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  • Subduction  (4)
  • -; 355-U1457A; 355-U1457B; 355-U1457C; AGE; Arabian Sea; clay; Clay minerals; DEPTH, sediment/rock; Diameter; DRILL; Drilling/drill rig; DSDP/ODP/IODP sample designation; erosion; Event label; Exp355; Expedition 355; ICP-OES; Joides Resolution; Laser diffraction particle size analyser (Malvern Mastersizer 2000); Mode, grain size; neodymium (Nd); physical fractionation; Sample code/label; Sand; Silt; Site U1456; Site U1457; Size fraction 〈 0.020 µm; Size fraction 〉 2 mm, gravel; Size fraction 0.02-0.2 µm; Size fraction 0.20-0.24 µm; Size fraction 0.24-0.28 µm; Size fraction 0.28-0.32 µm; Size fraction 0.32-0.36 µm; Size fraction 0.36-0.42 µm; Size fraction 0.42-0.48 µm; Size fraction 0.48-0.55 µm; Size fraction 0.55-0.63 µm; Size fraction 0.63-0.72 µm; Size fraction 0.72-0.83 µm; Size fraction 0.83-0.96 µm; Size fraction 0.96-1.1 µm; Size fraction 1.10-1.26 µm; Size fraction 1.26-1.45 µm; Size fraction 1.45-1.66 µm; Size fraction 1.66-1.91 µm; Size fraction 1.91-2.19 µm; Size fraction 10.00-11.48 µm; Size fraction 104.71-120.23 µm; Size fraction 1096.48-1258.93 µm; Size fraction 11.48-13.18 µm; Size fraction 120.23-138.04 µm; Size fraction 1258.93-1445.44 µm; Size fraction 13.18-15.14 µm; Size fraction 138.04-158.49 µm; Size fraction 1445.44-1659.59 µm; Size fraction 15.14-17.38 µm; Size fraction 158.49-181.97 µm; Size fraction 1659.59-1905.46 µm; Size fraction 17.38-19.95 µm; Size fraction 181.97-208.93 µm; Size fraction 19.95-22.91 µm; Size fraction 1905.46-2000 µm; Size fraction 2.19-2.51 µm; Size fraction 2.51-2.88 µm; Size fraction 2.88-3.31 µm; Size fraction 208.93-239.88 µm; Size fraction 22.91-26.3 µm; Size fraction 239.88-275.42 µm; Size fraction 26.30-30.2 µm; Size fraction 275.42-316.23 µm; Size fraction 3.31-3.8 µm; Size fraction 3.80-4.37 µm; Size fraction 30.20-34.67 µm; Size fraction 316.23-363.08 µm; Size fraction 34.67-39.81 µm; Size fraction 363.08-416.87 µm; Size fraction 39.81-45.71 µm; Size fraction 4.37-5.01 µm; Size fraction 416.87-478.63 µm; Size fraction 45.71-52.48 µm; Size fraction 478.63-549.54 µm; Size fraction 5.01-5.75 µm; Size fraction 5.75-6.61 µm; Size fraction 52.48-60.26 µm; Size fraction 549.54-630.96 µm; Size fraction 6.61-7.59 µm; Size fraction 60.26-69.18 µm; Size fraction 630.96-724.44 µm; Size fraction 69.18-79.43 µm; Size fraction 7.59-8.71 µm; Size fraction 724.44-831.76 µm; Size fraction 79.43-91.2 µm; Size fraction 8.71-10 µm; Size fraction 831.76-954.99 µm; Size fraction 91.20-104.71 µm; Size fraction 954.99-1096.48 µm; Standard deviation; Strontium (Sr)  (1)
  • 117-720A; 117-731A; 117-731C; 23-224; Arabian Sea; Deep Sea Drilling Project; DRILL; Drilling/drill rig; DSDP; Glomar Challenger; Indian Ocean/Arabian Sea/RIDGE; Joides Resolution; Leg117; Leg23; Ocean Drilling Program; ODP  (1)
Collection
Keywords
Publisher
Years
  • 1
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    Grain size analysis from different Holes of IODP Sites 355-U1457 (2020)
    PANGAEA
    Details
    Publication Date: 2023-07-03
    Keywords: -; 355-U1457A; 355-U1457B; 355-U1457C; AGE; Arabian Sea; clay; Clay minerals; DEPTH, sediment/rock; Diameter; DRILL; Drilling/drill rig; DSDP/ODP/IODP sample designation; erosion; Event label; Exp355; Expedition 355; ICP-OES; Joides Resolution; Laser diffraction particle size analyser (Malvern Mastersizer 2000); Mode, grain size; neodymium (Nd); physical fractionation; Sample code/label; Sand; Silt; Site U1456; Site U1457; Size fraction 〈 0.020 µm; Size fraction 〉 2 mm, gravel; Size fraction 0.02-0.2 µm; Size fraction 0.20-0.24 µm; Size fraction 0.24-0.28 µm; Size fraction 0.28-0.32 µm; Size fraction 0.32-0.36 µm; Size fraction 0.36-0.42 µm; Size fraction 0.42-0.48 µm; Size fraction 0.48-0.55 µm; Size fraction 0.55-0.63 µm; Size fraction 0.63-0.72 