp, but deeper, lateral gradient in seismic velocity, inferred to mark a transition from serpentinized peridotite to either gabbro or pristine mantle rocks, and is close to a mapped outcrop of serpentinized peridotites. We relate this variability in shallow structure primarily to changes in porosity related to composition.

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Constraints on deformation conditions and the origin of oceanic detachments: The Mid‐Atlantic Ridge core complex at 15°45′N

Cited by 251 publications

References 71 publications

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Strain localization on an oceanic detachment fault system, Atlantis Massif, 30°N, Mid‐Atlantic Ridge

A short electromagnetic profile across the Kane Oceanic Core Complex

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