Ubiquitous lower-mantle anisotropy beneath subduction zones

Seismic anisotropy provides key information to map the trajectories of mantle flow and understand the evolution of our planet. While the presence of anisotropy in the uppermost mantle is well established, the existence and nature of anisotropy in the transition zone and uppermost lower mantle are st...

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Bibliographic Details
Published in:Nature geoscience 2019-04, Vol.12 (4), p.301-306
Main Authors: Ferreira, Ana M. G., Faccenda, Manuele, Sturgeon, William, Chang, Sung-Joon, Schardong, Lewis
Format: Article
Language:English
Subjects:
704/2151
704/2151/210
704/2151/508
Anisotropy
Anomalies
Deformation
Dislocation
Dislocations
Earth
Earth and Environmental Science
Earth mantle
Earth Sciences
Earth System Sciences
Evolution
Geochemistry
Geology
Geophysics/Geodesy
Lower mantle
Mantle
Mathematical models
Numerical models
Planetary evolution
Preferred orientation
Seismic tomography
Slabs
Solifluction
Subduction
Subduction (geology)
Subduction zones
Three dimensional models
Tomography
Transition zone
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Summary:Seismic anisotropy provides key information to map the trajectories of mantle flow and understand the evolution of our planet. While the presence of anisotropy in the uppermost mantle is well established, the existence and nature of anisotropy in the transition zone and uppermost lower mantle are still debated. Here we use three-dimensional global seismic tomography images based on a large dataset that is sensitive to this region to show the ubiquitous presence of anisotropy in the lower mantle beneath subduction zones. Whereas above the 660 km seismic discontinuity slabs are associated with fast SV anomalies up to about 3%, in the lower mantle fast SH anomalies of about 2% persist near slabs down to about 1,000–1,200 km. These observations are consistent with 3D numerical models of deformation from subducting slabs and the associated lattice-preferred orientation of bridgmanite produced in the dislocation creep regime in areas subjected to high stresses. This study provides evidence that dislocation creep may be active in the Earth’s lower mantle, providing new constraints on the debated nature of deformation in this key, but inaccessible, component of the deep Earth. Lower-mantle anisotropy is present beneath all subduction zones, indicating that dislocation creep is active in the lower mantle, according to analysis of 3D global seismic tomography images.
ISSN:1752-0894
1752-0908
DOI:10.1038/s41561-019-0325-7