Seismic reflection images of the Moho underlying melt sills at the East Pacific Rise

Singh, S. C.; Harding, A. J.; Kent, G. M.; Sinha, M. C.; Combier, Violaine; Bazin, Sara; Tong, C. H.; Pye, J. W.; Barton, P. J.; Hobbs, R. W.; White, R. S.; Orcutt, John A.

doi:10.1038/nature04939

Cited by 67 publications

(75 citation statements)

References 30 publications

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“…In addition, though the illustration suggests the presence of a dacitic magma body overlying the sub-axial magma sill, the location of dacitic magma is not truly known. Detailed images and information on the seismically determined distribution and geometry of subsurface melt can be found in Kent et al (2000) and Singh et al (2006). model U-Th differentiation ages.…”

Section: Discussionmentioning

confidence: 99%

“…However, this melt "sill" is not clearly a continuous melt-rich region, but it is instead complex in 3-D geometry and distribution and may include a network of isolated melt-rich regions away from the melt accumulation underlying the axial graben (cf., Fig. 3d of Singh et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

“…The overlapping spreading center (OSC) at 9103′N EPR presents an ideal opportunity for studying the relationships between volcanism and magmatism because the subsurface melt distribution and seafloor morphology have recently been well-characterized in a number of geophysical and geological studies (e.g., Bazin et al,a low velocity anomaly interpreted as melt in the uppermost mantle extending across the OSC, with the lowest velocities centered beneath the eastern limb (Dunn et al, 2000;Toomey et al, 2007), melt accumulation in the overlying crust (Singh et al, 2006), and a mid-crustal mush zone at the northern end of the overlap basin at~9108′N (Bazin et al, 2003;Crawford and Webb, 2002). In addition, a 3-D seismic reflection study reveals a~4 km wide, upper-crustal melt sill beneath the eastern limb that extends westward into the northern portion of the overlap basin (Kent et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

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Sill to surface: Linking young off-axis volcanism with subsurface melt at the overlapping spreading center at 9°03′N East Pacific Rise

Waters

Sims

Klein

et al. 2013

Earth and Planetary Science Letters

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a b s t r a c tNo young, off-axis, mid-ocean ridge lavas have yet been directly linked to underlying off-axis melt bodies. In this study, we present new measurements of 238 U-230 Th-226 Ra-210 Pb isotope compositions for a suite of lavas from the overlapping spreading center (OSC) at 9103′N on the East Pacific Rise (EPR). These lavas span a large range of compositions, from basalt to dacite, and include both axial and off-axis samples recovered from a prominent, axis-parallel pillow ridge and a flat-topped seamount that overlie the westernmost extent of a 4-km-wide melt lens (Kent et al., 2000). We report 210 Pb excesses in axial basalts and basaltic andesites, which we suggest results from gas-magma fractionation of 222 Rn from 226 Ra beneath dacite magmas. In addition, our U-series ages agree with visual observations, indicating that while most recent volcanic activity occurs at the spreading axis, active volcanism also occurs away from the axis. Specifically, the off-axis pillow ridge and seamount samples overlying the off-axis subsurface melt body have eruption ages of less than 8 ka, and likely as young as 1 ka, despite being located on crust that has a spreading age of~75 ka. The young ages of these lavas, combined with existing geological, geochemical and geophysical constraints, provide evidence for a genetic link between the pillow ridge and seamount lavas and the seismically imaged, underlying off-axis melt lens. This link demonstrates that off-axis volcanism does not necessarily come from a sub-axial magma body and can be sourced directly from off-axis magma bodies.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sill to surface: Linking young off-axis volcanism with subsurface melt at the overlapping spreading center at 9°03′N East Pacific Rise

Waters

Sims

Klein

et al. 2013

Earth and Planetary Science Letters

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“…[2] A small melt lens has been imaged by multichannel seismic profiles in the late 1980s below fast spreading centers, extending <1 to 4 km on each side of the ridge axis and locally as thin as 30 m [e.g., Detrick et al, 1987;Harding et al, 1989;Collier and Singh, 1997;Singh et al, 1998Singh et al, , 2006Kent et al, 2000]. This discovery has raised the question of how this lens relates to the overlying sheeted dike complex, as previously described from oceanic drilling [e.g., Alt et al, 1993Alt et al, , 1996Bach et al, 2003] and in tectonic windows such as Hess Deep [Karson et al, 1992[Karson et al, , 2002b and fracture zones [e.g., Juteau et al, 1995;Karson et al, 2002a].…”

