Metastable olivine wedge in the subducting Pacific slab and its relation to deep earthquakes

Metastable olivine wedge in the subducting Pacific slab and its relation to deep earthquakes

► We applied a forward-modeling method to study the metastable olivine wedge (MOW). ► We used a modified double-difference method to relocate 78 deep earthquakes. ► The result shows that the MOW with a lower velocity does exist in the Pacific slab. ► The deep earthquakes occur within the MOW or alon...

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Bibliographic Details
Published in:Journal of Asian earth sciences Vol. 42; no. 6; pp. 1411 - 1423
Main Authors: Jiang, Guoming, Zhao, Dapeng
Format: Journal Article
Language:English
Published: Elsevier Ltd 11-11-2011
Subjects:
Deep earthquakes
Double-difference earthquake location
Forward modeling
Metastable olivine wedge
Pacific slab
Transformational faulting
Deep earthquakes
Double-difference earthquake location
Metastable olivine wedge
Pacific slab
Forward modeling
Transformational faulting
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Summary:► We applied a forward-modeling method to study the metastable olivine wedge (MOW). ► We used a modified double-difference method to relocate 78 deep earthquakes. ► The result shows that the MOW with a lower velocity does exist in the Pacific slab. ► The deep earthquakes occur within the MOW or along its edges within the slab. ► The transformational faulting may be the mechanism of deep earthquakes. A metastable olivine wedge (MOW) is detected in the subducting Pacific slab under the Japan Sea by applying a forward-modeling approach with 3-D ray tracing to high-quality arrival-time data from 78 well-located deep earthquakes. The data were recorded by the dense and high-quality seismic networks on the Japan Islands. The double-difference earthquake location technique is improved and used to relocate the 78 deep earthquakes precisely. Our results show that the MOW does exist in the Pacific slab and it has a P-wave velocity 3% lower than the normal mantle or 4% lower than the surrounding slab velocity. The top and bottom depths of the MOW are 400 and 570 km, respectively, and the MOW is located in the central portion of the slab. After precise relocation, all the 78 deep earthquakes are found to occur within the MOW or along its edges within the slab. The cut-off depth of deep seismicity under the Japan Sea is consistent with the estimated MOW bottom depth. Our results favor the transformational faulting as the mechanism of deep earthquakes in the Pacific slab under the Japan Sea.
ISSN:1367-9120
1878-5786
DOI:10.1016/j.jseaes.2011.08.005