Segmentation of plate coupling, fate of subduction fluids, and modes of arc magmatism in <scp>C</scp>ascadia, inferred from magnetotelluric resistivity

Wannamaker, Philip E.; Evans, Robert; Bedrosian, Paul A.; Unsworth, Martyn; Maris, Virginie; McGary, R. Shane

doi:10.1002/2014gc005509

Cited by 100 publications

(122 citation statements)

References 128 publications

(321 reference statements)

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“…Atg antigorite serpentinite, CPx clinopyroxene, OPx orthopyroxene, and Ol olivine. Olive symbols olivine aggregate and dark green symbols pyroxene-rich peridotite resolution of 2D electrical conductivity images has greatly improved (Wannamaker, et al 2014;Worzewski, et al 2011) with imaging of fluid paths that can be compared with seismic tomography. Typical values of conductivity range between 10 −3 and 10 −4 and 1 S.m 1 , the lower values being defined by the background sensitivity in cold and fluid-poor regions, and the highest observed in zones where fluids and melts are abundant.…”

Section: Magnetotelluricsmentioning

confidence: 99%

“…Magnetotellurics made great improvements in providing more accurate pictures of subduction zones from early studies that depicted rough limits between compartments of a few tens of kilometers to recent studies that give resolution of a few kilometers (Wannamaker, et al 2014;Worzewski, et al 2011). In the forearc region, the most prominent structures are high-conductivity zones that are located near the limit between the serpentinized mantle and the base of the overriding plate (Fig.…”

Section: Fluid Composition From Magnetotelluric Datamentioning

confidence: 99%

“…Further decrease in seismic velocity and variations of V P /V S ratio is expected if excess fluid pressure develops at depths (Peacock, et al 2011;Schubnel, et al 2006). If fluids are connected, this will also result in variations of electrical conductivity that can be mapped by magnetotelluric surveys in subduction zones (Baba, et al 2010;Wannamaker, et al 2014).…”

Section: Introductionmentioning

confidence: 99%

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Mantle hydration and Cl-rich fluids in the subduction forearc

Reynard

2016

Prog. in Earth and Planet. Sci.

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In the forearc region, aqueous fluids are released from the subducting slab at a rate depending on its thermal state. Escaping fluids tend to rise vertically unless they meet permeability barriers such as the deformed plate interface or the Moho of the overriding plate. Channeling of fluids along the plate interface and Moho may result in fluid overpressure in the oceanic crust, precipitation of quartz from fluids, and low Poisson ratio areas associated with tremors. Above the subducting plate, the forearc mantle wedge is the place of intense reactions between dehydration fluids from the subducting slab and ultramafic rocks leading to extensive serpentinization. The plate interface is mechanically decoupled, most likely in relation to serpentinization, thereby isolating the forearc mantle wedge from convection as a cold, potentially serpentinized and buoyant, body. Geophysical studies are unique probes to the interactions between fluids and rocks in the forearc mantle, and experimental constrains on rock properties allow inferring fluid migration and fluid-rock reactions from geophysical data. Seismic velocities reveal a high degree of serpentinization of the forearc mantle in hot subduction zones, and little serpentinization in the coldest subduction zones because the warmer the subduction zone, the higher the amount of water released by dehydration of hydrothermally altered oceanic lithosphere. Interpretation of seismic data from petrophysical constrain is limited by complex effects due to anisotropy that needs to be assessed both in the analysis and interpretation of seismic data. Electrical conductivity increases with increasing fluid content and temperature of the subduction. However, the forearc mantle of Northern Cascadia, the hottest subduction zone where extensive serpentinization was first demonstrated, shows only modest electrical conductivity. Electrical conductivity may vary not only with the thermal state of the subduction zone, but also with time for a given thermal state through variations of fluid salinity. High-Cl fluids produced by serpentinization can mix with the source rocks of the volcanic arc and explain geochemical signatures of primitive magma inclusions. Signature of deep high-Cl fluids was also identified in forearc hot springs. These observations suggest the existence of fluid circulations between the forearc mantle and the hot spring hydrothermal system or the volcanic arc. Such circulations are also evidenced by recent magnetotelluric profiles.

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Section: Magnetotelluricsmentioning

confidence: 99%

Section: Fluid Composition From Magnetotelluric Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Mantle hydration and Cl-rich fluids in the subduction forearc

Reynard

2016

Prog. in Earth and Planet. Sci.

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“…Kohl & Rybach 1996), the dynamics of electric resistivity, covering several orders of magnitudes compared to typical crustal rock, characterize mid-crustal conductors (e.g. Unsworth et al 2004;Hill et al 2009;Wannamaker et al 2014). The origin of these electric conductors has early been attributed to graphite (Frost et al 1989;Jödicke 1992).…”

Section: Introductionmentioning

confidence: 99%

“…The origin of these electric conductors has early been attributed to graphite (Frost et al 1989;Jödicke 1992). More recently, links to aqueous fluids and secondary minerals in fault zones (Korja et al 2008;Brasse et al 2009;Weckmann et al 2012), to partial melt (Unsworth et al 2005;Hill et al 2009), and to metamorphic processes (Wannamaker et al 2014;Zhang et al 2015) have been discussed. Worldwide, it is observed that these conductors have an upper depth limit near the brittle-ductile transition (Jones 1992;Jiracek 1995).…”

Section: Introductionmentioning

confidence: 99%

Resistivity distribution from mid-crustal conductor to near-surface across the 1200 km long Liquiñe-Ofqui Fault System, southern Chile

Schill

Pavez

Díaz

et al. 2016

Geophysical Journal International

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Structure of the mantle beneath the Alboran Basin from magnetotelluric soundings

García

Seillé

Elsenbeck

et al. 2015

Geochem Geophys Geosyst

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We present results of marine MT acquisition in the Alboran sea that also incorporates previously acquired land MT from southern Spain into our analysis. The marine data show complex MT response functions with strong distortion due to seafloor topography and the coastline, but inclusion of high resolution topography and bathymetry and a seismically defined sediment unit into a 3-D inversion model has allowed us to image the structure in the underlying mantle. The resulting resistivity model is broadly consistent with a geodynamic scenario that includes subduction of an eastward trending plate beneath Gibraltar, which plunges nearly vertically beneath the Alboran. Our model contains three primary features of interest: a resistive body beneath the central Alboran, which extends to a depth of $150 km. At this depth, the mantle resistivity decreases to values of $100 Ohm-m, slightly higher than those seen in typical asthenosphere at the same depth. This transition suggests a change in slab properties with depth, perhaps reflecting a change in the nature of the seafloor subducted in the past. Two conductive features in our model suggest the presence of fluids released by the subducting slab or a small amount of partial melt in the upper mantle (or both). Of these, the one in the center of the Alboran basin, in the uppermost-mantle (20-30 km depth) beneath Neogene volcanics and west of the termination of the Nekkor Fault, is consistent with geochemical models, which infer highly thinned lithosphere and shallow melting in order to explain the petrology of seafloor volcanics.

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Segmentation of plate coupling, fate of subduction fluids, and modes of arc magmatism in Cascadia, inferred from magnetotelluric resistivity

Cited by 100 publications

References 128 publications

Mantle hydration and Cl-rich fluids in the subduction forearc

Mantle hydration and Cl-rich fluids in the subduction forearc

Resistivity distribution from mid-crustal conductor to near-surface across the 1200 km long Liquiñe-Ofqui Fault System, southern Chile

Structure of the mantle beneath the Alboran Basin from magnetotelluric soundings

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