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Confirmation of a change in the global shear velocity pattern at around 1000 km depth

Abstract : In this study, we confirm the existence of a change in the shear velocity spectrum around 1000 km depth based on a new shear velocity tomographic model of the Earth’s mantle, SEISGLOB2. This model is based on Rayleigh surface wave phase velocities, self- and crosscoupling structure coefficients of spheroidal normal modes and body wave traveltimes which are, for the first time, combined in a tomographic inversion. SEISGLOB2 is developed up to spherical harmonic degree 40 and in 21 radial spline functions. The spectrum of SEISGLOB2 is the flattest (i.e. richest in ‘short’ wavelengths corresponding to spherical harmonic degrees greater than 10) around 1000 km depth and this flattening occurs between 670 and 1500 km depth.We also confirmvarious changes in the continuity of slabs and mantle plumes all around 1000 km depth where we also observed the upper boundary of Large Low Shear Velocity Provinces. The existence of a flatter spectrum, richer in short-wavelength heterogeneities, in a region of the mid-mantle can have great impacts on our understanding of the mantle dynamics and should thus be better understood in the future. Although a viscosity increase, a phase change or a compositional change can all concur to induce this change of pattern, its precise origin is still very uncertain.
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https://hal.archives-ouvertes.fr/hal-01630025
Contributor : Christophe Zaroli Connect in order to contact the contributor
Submitted on : Sunday, October 17, 2021 - 11:25:20 AM
Last modification on : Tuesday, October 19, 2021 - 7:00:31 PM

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S. Durand, E Debayle, Y. Ricard, C. Zaroli, S. Lambotte. Confirmation of a change in the global shear velocity pattern at around 1000 km depth. Geophysical Journal International, Oxford University Press (OUP), 2017, 211 (3), pp.1628 - 1639. ⟨10.1093/gji/ggx405⟩. ⟨hal-01630025⟩

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