Petrology‐based modeling of mantle melt electrical conductivity and joint interpretation of electromagnetic and seismic results

Pommier, Anne; Garnero, Edward J.

doi:10.1002/2013jb010449

Cited by 31 publications

(28 citation statements)

References 95 publications

(158 reference statements)

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“…There appears to be large volumes of melt beneath parts of Afar that extend well into the mantle (Desissa et al 2013). There is some discrepancy between the estimated melt volumes from magnetotelluric and seismic methods, but the effect of melt composition may explain some of this (Pommier & Garnero 2014). Linking seismic and electrical images of melt and their anisotropy is an ongoing challenge.…”

Section: Geophysical Signature Of Lithospheric Meltmentioning

confidence: 99%

Why is Africa rifting?

Kendall

Lithgow‐Bertelloni

2016

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Continental rifting has a fundamental role in the tectonic behaviour of the Earth, shaping the surface we live on. Although there is not yet a consensus about the dominant mechanism for rifting, there is a general agreement that the stresses required to rift the continental lithosphere are not readily available. Here we use a global finite element model of the lithosphere to calculate the stresses acting on Africa. We consider the stresses induced by mantle flow, crustal structure and topography in two types of models: one in which flow is exclusively driven by the subducting slabs and one in which it is derived from a shear wave tomographic model. The latter predicts much larger stresses and a more realistic dynamic topography. It is therefore clear that the mantle structure beneath Africa plays a key part in providing the radial and horizontal tractions, dynamic topography and gravitational potential energy necessary for rifting. Nevertheless, the total available stress (c. 100 MPa) is much less than that needed to break thick, cold continental lithosphere. Instead, we appeal to a model of magma-assisted rifting along pre-existing weaknesses, where the strain is localized in a narrow axial region and the strength of the plate is reduced significantly. Mounting geological and geophysical observations support such a model. Gold Open Access:This article is published under the terms of the CC-BY 3.0 license.

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Section: Geophysical Signature Of Lithospheric Meltmentioning

confidence: 99%

Why is Africa rifting?

Kendall

Lithgow‐Bertelloni

2016

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“…It depends weakly on the mineralogical composition, but it might (or not) be highly sensitive to hydrogen incorporated as a trace element in olivine (there is no consensus in the experimental data; cf., Poe et al, 2010;Yoshino and Katsura, 2013;Dai and Karato, 2014). Electrical conductivity also depends on oxygen fugacity (Duba et al, 1974) and on the presence and interconnectivity of minor, but highly conductive phases, like graphite, sulfides, or melts along grain boundaries (Ducea and Park, 2000;Jones et al, 2001;Wang et al, 2013a;Pommier and Garnero, 2014;Sifré et al, 2014). Joint seismic and magnetotelluric surveys may help discriminating between these effects, since the sensitivities of seismic and electrical properties to each parameter differ.…”

Section: Accepted Manuscriptmentioning

confidence: 99%

Heterogeneity and anisotropy in the lithospheric mantle

2015

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International audienceThe lithospheric mantle is intrinsically heterogeneous and anisotropic. These two properties govern the repartition of deformation, controlling intraplate strain localization and development of new plate boundaries. Geophysical and geological observations provide clues on the types, ranges, and characteristic length scales of heterogeneity and anisotropy in the lithospheric mantle. Seismic tomography points to variations in geothermal gradient and hence in rheological behavior at scales of hundreds of km. Seismic anisotropy data substantiate anisotropic physical properties consistent at scales of tens to hundreds of km. Receiver functions imply lateral and vertical heterogeneity at scales < 10 km, which might record gradients in composition or anisotropy. Observations on naturally deformed peridotites establish that compositional heterogeneity and Crystal Preferred Orientations (CPOs) are ubiquitous from the mm to the km scales. These data allow discussing the processes that produce/destroy heterogeneity and anisotropy and constraining the time scales over which they are active. This analysis highlights: (i) the role of deformation and reactive percolation of melts and fluids in producing compositional and structural heterogeneity and the feedbacks between these processes, (ii) the weak mechanical effect of mineralogical variations, and (iii) the low volumes of fine-grained microstructures and difficulty to preserve them. In contrast, olivine CPO and the resulting anisotropy of mechanical and thermal properties are only modified by deformation. Based on this analysis, we propose that strain localization at the plate scale is, at first order, controlled by large-scale variations in thermal structure and in CPO-induced anisotropy. In cold parts of the lithospheric mantle , grain size reduction may contribute to strain localization, but the low volume of fine-grained domains limits this effect

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“…The above studies indicate the effect of melt on conductivity is greater than previously thought when interpreting field results [Pommier and Garnero, 2014;Sifre et al, 2014]. This means that MT is in fact able to detect very small silicate melt fractions (typically on the order of 0.1-0.2 vol%) at the onset of melting where CO2 is concentrated in the melt.…”

Section: Mantle Conductivity: a Summarymentioning

confidence: 70%

“…Other effects on melt conductivity are Na content, which can increase conductivity at the incipient stages of melting [Pommier and Garnero, 2014] and CO2 content, which at the very early stages of melting can dramatically increase conductivity [Sifre et al, 2014]. The above studies indicate the effect of melt on conductivity is greater than previously thought when interpreting field results [Pommier and Garnero, 2014;Sifre et al, 2014].…”

Section: Mantle Conductivity: a Summarymentioning

confidence: 71%

Geophysical and petrological constraints on ocean plate dynamics

Sarafian¹

2017

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This thesis investigates the formation and subsequent motion of oceanic lithospheric plates through geophysical and petrological methods. Ocean crust and lithosphere forms at mid-ocean ridges as the underlying asthenosphere rises, melts, and flows away from the ridge axis. In Chapters 2 and 3, I present the results from partial melting experiments of mantle peridotite that were conducted in order to examine the mantle melting point, or solidus, beneath a mid-ocean ridge. Chapter 2 determines the peridotite solidus at a single pressure of 1.5 GPa and concludes that the oceanic mantle potential temperature must be ~60 ºC hotter than current estimates. Chapter 3 goes further to provide a more accurate parameterization of the anhydrous mantle solidus from experiments over a range of pressures. This chapter concludes that the range of potential temperatures of the mantle beneath mid-ocean ridges and plumes is smaller than currently estimated. Once formed, the oceanic plate moves atop the underlying asthenosphere away from the ridge axis. Chapter 4 uses seafloor magnetotelluric data to investigate the mechanism responsible for plate motion at the lithosphere-asthenosphere boundary. The resulting two dimensional conductivity model shows a simple layered structure. By applying petrological constraints, I conclude that the upper asthenosphere does not contain substantial melt, which suggests that either a thermal or hydration mechanism supports plate motion. Oceanic plate motion has dramatically changed the surface of the Earth over time, and evidence for ancient plate motion is obvious from detailed studies of the longer lived continental lithosphere. In Chapter 5, I investigate past plate motion by inverting magnetotelluric data collected over eastern Zambia. The conductivity model probes the Zambian lithosphere and reveals an ancient subduction zone previously suspected from surface studies. This chapter elucidates the complex lithospheric structure of eastern Zambia and the geometry of the tectonic elements in the region, which collided as a result of past oceanic plate motion. Combined, the chapters of this thesis provide critical constraints on ocean plate dynamics.

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Petrology‐based modeling of mantle melt electrical conductivity and joint interpretation of electromagnetic and seismic results

Cited by 31 publications

References 95 publications

Why is Africa rifting?

Why is Africa rifting?

Heterogeneity and anisotropy in the lithospheric mantle

Geophysical and petrological constraints on ocean plate dynamics

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