Your search keyword '"Vema fracture zone"' showing total 3 results

1. Serpentinization of mantle peridotites along an uplifted lithospheric section, Mid Atlantic Ridge at 11° N.

Author

Boschi, Chiara, Bonatti, Enrico, Ligi, Marco, Brunelli, Daniele, Cipriani, Anna, Dallai, Luigi, D'Orazio, Massimo, Früh-Green, Gretchen L., Tonarini, Sonia, Barnes, Jaime D., and Bedini, Rosa M.

Subjects

*SERPENTINITE, *REGOLITH, *PERIDOTITE, *LITHOSPHERE, *OCEAN bottom

Abstract

Abstract: Mantle peridotites from an exposed lithospheric section (Vema Lithospheric Section, VLS), generated during ~26Ma at a ~80km long Mid Atlantic Ridge segment (11° N), have been sampled and studied to understand the evolution of the serpentinization process. The VLS was uplifted due to a 10Ma transtensional event along the Vema transform. Before the uplift residual mantle rocks were lying beneath a 0.8–1.3km thick basaltic crustal layer. The major and trace element compositions of the serpentinites, as well as their H, O, Sr, Cl and B isotopic compositions were interpreted based on thermal models of lithospheric spreading from ridge axis. The results suggest that serpentinization occurred mostly near the ridge axis. Serpentinization temperatures, estimated from stable isotopes, are consistent with resetting of the closure temperatures during the tectonic uplift of the lithospheric sliver, reflected by decreasing δ18O and increasing δ11B values. Modeling shows that the thermal influence of the transtensional event affected mainly the region close to the RTI (ridge–transform intersection). Petrological, elemental and isotopic data suggest that, when the ultramafic basal unit of the VLS was uplifted and exposed on the ocean floor, serpentinization became superseded by low temperature water–rock reactions, with Fe–Mn crust formation, which is still progressing, as recorded by δD. Ultramafic mylonites, prevalent in a short stretch of the VLS, show only a partial serpentinization process, together with pervasive contamination by low-temperature Fe–Mn crust. [Copyright &y& Elsevier]

Published

2013

2. Flexural uplift of a lithospheric slab near the Vema transform (Central Atlantic): Timing and mechanisms

Author

Daniele Brunelli, W. Roger Buck, Marco Ligi, Luca Gasperini, Valentina Ferrante, P. Fabretti, Enrico Bonatti, and Anna Cipriani

Subjects

lithospheric flexure, geography, geography.geographical_feature_category, mid-ocean ridge, Mid Atlantic Ridge, Vema fracture zone, Mid-ocean ridge, Crust, Mid-Atlantic Ridge, flexural uplift, oceanic lithosphere, Seafloor spreading, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Lithosphere, Ridge, Earth and Planetary Sciences (miscellaneous), Lithospheric flexure, oceanic transform, Geology, Seismology, Sea level

Abstract

The Vema Transverse Ridge (VTR) is a prominent, long and narrow topographic anomaly that runs for over 300 km along a sea floor spreading flow line south of the Vema transform at 11° N in the Atlantic. It rises abruptly about 140 km from the axis of the Mid-Atlantic Ridge (MAR) in ∼10 Myr old crust and runs continuously up to ∼25 Myr old crust. It reaches over 3 km above the predicted lithospheric thermal contraction level. It is absent in crust younger than 10 Myr; thus, the uplift of the VTR must have ended roughly 10 Ma. The VTR is interpreted as the exposed edge of a flexured and uplifted slab of oceanic lithosphere that was generated at an 80 km long MAR segment. Based on satellite gravimetry imagery this MAR segment was born roughly 50 Ma and increased its length at an average rate of 1.6 mm/yr. Multibeam data show that the MAR-parallel sea floor fabric south of the VTR shifts its orientation by 5° to 10° clockwise in ∼11–12 Myr old crust, indicating a change at that time of the orientation of the MAR axis and of the position of the Euler rotation pole. This change caused extension normal to the transform, followed between 12 and 10 Ma by flexure of the edge of the lithospheric slab, uplift of the VTR at a rate of 2 to 4 mm/yr, and exposure of a lithospheric section (Vema Lithospheric Section or VLS) at the northern edge of the slab, parallel to the Vema transform. Ages of pelagic carbonates encrusting ultramafic rocks sampled at the base of the VLS at different distances from the MAR axis suggest that the entire VTR rose vertically as a single block within the active transform offset. A 50 km long portion of the crest of the VTR rose above sea level, subsided, was truncated at sea level and covered by a carbonate platform. Subaerial and submarine erosion has gradually removed material from the top of the VTR and has modified its slopes. Spreading half rate of the crust south of the transform decreased from 17.2 mm/yr between 26 and 19 Ma to ∼16.9 mm/yr between 19 and ∼10 Ma, to ∼13.6 mm/yr from 10 Ma to present. The slowing down of spreading occurred close in time to the change in ridge/transform geometry, suggesting that the two events are related. A numerical model relates lithospheric flexure to extension normal to the transform, suggesting that the extent of the uplift depends on the thickness of the brittle layer, consistent with the observed greater uplift of the older lithosphere along the VTR.

Published

2005

3. Discontinuous melt extraction and weak refertilization of mantle peridotites at the Vema Lithospheric Section (Mid Atlantic Ridge)

Author

Enrico Bonatti, Anna Cipriani, Daniele Brunelli, Luisa Ottolini, and Monique Seyler

Subjects

Provenance, refertilization, Rare-earth element, partial melting, Vema Fracture Zone, Partial melting, garnet, Mid Atlantic Ridge, Vema fracture zone, Fracture zone, Mid-Atlantic Ridge, Geophysics, Mantle (geology), abyssal peridotite, trace element, ABYSSAL PERIDOTITES, OCEANIC-CRUST, FRACTURE-ZONE, GEOCHEMICAL MORPHOLOGY, SUBOCEANIC MANTLE, MIDOCEAN RIDGE, SOUTH-ATLANTIC, TRACE-ELEMENTS, BASALT, CLINOPYROXENE, Geochemistry and Petrology, Lithosphere, Petrology, Porosity, Geology, mantle partial melting

Abstract

Melting processes beneath the Mid-Atlantic Ridge were studied in residual mantle peridotites sampled from a lithospheric section exposed near the Vema Fracture Zone at 11°N along the Mid-Atlantic Ridge. Fractional and dynamic melting models were tested based on clinopyroxene rare earth element and high field strength element data. Pure fractional melting (non-modal) cannot account for the observed trends, whereas dynamic melting with critical mass porosity

Published

2006