µm; Size fraction 0.72-0.83 µm; Size fraction 0.83-0.96 µm; Size fraction 0.96-1.1 µm; Size fraction 1.10-1.26 µm; Size fraction 1.26-1.45 µm; Size fraction 1.45-1.66 µm; Size fraction 1.66-1.91 µm; Size fraction 1.91-2.19 µm; Size fraction 10.00-11.48 µm; Size fraction 104.71-120.23 µm; Size fraction 1096.48-1258.93 µm; Size fraction 11.48-13.18 µm; Size fraction 120.23-138.04 µm; Size fraction 1258.93-1445.44 µm; Size fraction 13.18-15.14 µm; Size fraction 138.04-158.49 µm; Size fraction 1445.44-1659.59 µm; Size fraction 15.14-17.38 µm; Size fraction 158.49-181.97 µm; Size fraction 1659.59-1905.46 µm; Size fraction 17.38-19.95 µm; Size fraction 181.97-208.93 µm; Size fraction 19.95-22.91 µm; Size fraction 1905.46-2000 µm; Size fraction 2.19-2.51 µm; Size fraction 2.51-2.88 µm; Size fraction 2.88-3.31 µm; Size fraction 208.93-239.88 µm; Size fraction 22.91-26.3 µm; Size fraction 239.88-275.42 µm; Size fraction 26.30-30.2 µm; Size fraction 275.42-316.23 µm; Size fraction 3.31-3.8 µm; Size fraction 3.80-4.37 µm; Size fraction 30.20-34.67 µm; Size fraction 316.23-363.08 µm; Size fraction 34.67-39.81 µm; Size fraction 363.08-416.87 µm; Size fraction 39.81-45.71 µm; Size fraction 4.37-5.01 µm; Size fraction 416.87-478.63 µm; Size fraction 45.71-52.48 µm; Size fraction 478.63-549.54 µm; Size fraction 5.01-5.75 µm; Size fraction 5.75-6.61 µm; Size fraction 52.48-60.26 µm; Size fraction 549.54-630.96 µm; Size fraction 6.61-7.59 µm; Size fraction 60.26-69.18 µm; Size fraction 630.96-724.44 µm; Size fraction 69.18-79.43 µm; Size fraction 7.59-8.71 µm; Size fraction 724.44-831.76 µm; Size fraction 79.43-91.2 µm; Size fraction 8.71-10 µm; Size fraction 831.76-954.99 µm; Size fraction 91.20-104.71 µm; Size fraction 954.99-1096.48 µm; Standard deviation; Strontium (Sr)
    Type: Dataset
    Format: text/tab-separated-values, 6308 data points
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  • 2
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    Nd and Pb isotope data for DSDP and ODP sediments from the Bengal Fan (2001)
    PANGAEA
    In:  Supplement to: Clift, Peter D; Shimizu, Nobumichi; Layne, Graham D; Blusztajn, Jerzy S; Gaedicke, Christoph; Schlüter, Hans-Ulrich; Clark, M K; Amjad, Shahid (2001): Development of the Indus Fan and its significance for the erosional history of the Western Himalaya and Karakoram. Geological Society of America Bulletin, 113(8), 1039-1051, https://doi.org/10.1130/0016-7606(2001)113%3C1039:DOTIFA%3E2.0.CO;2
    Details
    Publication Date: 2024-03-02
    Description: Correlation of new multichannel seismic profiles across the upper Indus Fan and Murray Ridge with a dated industrial well on the Pakistan shelf demonstrates that ~40% of the Indus Fan predates the middle Miocene, and ~35% predates uplift of the Murray Ridge (early Miocene, ~22 Ma). The Arabian Sea, in addition to the Makran accretionary complex, was therefore an important repository of sediment from the Indus River system during the Paleogene. Channel and levee complexes are most pronounced after the early Miocene, coincident with an increase in sedimentation rates. Middle Eocene sandstones from Deep Sea Drilling Project Site 224 on the Owen Ridge yield K-feldspars whose Pb isotopic composition, measured by in situ ion microprobe methods, indicates an origin in, or north of, the Indus suture zone. This observation requires that India-Asia collision had occurred by this time and that an Indus River system, feeding material from the suture zone into the basin, was active soon after collision. Pleistocene provenance was similar to that during the Eocene, albeit with greater contribution from the Karakoram. A mass balance of the erosional record on land with deposition in the fan and associated basins suggests that only ~40% of the Neogene sediment in the fan is derived from the Indian plate.
