Slab dehydration in warm subduction zones at depths of episodic slip and tremor

1991 ◽

Vol 335 (1638) ◽

pp. 377-392 ◽

Cited By ~ 157

Keyword(s):

Subduction Zones ◽

Mantle Wedge ◽

Chemical Fractionation ◽

Ocean Island Basalts ◽

Hydrous Melting ◽

Dehydration Processes ◽

Slab Dehydration ◽

Subduction Magmatism ◽

Element Flux ◽

Continental Growth

Subduction zones represent major sites of chemical fractionation within the Earth. Element pairs which behave coherently during normal mantle melting may become strongly decoupled from one another during the slab dehydration processes and during hydrous melting conditions in the slab and in the mantle wedge. This results in the large ion lithophile elements (e.g. K, Rb, Th, U, Ba) and the light rare earth elements being transferred from the slab to the mantle wedge, and being concentrated within the mantle wedge by hydrous fluids, stabilized in hydrous phases such as hornblende and phlogopite, from where they are eventually extracted as magmas and contribute to growth of the continental crust. High-field strength elements (e.g. Nb, Ta, Ti, P, Zr) are insoluble in hydrous fluids and relatively insoluble in hydrous melts, and remain in the subducted slab and the adjacent parts of the mantle which are dragged down and contribute to the source for ocean island basalts. The required element fractionations result from interaction between specific mineral phases (hornblende, phlogopite, rutile, sphene, etc.) and hydrous fluids. In present day subduction magmatism the mantle wedge contributes dominantly to the chemical budget, and there is a requirement for significant convection to maintain the element flux. In the Precambrian, melting of subducted ocean crust may have been easier, providing an enhanced slab contribution to continental growth.

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Overriding plate thinning in subduction zones: Localized convection induced by slab dehydration

Geochemistry Geophysics Geosystems ◽

10.1029/2005gc001061 ◽

2006 ◽

Vol 7 (2) ◽

pp. n/a-n/a ◽

Cited By ~ 45

Author(s):

D. Arcay ◽

M.-P. Doin ◽

E. Tric ◽

R. Bousquet ◽

C. de Capitani

Keyword(s):

Subduction Zones ◽

Slab Dehydration

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The thermal structure of subduction zones constrained by seismic imaging: Implications for slab dehydration and wedge flow

Earth and Planetary Science Letters ◽

10.1016/j.epsl.2005.11.055 ◽

2006 ◽

Vol 241 (3-4) ◽

pp. 387-397 ◽

Cited By ~ 167

Author(s):

Geoffrey A. Abers ◽

Peter E. van Keken ◽

Erik A. Kneller ◽

Aaron Ferris ◽

Joshua C. Stachnik

Keyword(s):

Subduction Zones ◽

Seismic Imaging ◽

Thermal Structure ◽

Wedge Flow ◽

Slab Dehydration

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Bromine speciation and partitioning in slab-derived fluids and melts: Implications for halogens recycling in subduction zones

10.5194/se-2019-205 ◽

2020 ◽

Author(s):

Marion Louvel ◽

Carmen Sanchez-Valle ◽

Wim J. Malfait ◽

Gleb S. Pokrovski ◽

Camelia N. Borca ◽

...

Keyword(s):

