Topology of the postperovskite phase transition and mantle dynamics

Monnereau, M.; Yuen, David A.

doi:10.1073/pnas.0608480104

Cited by 23 publications

(13 citation statements)

References 37 publications

(45 reference statements)

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“…Because the Clapeyron slope for the deep mantle transition is about twice that of the upper mantle transition, the effect is enhanced, and convection models that include the postperovskite transition have quite unstable lower thermal boundary layers that tend to generate vigorous deep mantle flow (e.g., Cizkova et al, 2010;Kameyama and Yuen, 2006;Yuen, 2004, 2006;Monnereau and Yuen, 2007;Nakagawa and Tackley, 2004Tackley et al, 2007;Tosi et al, 2010;van den Berg et al, 2010;Yuen et al, 2007). Warmer regions of the boundary layer will have a thinner layer of dense postperovskite mineralogy, while colder regions of the boundary layer will have a thicker layer of the denser material.…”

Section: Phase Change In Perovskitementioning

confidence: 99%

Deep Earth Structure: Lower Mantle and D″

Lay

2015

Treatise on Geophysics

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Section: Phase Change In Perovskitementioning

confidence: 99%

Deep Earth Structure: Lower Mantle and D″

Lay

2015

Treatise on Geophysics

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“…At the present stage of the cooling history, the Pv‐pPv transition is expected to occur only in the lowest temperature regions within D ″. This could explain the characteristics of the observed shear velocity discontinuity, which are such that the high‐velocity lenses are found only in regions that are expected to be anomalously cold [e.g., Monnereau and Yuen , 2007, 2010]. The presence of a very low‐viscosity post‐perovskite lens or layer above the CMB would be expected to enhance the CMB heat flux in the cold slab regions and may cause deflection of the cold subducting material in D ″ [ Cizkova et al , 2010].…”

Section: The Perovskite‐postperovskite Transition: a New Contributionmentioning

confidence: 99%

“…Similarly, in anomalously warm regions adjacent to the CMB, the postperovskite phase is expected to be absent. For a CMB temperature greater than the intercept temperature, which is the temperature of the phase transition at CMB pressure, there is a “double crossing” of the phase boundary by the geotherms associated with the cold descending flow [ Hernlund et al , 2005; Monnereau and Yuen , 2007]. Employing the seismic images of the D ″ layer and double crossing depths, Monnereau and Yuen [2010] have attempted to put constraints on the CMB heat flux.…”

Section: The Perovskite‐postperovskite Transition: a New Contributionmentioning

confidence: 99%

Layered convection and the impacts of the perovskite‐postperovskite phase transition on mantle dynamics under isochemical conditions

Shahnas¹,

Peltier²

2010

J. Geophys. Res.

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[1] The issue of the style of the mantle convection process remains important to the understanding of Earth's deep interior and surface processes. While results from structural seismology may be interpreted to support the existence of a whole mantle convection regime, in several geographic regions high-resolution reconstructions of Benioff zone body wave heterogeneity demonstrate that the downgoing slab appears to be "trapped" in the transition zone rather than continuing to penetrate unimpeded into the lower mantle. The presence of the recently discovered exothermic perovskite-postperovskite (Pv-pPv) phase transition that appears to define the top of the D″ layer adjacent to the core-mantle boundary may be expected to exert considerable impact on the mixing process. On the basis of the use of the most recent mantle parameters derived on the basis of mineral physics and a viscosity model inferred from glacial isostatic adjustment and Earth rotation observables, we reinvestigate the impact of the Pv-pPv transition on mantle mixing. Our analyses are based on a newly constructed axisymmetric control volume model, which is described in detail. Analyses with this model demonstrate that the action of the Pv-pPv transitions slightly decreases the tendency to layered flow due to the endothermic transitions that occur at 660 km depth and enhances the absolute radial mass flux especially in the lower mantle. However, the results also demonstrate that the episodically layered style of mantle mixing persists in models in which the strength of the Pv-pPv transition is significant.

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“…The transformation of perovskite to post‐perovskite is now the favoured explanation for a discontinuity at the top of the D″ layer. Due to the large clapeyron slope of this phase change, the topography of the D″ discontinuity is expected to be quite large, of the order of a few hundred kilometres over scales that are related to the lateral variations of temperature in D″ (Monnereau & Yuen 2007). However, the P ‐wave velocity contrast of this phase transition at constant chemistry is small (Oganov & Ono 2004; Stackhouse et al 2006).…”

Section: Influence Of Discontinuities Topographymentioning

confidence: 99%

Statistical study of seismic heterogeneities at the base of the mantle from PKP differential traveltimes

Garcia

Chevrot

Calvet

2009

Geophysical Journal International

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S U M M A R YStochastic tomography can provide crucial information on the small-scale structures at the base of the mantle that are still beyond the reach of deterministic imaging. For this purpose, we relate differential traveltime variances of core phases to the correlation function of velocity heterogeneities at the base of the mantle. A global data set of PKP traveltimes is then used to invert for statistical properties of velocity perturbations in the D layer. We find that the average thickness of D is 350 ± 50 km with 1.2 ± 0.3 per cent rms velocity perturbations. The horizontal correlation length is 3 • ± 1 • and the vertical correlation length 150 ± 75 km. The statistical analysis of the traveltimes of core phases reveals a much stronger energy at short wavelengths compared to global tomographic models, which is in good agreement with the results of most studies of the seismic wavefield scattered at the base of the mantle, based upon the analysis of PKP precursors.

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Topology of the postperovskite phase transition and mantle dynamics

Cited by 23 publications

References 37 publications

Deep Earth Structure: Lower Mantle and D″

Deep Earth Structure: Lower Mantle and D″

Layered convection and the impacts of the perovskite‐postperovskite phase transition on mantle dynamics under isochemical conditions

Statistical study of seismic heterogeneities at the base of the mantle from PKP differential traveltimes

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