    Keywords: 117-720A; 117-731A; 117-731C; 23-224; Arabian Sea; Deep Sea Drilling Project; DRILL; Drilling/drill rig; DSDP; Glomar Challenger; Indian Ocean/Arabian Sea/RIDGE; Joides Resolution; Leg117; Leg23; Ocean Drilling Program; ODP
    Type: Dataset
    Format: application/zip, 2 datasets
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  • 3
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    Origin and significance of the Delaney Dome Formation, Connemara, Ireland (2005)
    Geological Society of London
    Details
    Publication Date: 2022-05-25
    Description: Author Posting. © Geological Society of London, 2002. This article is posted here by permission of Geological Society of London for personal use, not for redistribution. The definitive version was published in Journal of the Geological Society 159 (2002): 95-103, doi: 10.1144/0016-764901034
    Description: Dalradian meta-sediments of the Laurentian margin and mafic intrusions thereof in SW Connemara, Ireland, tectonically overlie meta-rhyolites of the Delaney Dome Formation. The two units are separated by the Mannin Thrust. A new U–Pb age of 474.6 ± 5.5 Ma shows that the Delaney Dome Formation is a temporal equivalent of arc volcanic rocks preserved in the adjacent South Mayo Trough: the Tourmakeady Volcanic Group, erupted during the collision of an oceanic island arc with the Laurentian margin in the Grampian Orogeny. New rare earth and high field strength element data show that the Delaney Dome Formation and Tourmakeady Volcanic Group are chemically similar and arc-like in character. This suggests that the Delaney Dome Formation is an along-strike equivalent of the Tourmakeady Group, strike-slip faulted south of the South Mayo Trough during or after the Grampian Orogeny. Further correlation of these units with northern Appalachian rhyolites is also possible. The Delaney Dome Formation is an extrusive temporal equivalent of intrusions that penetrate the Connemara Dalradian. Thus, movement along the Mannin Thrust brought mid-crustal plutons and Dalradian country rocks tectonically above the extrusive volcanic sequence. The Mannin Thrust is identified as a major imbricating structure within a continental arc, but not a terrane boundary.
    Keywords: Ireland ; Grampian Orogeny ; U–Pb ; Geochemistry ; Subduction ; Plate collision
    Repository Name: Woods Hole Open Access Server
    Type: Article
    Format: 889535 bytes
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  • 4
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    Pulsed subduction accretion and tectonic erosion reconstructed since 2.5 Ma from the tephra record offshore Costa Rica (2006)
    American Geophysical Union
    Details
    Publication Date: 2022-05-25
    Description: Author Posting. © American Geophysical Union, 2005. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Geochemistry Geophysics Geosystems 6 (2005): Q09016, doi:10.1029/2005GC000963.
    Description: Tephra layers recovered by Ocean Drilling Program from the forearc and trench regions offshore the Nicoya Peninsula of Costa Rica allow the temporal evolution of the volcanic arc to be reconstructed since 2.5 Ma. Major and trace element analyses by microprobe methods reveal a dominant tholeiitic character and a provenance in the Costa Rican area. The tephra show long-term coherent variability in geochemistry. One tephra dated at 1.45 Ma shows minimum values in ɛ Nd and maximum Li/Y consistent with very high degrees of sediment recycling at this time. However, overall Li/Y and δ7Li increase with SiO2 content, suggesting addition of heavy Li through forearc tectonic erosion and crustal assimilation. Peak values in δ7Li starting at 1.45 Ma and lasting ∼0.5 m.y. indicate enhanced tectonic erosion of the forearc possibly caused by subduction of a seamount at 1.45 Ma. The tephra record indicates significant temporal variability in terms of sediment subduction, reconciling the geologic evidence for long-term tectonic erosion and geochemical evidence for recent sediment accretion in the modern Central American arc.
    Description: Financial support for the analytical work was gratefully received from JOI-USSAC. The lithium isotope work was supported in part by National Science Foundation grant OCE-990554 to L.H.C.
