1999
DOI: 10.1126/science.286.5440.752
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Asymmetric Electrical Structure in the Mantle Beneath the East Pacific Rise at 17°S

Abstract: The magnetotelluric component of the Mantle Electromagnetic and Tomography (MELT) Experiment measured the electrical resistivity structure of the mantle beneath the fast-spreading southern East Pacific Rise (EPR). The data reveal an asymmetric resistivity structure, with lower resistivity to the west of the ridge. The uppermost 100 kilometers of mantle immediately to the east of the ridge is consistent with a dry olivine resistivity structure indicating a mantle depleted of melt and volatiles. Mantle resistivi… Show more

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Cited by 125 publications
(127 citation statements)
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“…Their results exhibited a broad region of anomalously slow velocities, centered to the west of the ridge axis, that they attribute to the presence of partial melt. A similar pattern of asymmetry was observed with teleseismic body wave tomography [Toomey et al, 1998;Hammond and Toomey, 2003], shear wave splitting [Wolfe and Solomon, 1998], and a magnetotelluric survey [Evans et al, 1999]. Dunn and Forsyth [2003] used short-period Love waves to probe S wave velocity to a depth of ∼50 km for up to ∼100 km on each side of the axis and found strong cross-ridge asymmetry in the slow anomaly.…”
Section: Introductionsupporting
confidence: 65%
“…Their results exhibited a broad region of anomalously slow velocities, centered to the west of the ridge axis, that they attribute to the presence of partial melt. A similar pattern of asymmetry was observed with teleseismic body wave tomography [Toomey et al, 1998;Hammond and Toomey, 2003], shear wave splitting [Wolfe and Solomon, 1998], and a magnetotelluric survey [Evans et al, 1999]. Dunn and Forsyth [2003] used short-period Love waves to probe S wave velocity to a depth of ∼50 km for up to ∼100 km on each side of the axis and found strong cross-ridge asymmetry in the slow anomaly.…”
Section: Introductionsupporting
confidence: 65%
“…For example, melt segregation and magma focusing beneath midocean ridges is an important magmatic process that may critically depend on carbonate melt migration. A fundamental geophysical observation of the mantle beneath mid-ocean ridges is that a low degree of melt is distributed over a broad region 42,43 . In addition, geochemical models of melting beneath mid-ocean ridges based on radioactive isotope disequilibrium predict that melt segregates from the matrix at very low porosities on the order of 0.1% and rises B100 km in 1,600-8,000 years (melt ascent velocity of 410 m per year) (refs 44,45).…”
Section: Article Nature Communications | Doi: 101038/ncomms6091mentioning
confidence: 99%
“…Third, seismic velocity anomalies extend to greater depth and change more rapidly with distance from the East Pacific Rise axis than expected if simple conductive cooling from above is the primary control on structure (Dunn and Forsyth, 2003;Forsyth, 1977;Hammond and Toomey, 2003). Finally, the presence of pronounced Earth and Planetary Science Letters 278 (2009) [96][97][98][99][100][101][102][103][104][105][106] asymmetries across spreading centers (Evans et al, 1999;Forsyth et al, 1998;Key and Constable, 2008;Toomey et al, 2007) suggests that flow in the mantle is more complex than is assumed in the simple models. As pointed out by many of these authors and others, the presence of water and/or melt in the asthenosphere and a dehydrated lithosphere following extraction of melt are probably necessary to explain the pattern of velocity and conductivity anomalies.…”
Section: Introductionmentioning
confidence: 99%