P-wave tomography of the mantle beneath the South Pacific Superswell revealed by joint ocean floor and islands broadband seismic experiments

Three-dimensional P-wave velocity structure of the mantle beneath the South Pacific Superswell is determined through passive broadband seismic experiments on the ocean floor and islands between 2003 and 2005. We collected approximately 1500 relative times of long-period teleseismic P-waves by using...

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Bibliographic Details
Published in:Physics of the earth and planetary interiors 2009-02, Vol.172 (3), p.268-277
Main Authors: Tanaka, S., Obayashi, M., Suetsugu, D., Shiobara, H., Sugioka, H., Yoshimitsu, J., Kanazawa, T., Fukao, Y., Barruol, G.
Format: Article
Language:English
Subjects:
Broadband ocean bottom seismograph (BBOBS)
Earth Sciences
French Polynesia
Geophysics
Marine
P-wave tomography
Physics
PLUME project
Sciences of the Universe
South Pacific Superswell
Tectonics
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Summary:Three-dimensional P-wave velocity structure of the mantle beneath the South Pacific Superswell is determined through passive broadband seismic experiments on the ocean floor and islands between 2003 and 2005. We collected approximately 1500 relative times of long-period teleseismic P-waves by using a waveform cross-correlation. We analyzed this data set with relative time tomography to depths of 2000 km. The resultant structure shows lateral heterogeneity of approximately ±2%, in which a distinct low velocity region is found beneath the center of the Superswell at a depth of 1600 km. At 1200 km depth, an elongated low velocity region is found beneath the Society to Pitcairn hotspots. At 800 km depth, two linear low velocity regions are located beneath Tuamotu and Austral islands. Isolated low velocity regions are identified beneath the Society, Marquesas, and Macdonald hotspots at 400 km depth. Our new tomographic images reveal that the large low velocity region rooted in the deep lower mantle is split into two sheets at 1200 km depth and these terminate at approximately 800 km depth. This feature appears to be consistent with the characteristics of a thermo-chemical pile or dome.
ISSN:0031-9201
1872-7395
0031-9201
DOI:10.1016/j.pepi.2008.10.016