Deep earthquakes in subducting slabs hosted in highly anisotropic rock fabric

Deep earthquakes in subducting slabs hosted in highly anisotropic rock fabric

Analysis of deep subduction-zone earthquakes, those at depths greater than 60 km, reveals the physical and chemical properties of a descending oceanic lithosphere at mantle depths. Over the past five decades, it has been observed that a large fraction of deep earthquakes has non-double-couple (non-D...

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Veröffentlicht in:Nature geoscience 2018-09, Vol.11 (9), p.696-700
Hauptverfasser: Li, Jiaxuan, Zheng, Yingcai, Thomsen, Leon, Lapen, Thomas J., Fang, Xinding
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704/2151
704/2151/508
Anisotropic rocks
Anisotropy
Chemical properties
Chemicophysical properties
Dehydration
Earth and Environmental Science
Earth Sciences
Earth System Sciences
Earthquakes
Geochemistry
Geology
Geophysics/Geodesy
Lithosphere
Magnesite
Magnesium carbonate
Metastable phases
Organic chemistry
Phase transitions
Radiation
Seismic activity
Shear
Slabs
Subduction
Subduction (geology)
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container_end_page 700
container_issue 9
container_start_page 696
container_title Nature geoscience
container_volume 11
creator Li, Jiaxuan
Zheng, Yingcai
Thomsen, Leon
Lapen, Thomas J.
Fang, Xinding
description Analysis of deep subduction-zone earthquakes, those at depths greater than 60 km, reveals the physical and chemical properties of a descending oceanic lithosphere at mantle depths. Over the past five decades, it has been observed that a large fraction of deep earthquakes has non-double-couple (non-DC) seismic radiation patterns. In contrast, shallow earthquakes tend to have DC radiation patterns due to mechanisms of shear faulting. These observations have been used to argue that deep earthquakes rupture differently from shallow earthquakes. Here we show that the observed global distribution of non-DC deep earthquakes could be caused by shear faulting mechanisms, but in a highly anisotropic laminated rock fabric that surrounds the deep earthquakes within subducted slabs. For intermediate-depth earthquakes (~60–300 km), we found a large shear-wave anisotropy of ~25%, possibly caused by laminated fabric or aligned melt pockets oriented parallel to the slab interface, which provides new supporting evidence for the metamorphic dehydration reactions in slabs. However, at deep-focus depths (>300 km), the putative metastable phase-change mechanism alone cannot explain the seismic anisotropy. Instead, our results and those from recent experiments suggest materials such as magnesite, or perhaps carbonatite melt, may play a role in generating deep-focus earthquakes. Radiation patterns for deep earthquakes could be a result of shear faulting mechanisms—similar to those for shallow earthquakes—but in highly anisotropic rock fabric, suggest seismic analyses.
doi_str_mv 10.1038/s41561-018-0188-3
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subjects 704/2151
704/2151/508
Anisotropic rocks
Anisotropy
Chemical properties
Chemicophysical properties
Dehydration
Earth and Environmental Science
Earth Sciences
Earth System Sciences
Earthquakes
Geochemistry
Geology
Geophysics/Geodesy
Lithosphere
Magnesite
Magnesium carbonate
Metastable phases
Organic chemistry
Phase transitions
Radiation
Seismic activity
Shear
Slabs
Subduction
Subduction (geology)
title Deep earthquakes in subducting slabs hosted in highly anisotropic rock fabric
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