    Keywords: Costa Rica ; Subduction ; Geochemistry ; Tephra
    Repository Name: Woods Hole Open Access Server
    Type: Article
    Format: 1261051 bytes
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  • 5
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    Controls on tectonic accretion versus erosion in subduction zones : implications for the origin and recycling of the continental crust (2010)
    American Geophysical Union
    Details
    Publication Date: 2022-05-25
    Description: Author Posting. © American Geophysical Union, 2004. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Reviews of Geophysics 42 (2004): RG2001, doi:10.1029/2003RG000127.
    Description: Documenting the mass flux through convergent plate margins is important to the understanding of petrogenesis in arc settings and to the origin of the continental crust, since subduction zones are the only major routes by which material extracted from the mantle can be returned to great depths within the Earth. Despite their significance, there has been a tendency to view subduction zones as areas of net crustal growth. Convergent plate margins are divided into those showing long-term landward retreat of the trench and those dominated by accretion of sediments from the subducting plate. Tectonic erosion is favored in regions where convergence rates exceed 6 ± 0.1 cm yr−1 and where the sedimentary cover is 〈1 km. Accretion preferentially occurs in regions of slow convergence (〈7.6 cm yr−1) and/or trench sediment thicknesses 〉1 km. Large volumes of continental crust are subducted at both erosive and accretionary margins. Average magmatic productivity of arcs must exceed 90 km3 m.y.−1 if the volume of the continental crust is to be maintained. Convergence rate rather than height of the melting column under the arc appears to be the primary control on long-term melt production. Oceanic arcs will not be stable if crustal thicknesses exceed 36 km or trench retreat rates are 〉6 km m.y.−1. Continental arcs undergoing erosion are major sinks of continental crust. This loss requires that oceanic arcs be accreted to the continental margins if the net volume of crust is to be maintained.
    Description: This material is partly based upon work supported by the National Science Foundation (Ocean Sciences) under grant 9907137.
    Keywords: Tectonics ; Subduction ; Magmatism
    Repository Name: Woods Hole Open Access Server
    Type: Article
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  • 6
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    Arc–continent collision and the formation of continental crust : a new geochemical and isotopic record from the Ordovician Tyrone Igneous Complex, Ireland (2009)
    Details
    Publication Date: 2022-05-26
    Description: Author Posting. © Geological Society of London, 2009. This is the author's version of the work. It is posted here by permission of Geological Society of London for personal use, not for redistribution. The definitive version was published in Journal of the Geological Society 166 (2009): 485-500, doi:10.1144/0016-76492008-102.
    Description: Collisions between oceanic island-arc terranes and passive continental margins are thought to have been important in the formation of continental crust throughout much of Earth’s history. Magmatic evolution during this stage of the plate-tectonic cycle is evident in several areas of the Ordovician Grampian-Taconic Orogen, as we demonstrate in the first detailed geochemical study of the Tyrone Igneous Complex, Ireland. New U–Pb zircon dating yields ages of 493 ± 2 Ma from a primitive mafic intrusion, indicating intra-oceanic subduction in Tremadoc time, and 475 ± 10 Ma from a light-rare-earth-element (LREE)-enriched tonalite intrusion that incorporated Laurentian continental material by early Arenig time (Early Ordovician, Stage 2) during arc-continent collision. Notably, LREE enrichment in volcanism and silicic intrusions of the Tyrone Igneous Complex exceeds that of average Dalradian (Laurentian) continental material which would have been thrust under the colliding forearc and potentially recycled into arc magmatism. This implies that crystal fractionation, in addition to magmatic mixing and assimilation, was important to the formation of new crust in the Grampian-Taconic Orogeny. Because similar super-enrichment of orogenic melts occurred elsewhere in the Caledonides in the British Isles and Newfoundland, the addition of new, highly enriched melt to this accreted arc terrane was apparently widespread spatially and temporally. Such super-enrichment of magmatism, especially if accompanied by loss of corresponding lower crustal residues, supports the theory that arc-continent collision plays an important role in altering bulk crustal composition toward typical values for ancient continental crust.
    Description: This work was supported by the University of Aberdeen. LA-MC-ICPMS dating was conducted at the Arizona LaserChron Center with the assistance of George Gehrels and Victor Valencia and was supported by NSF-EAR 0443387.
    Keywords: Subduction ; Continental crust ; Arc-continent collision ; Caledonides, Ireland
    Repository Name: Woods Hole Open Access Server
    Type: Preprint
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