Section: Introductionmentioning

confidence: 99%

Root zone of the sheeted dike complex in the Oman ophiolite

Nicolas

Boudier

Koepke

et al. 2008

Geochem Geophys Geosyst

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[1] In the Oman ophiolite crustal section, a contact zone between the gabbro unit and the volcanics and diabase sheeted dikes, called the root zone of the sheeted dike complex, has been recently mapped at a fine scale in a selected area. The Oman ophiolite is derived from a fast spreading ridge which had a melt lens located between the main gabbro unit and the root zone of the sheeted dike complex. With a few exceptions accounted for, this horizon has a fairly constant thickness, $100 m, and a crude internal pseudo-stratigraphy. At the base of the root zone are isotropic ophitic gabbros interpreted as a thermal boundary layer. This layer is transitional between the magmatic system of the melt lens, convecting at 1200°C, and a high-temperature (<1100°C) hydrothermal system, convecting within the root zone. Above this level, the isotropic gabbros have been, locally, largely molten due to an influx of seawater, at $1100°C, thus generating varitextured ophitic and pegmatitic gabbros. These latter gabbros constitute the upper part of the root zone and are associated with trondjhemitic intrusions as screens in the lower sheeted dikes. Diorites and trondjhemites were also generated by hydrous melting, at temperatures below 1000°C. The whole root zone is a domain of very sharp average thermal gradient ($7°C/m). At the top of the root zone, a new thermal boundary layer, with diabase dikes hydrated in amphibolite facies conditions, separates the preceding high-temperature convective system from the well-known greenschist facies (<450°C) hydrothermal system operating throughout the sheeted dike complex, up to the seafloor. The isotropic gabbros near the base of the root zone are intruded by protodikes with distinctive microgranular margins and an ophitic center. Protodike swarms are exceptional because, intruding a medium at $1100°C, they are largely destroyed by dike-in-dike intrusions and by hydrous melting. However, they demonstrate that this zone was generated by melt conduits issued from the underlying melt lens. Each dike of the sheeted dike complex is thus fed by one protodike. As this zone has been recently drilled by IODP in the eastern Pacific Ocean, a brief comparison is proposed.

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“…In contrast to many large MOR discontinuities, the large overlapping spreading center (OSC) at 9º03'N East Pacific Rise (EPR), a 2 nd order discontinuity with an ~8 km offset and ~27 km of overlap, has been the subject of extensive tectonic and geophysical study Combier et al, 2008;Dunn et al, 2001;Sempere and Macdonald, 1984;1986a,b;Toomey et al, 2007;Tong et al, 2002;Singh et al, 2006;White et al, 2009), including the first detailed 3-D multi-channel seismic reflection survey of a MOR (Kent et al, 2000). However, only limited geochemical and petrologic work has been done to date and these studies (Langmuir et al, 1986;Natland and Melson, 1980;Natland et al, 1986a, b) indicate that this tectonic discontinuity delimits a significant magmatic discontinuity.…”

Section: Introductionmentioning

confidence: 99%

Temporal and petrogenetic constraints on volcanic accretionary processes at 9-10 degrees north East Pacific Rise

Waters¹

2010

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Volcanic accretion at the fast-spreading East Pacific Rise (EPR) occurs over a ~2-4 km wide neo-volcanic zone on either side of the axial summit trough (AST). Eruption ages are critical for understanding the distribution and timing of volcanic and magmatic activity. Uranium series nuclides are susceptible to fractionation by magmatic processes that occur beneath mid-ocean ridges, and the half-lives of

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Seismic reflection images of the Moho underlying melt sills at the East Pacific Rise

Cited by 67 publications

References 30 publications

Sill to surface: Linking young off-axis volcanism with subsurface melt at the overlapping spreading center at 9°03′N East Pacific Rise

Sill to surface: Linking young off-axis volcanism with subsurface melt at the overlapping spreading center at 9°03′N East Pacific Rise

Root zone of the sheeted dike complex in the Oman ophiolite

Temporal and petrogenetic constraints on volcanic accretionary processes at 9-10 degrees north East Pacific Rise

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