Long-lived mid-ocean ridge segmentation of the Pacific-Antarctic Ridge and the Southeast Indian Ridge

AbstractThe plate tectonic cycle produces chemically distinct mid-ocean ridge basalts and arc volcanics, with the latter enriched in elements such as Ba, Rb, Th, Sr and Pb and depleted in Nb owing to the water-rich flux from the subducted slab. Basalts from back-arc basins, with intermediate compositions, show that such a slab flux can be transported behind the volcanic front of the arc and incorporated into mantle flow. Hence it is puzzling why melts of subduction-modified mantle have rarely been recognized in mid-ocean ridge basalts. Here we report the first mid-ocean ridge basalt samples with distinct arc signatures, akin to back-arc basin basalts, from the Arctic Gakkel Ridge. A new high precision dataset for 576 Gakkel samples suggests a pervasive subduction influence in this region. This influence can also be identified in Atlantic and Indian mid-ocean ridge basalts but is nearly absent in Pacific mid-ocean ridge basalts. Such a hemispheric-scale upper mantle heterogeneity reflects subduction modification of the asthenospheric mantle which is incorporated into mantle flow, and whose geographical distribution is controlled dominantly by a “subduction shield” that has surrounded the Pacific Ocean for 180 Myr. Simple modeling suggests that a slab flux equivalent to ~13% of the output at arcs is incorporated into the convecting upper mantle.

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Melvicalathis, a new brachiopod genus (Terebratulida: Chlidonophoridae) fromdeep sea volcanic substrates, and the biogeographic significance of the mid-oceanridge system

Zootaxa ◽

10.11646/zootaxa.1866.1.6 ◽

2008 ◽

Vol 1866 (1) ◽

pp. 136 ◽

Cited By ~ 3

Author(s):

DAPHNE E. LEE ◽

MURRAY R. GREGORY ◽

CARSTEN LÜTER ◽

OLGA N. ZEZINA ◽

JEFFREY H. ROBINSON ◽

...

Keyword(s):

Deep Sea ◽

New Genus ◽

Significant Component ◽

Ocean Ridges ◽

Southeast Indian Ridge ◽

Mid Ocean Ridge ◽

History Of ◽

Cryptic Habitats ◽

Ocean Ridge ◽

Ridge System

Brachiopods form a small but significant component of the deep-sea benthos in all oceans. Almost half of the 40 brachiopod species so far described from depths greater than 2000 m are small, short-looped terebratulides assigned to two superfamilies, Terebratuloidea and Cancellothyridoidea. In this study we describe Melvicalathis, a new genus of cancellothyridoid brachiopod (Family Chlidonophoridae; Subfamily Eucalathinae) from ocean ridge localities in the south and southeast Pacific Ocean, and cryptic habitats within lava caves in glassy basalt dredged from the Southeast Indian Ridge, Indian Ocean. These small, punctate, strongly-ribbed, highly spiculate brachiopods occur at depths between 2009 m and 4900 m, and appear to be primary colonisers on the inhospitable volcanic rock substrate. The ecology and life-history of Melvicalathis and related deep-sea brachiopods are discussed. Brachiopods are rarely reported from the much-studied but localised hydrothermal vent faunas of the mid ocean ridge systems. They are, however, widespread members of a poorly known deep-sea benthos of attached, suspension-feeding epibionts that live along the rarely sampled basalt substrates associated with mid-ocean ridge systems. We suggest that these basalt rocks of the mid-ocean ridge system act as deep-sea “superhighways” for certain groups of deep-sea animals, including brachiopods, along which they may migrate and disperse. Although the mid-ocean ridges form the most extensive, continuous, essentially uniform habitat on Earth, their biogeographic significance may not have been fully appreciated.

