Upper mantle Q structure beneath old seafloor in the western Pacific

The Pacific Lithosphere Anisotropy and Thickness Experiment ocean bottom seismometer array south of the Shatsky Rise allows imaging the attenuation structure of the upper mantle in the oldest parts of the Pacific Ocean. The array consisted of eight seismometers with a lateral extent of 200 km by 600...

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Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2014-04, Vol.119 (4), p.3448-3461
Main Authors: Booth, Catherine M., Forsyth, Donald W., Weeraratne, Dayanthie S.
Format: Article
Language:English
Subjects:
Anisotropy
Arrays
Attenuation
Depth
Earthquakes
Elastic waves
Geophysics
Least squares method
Lithosphere
Magma
Mantle
Ocean bottom
Ocean bottom seismometers
Ocean floor
Oceans
P waves
Pacific
Sea beds
Seismic activity
Seismic phenomena
Seismographs
Seismology
Seismometers
Spectra
Subduction
Subduction (geology)
Subduction zones
Transition zone
Travel time
Upper mantle
Wave attenuation
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Summary:The Pacific Lithosphere Anisotropy and Thickness Experiment ocean bottom seismometer array south of the Shatsky Rise allows imaging the attenuation structure of the upper mantle in the oldest parts of the Pacific Ocean. The array consisted of eight seismometers with a lateral extent of 200 km by 600 km. Intermediate‐ and deep‐focus earthquake sources in the Mariana and Izu‐Bonin subduction zones provide paths that probe different depths beneath the seafloor. Acceleration spectra from the vertical component of P waves are inverted for the attenuation operator and corner frequency. P n propagation indicates very high Q p values in the lithosphere, of order 1000, while path‐average Q p values in the upper mantle are on the order of 400. The variety of source epicentral distances and depths enables us to deduce the vertical Q p −1 structure of the upper mantle. Using the amplitude spectra directly in a weighted least squares problem that accounts for the effects of triplications in the traveltime curves, we invert for Q p −1 as a function of depth. We demonstrate that Q p is frequency dependent and adopt a power law dependence with coefficient α  = 0.27. We resolve three distinct layers using a reference frequency of 1 Hz with Q p on the order of 145 at depths 100–250 km, Q p on the order of 350 at depths 250–410 km, and very high Q p with attenuation indistinguishable from zero for depths below 410 km. The P waves have a component of scattering, and thus, Q p −1 represents the maximum intrinsic attenuation beneath normal undisturbed oceanic lithosphere. P wave path-average Q is about 400 in upper mantle beneath old Pacific seafloor There is a highly attenuating asthenosphere similar to back‐arc basins Attenuation in the mantle transition zone is very low
ISSN:2169-9313
2169-9356
DOI:10.1002/2013JB010589