Supercritical Fluids ◽

Subduction Zones ◽

Silicate Melts ◽

Water Molecules ◽

Hydrous Silicate ◽

Gradual Evolution ◽

Diamond Anvil ◽

Na Ions ◽

Preferential Uptake ◽

Slab Dehydration

Abstract. Understanding the behavior of halogens (Cl, Br, and I) in subduction zones is critical to constrain the recycling of trace elements and metals, and to quantify the halogen fluxes to the atmosphere via volcanic degassing. Here, the partitioning of bromine between coexisting aqueous fluids and hydrous granitic melts and its speciation in slab-derived fluids have been investigated in situ up to 840 °C and 2.2 GPa by X-ray fluorescence (SXRF) and absorption (XANES and EXAFS) spectroscopy in hydrothermal diamond-anvil cells. The partition coefficients Df/mBr range from 15.3 ± 1.0 to 2.0 ± 0.1, indicating the preferential uptake of Br by aqueous fluids at all investigated conditions. EXAFS analysis further evidences a gradual evolution of Br speciation from hydrated Br ions [Br(H2O)6]− in slab dehydration fluids to more complex structures invoving both Na ions and water molecules, [BrNax(H2O)y], in hydrous silicate melts and supercritical fluids released at greather depth (> 200 km). In dense fluids containing 60 wt % dissolved alkali-silicates and in hydrous Na2Si2O5 melts (10 wt % H2O), Br is found in a salt-like structure involving 6 nearest Na ions and several next-nearest O neighbors that are either from water molecules or the tetrahedral silicate network. Bromine (and likely chlorine and iodine) complexation with alkalis is thus an efficient mechanism for the mobilization and transport of halogens by hydrous silicate melts and supercritical fluids, which can carry high amounts of Br, up to the 1000 ppm level. Overall, our results suggest that both shallow dehydration fluids and deeper silicate-bearing fluids efficiently remove halogens from the slab in the sub-arc region, thus controling an efficient recycling of halogens in subduction zones.

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Petrologic and geochemical role of serpentinite in subduction zones and plate interface domains

Rendiconti online della Società Geologica Italiana ◽

10.3301/rol.2015.177 ◽

2015 ◽

Vol 37 ◽

pp. 61-64

Author(s):

Marco Scambelluri ◽

Enrico Cannaò ◽

Mattia Gilio ◽

Marguerite Godard

Keyword(s):

Subduction Zones ◽

Plate Interface

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Diamonds from the Alps reveal carbon mobility in subduction zones

Rendiconti online della Società Geologica Italiana ◽

10.3301/rol.2015.168 ◽

2015 ◽

Vol 37 ◽

pp. 28-30

Author(s):

Maria Luce Frezzotti

Keyword(s):

Subduction Zones ◽

The Alps

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Evolution of Orogenic Plateaus at Subduction Zones - Sinking and raising the southern margin of the Central Anatolian Plateau

10.31237/osf.io/hf759 ◽

2018 ◽

Author(s):

David Fernández-Blanco

Keyword(s):

Tectonic Evolution ◽

Subduction Zones ◽

Inversion Tectonics ◽

High Discharge ◽

Anatolian Plateau ◽

Surface Uplift ◽

Southern Margin ◽

Wide Range ◽

Forearc Basins ◽

Orogenic Plateaus

Orogenic plateaus have raised abundant attention amongst geoscientists during the last decades, offering unique opportunities to better understand the relationships between tectonics and climate, and their expression on the Earth’s surface.Orogenic plateau margins are key areas for understanding the mechanisms behind plateau (de)formation. Plateau margins are transitional areas between domains with contrasting relief and characteristics; the roughly flat elevated plateau interior, often with internally drained endorheic basins, and the external steep areas, deeply incised by high-discharge rivers. This thesis uses a wide range of structural and tectonic approaches to investigate the evolution of the southern margin of the Central Anatolian Plateau (CAP), studying an area between the plateau interior and the Cyprus arc. Several findings are presented here that constrain the evolution, timing and possible causes behind the development of this area, and thus that of the CAP. After peneplanation of the regional orogeny, abroad regional subsidence took place in Miocene times in the absence of major extensional faults, which led to the formation of a large basin in the northeast Mediterranean. Late Tortonian and younger contractional structures developed in the interior of the plateau, in its margin and offshore, and forced the inversion tectonics that fragmented the early Miocene basin into the different present-day domains. The tectonic evolution of the southern margin of the CAP can be explained based on the initiation of subduction in south Cyprus and subsequent thermo-mechanical behavior of this subduction zone and the evolving rheology of the Anatolian plate. The Cyprus slab retreat and posterior pull drove subsidence first by relatively minor stretching of the crust and then by its flexure. The growth by accretion and thickening of the upper plate, and that of the associated forearc basins system, caused by accreting sediments, led to rheological changes at the base of the crust that allowed thermal weakening, viscous deformation, driving subsequent surface uplift and raising the modern Taurus Mountains. This mechanism could be responsible for the uplifted plateau-like areas seen in other accretionary margins. ISBN: 978-90-9028673-0

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