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Influence of the Amsterdam/St. Paul hot spot along the Southeast Indian Ridge between 77° and 88°E: Correlations of Sr, Nd, Pb, and He isotopic variations with ridge segmentation

Geochemistry Geophysics Geosystems ◽

10.1029/2006gc001540 ◽

2007 ◽

Vol 8 (9) ◽

pp. n/a-n/a ◽

Cited By ~ 21

Author(s):

K. P. Nicolaysen ◽

F. A. Frey ◽

J. J. Mahoney ◽

K. T. M. Johnson ◽

D. W. Graham

Keyword(s):

Hot Spot ◽

Southeast Indian Ridge ◽

Ridge Segmentation ◽

Indian Ridge ◽

Isotopic Variations

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Southwestern limits of Indian Ocean Ridge Mantle and the origin of low206Pb/204Pb mid-ocean ridge basalt: Isotope systematics of the central Southwest Indian Ridge (17°–50°E)

Journal of Geophysical Research Atmospheres ◽

10.1029/92jb01424 ◽

1992 ◽

Vol 97 (B13) ◽

pp. 19771 ◽

Cited By ~ 202

Author(s):

J. Mahoney ◽

A. P. le Roex ◽

Z. Peng ◽

R. L. Fisher ◽

J. H. Natland

Keyword(s):

Indian Ocean ◽

Southwest Indian Ridge ◽

Ridge Basalt ◽

Mid Ocean Ridge ◽

Indian Ridge ◽

Ocean Ridge ◽

Isotope Systematics

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High water content in primitive mid-ocean ridge basalt from Southwest Indian Ridge (51.56ºE): Implications for recycled hydrous component in the mantle

Journal of Earth Science ◽

10.1007/s12583-017-0731-y ◽

2017 ◽

Vol 28 (3) ◽

pp. 411-421 ◽

Cited By ~ 4

Author(s):

Wei Li ◽

Zhenmin Jin ◽

Haiming Li ◽

Chunhui Tao

Keyword(s):

Water Content ◽

High Water ◽

Southwest Indian Ridge ◽

High Water Content ◽

Ridge Basalt ◽

Mid Ocean Ridge ◽

Indian Ridge ◽

Ocean Ridge

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Isotopic and trace element constraints on the genesis of a boninitic sequence in the Thetford Mines ophiolitic complex, Quebec, Canada

Canadian Journal of Earth Sciences ◽

10.1139/e17-100 ◽

1997 ◽

Vol 34 (9) ◽

pp. 1258-1271 ◽

Cited By ~ 9

Author(s):

Valérie Olive ◽

Réjean Hébert ◽

Michel Loubet

Keyword(s):

Trace Element ◽

Trace Element Composition ◽

Nd Isotope ◽

Geodynamic Environment ◽

The Pacific ◽

Geochemical Study ◽

Mid Ocean Ridge ◽

Isochron Diagram ◽

Component C ◽

Ocean Ridge

The Mont Ham Massif (part of the Thetford Mines ophiolite, south Quebec) represents a magmatic sequence made up of tholeiitic and boninitic derived products. A geochemical study confirms the multicomponent mixing models that have been classically advanced for the source of boninites, with slab-derived components added to the main refractory harzburgitic peridotite. An isochron diagram of the boninitic rocks is interpreted as a mixing trend between two components: (i) a light rare earth element (LREE) enriched component (A), interpreted as slab-derived fluid–melts equilibrated with sedimentary materials (εNd = −3, 147Sm/144Nd = 0.140), and (ii) a LREE-depleted component (B) (0.21 < 147Sm/144Nd < 0.23), interpreted as slab-derived fluid–melt equilibrated with recycled Iapetus oceanic crust and equated to the Nd-isotope characteristics of the Iapetus mantle (εNd = 9). A multicomponent source is also necessary to explain the Nd-isotope and trace element composition of the tholeiites, which are explained by the melting of a more fertile, lherzolitic mantle and (or) mid-ocean ridge basalt source (component C), characterized by a large-ion lithophile element depleted pattern and an Iapetus mantle Nd isotopic composition (εNd = 9), mixed in adequate proportions with the two previously infered slab-derived components (A and B). The genesis of the boninites of Mont Ham is not significantly different from those of boninites located in the Pacific. An intraoceanic subduction zone appears to be an appropriate geodynamic environment for the Mont Ham ophiolitic sequence.

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Trace Element and Isotopic Evidence for Recycled Lithosphere from Basalts from 48 to 53°E, Southwest Indian Ridge

Journal of Petrology ◽

10.1093/petrology/egaa068 ◽

2020 ◽

Author(s):

Jixin Wang ◽

Huaiyang Zhou ◽

Vincent J M Salters ◽

Henry J B Dick ◽

Jared J Standish ◽

...

Keyword(s):

Trace Element ◽

Southwest Indian Ridge ◽

Isotopic Compositions ◽

Depleted Mantle ◽

Bone Segment ◽

Mid Ocean Ridge ◽

Mantle Component ◽

Indian Ridge ◽

Basalt Glasses ◽

Ocean Ridge

Abstract Mantle source heterogeneity and magmatic processes have been widely studied beneath most parts of the Southwest Indian Ridge (SWIR). But less is known from the newly recovered mid-ocean ridge basalts from the Dragon Bone Amagmatic Segment (53°E, SWIR) and the adjacent magmatically robust Dragon Flag Segment. Fresh basalt glasses from the Dragon Bone Segment are clearly more enriched in isotopic composition than the adjacent Dragon Flag basalts, but the trace element ratios of the Dragon Flag basalts are more extreme compared with average mid-ocean ridge basalts (MORB) than the Dragon Bone basalts. Their geochemical differences can be explained only by source differences rather than by variations in degree of melting of a roughly similar source. The Dragon Flag basalts are influenced by an arc-like mantle component as evidenced by enrichment in fluid-mobile over fluid-immobile elements. However, the sub-ridge mantle at the Dragon Flag Segment is depleted in melt component compared with a normal MORB source owing to previous melting in the subarc. This fluid-metasomatized, subarc depleted mantle is entrained beneath the Dragon Flag Segment. In comparison, for the Dragon Bone axial basalts, their Pb isotopic compositions and their slight enrichment in Ba, Nb, Ta, K, La, Sr and Zr and depletion in Pb and Ti concentrations show resemblance to the Ejeda–Bekily dikes of Madagascar. Also, Dragon Bone Sr and Nd isotopic compositions together with the Ce/Pb, La/Nb and La/Th ratios can be modeled by mixing the most isotopically depleted Dragon Flag basalts with a composition within the range of the Ejeda–Bekily dikes. It is therefore proposed that the Dragon Bone axial basalts, similar to the Ejeda–Bekily dikes, are sourced from subcontinental lithospheric Archean mantle beneath Gondwana, pulled from beneath the Madagascar Plateau. The recycling of the residual subarc mantle and the subcontinental lithospheric mantle could be related to either the breakup of Gondwana or the formation and accretion of Neoproterozoic island arc terranes during the collapse of the Mozambique Ocean, and is now present beneath the ridge.

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The Mode of Trench-Parallel Subduction of the Middle Ocean Ridge

Frontiers in Earth Science ◽

10.3389/feart.2021.781117 ◽

2021 ◽

Vol 9 ◽

Author(s):

Xiaobing Shen ◽

Wei Leng

Keyword(s):

Evolutionary Process ◽

Pacific Plate ◽

North American Plate ◽

Plate Motion ◽

Western Boundary ◽

Ridge Subduction ◽

Ocean Ridges ◽

The Pacific ◽

Mid Ocean Ridge ◽

Ocean Ridge

Trench-parallel subduction of mid-ocean ridges occurs frequently in plate motion history, such as along the western boundary of the Pacific plate in the early Cenozoic and along the eastern boundary of the Pacific plate at present. Such subduction may strongly alter the surface topography, volcanic activity and slab morphology in the mantle, whereas few studies have been conducted to investigate its evolutionary process. Here, we construct a 2-D viscoelastoplastic numerical model to study the modes and key parameters controlling trench-parallel subduction of mid-ocean ridges. Our model results show that the subduction modes of mid-ocean ridges can be primarily categorized into three types: the fast spreading mode, the slow spreading mode, and the extinction mode. The key factor controlling these subduction modes is the relative motion between the foregoing and the following oceanic plates, which are separated by the mid-ocean ridge. Different subduction modes exert different surface geological expressions, which may explain specific evolutionary processes related to mid-ocean ridge subduction, such as topographic deformation and the eruption gap of volcanic rocks in East Asia within 55–45 Ma and in the western North American plate during the late Cenozoic.

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