Array Triplication Data Constraining Seismic Structure and Composition in the Mantle

Seismic data recorded in the upper mantle triplication distance range between 10° and 30° are generated by wave propagation through complex upper mantle structure. They can be used to place constraints on seismic velocity structures in the upper mantle, key seismic features near the major discontinu...

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Veröffentlicht in:	Surveys in geophysics 2009-10, Vol.30 (4-5), p.355-376
Hauptverfasser:	Wang, Yi, Wen, Lianxing, Weidner, Donald
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Schlagworte:	Anisotropy Arrays Astronomy Data analysis Earth and Environmental Science Earth Sciences Geophysics/Geodesy Observations and Techniques Original Paper Seismology Upper mantle Wave propagation
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creator	Wang, Yi Wen, Lianxing Weidner, Donald
description	Seismic data recorded in the upper mantle triplication distance range between 10° and 30° are generated by wave propagation through complex upper mantle structure. They can be used to place constraints on seismic velocity structures in the upper mantle, key seismic features near the major discontinuities, and anisotropic structure varying with depth. In this paper, we review wave propagation of the upper mantle triplicated phases, how different key seismic features can be studied using upper mantle triplicated data, and the importance of those seismic features to the understanding of mantle temperature and composition. We present two examples of using array triplicated phases to constrain upper mantle velocity structures and detailed features of a certain discontinuity, with one for a shallow event and the other for deep events. For the shallow event, we present examples of how the array triplication data can be used to constrain several key properties of the upper mantle: existence of a lithospheric lid, existence of a low velocity zone beneath the lithospheric lid, and P/S velocity ratio as a function of depth. For deep events, we show examples of how array triplication data can be used to constrain the detailed structures of a certain discontinuity: velocity gradients above and below the discontinuity, velocity jumps across the discontinuity and depth extents of different velocity gradients. We discuss challenges of the upper mantle triplication study, its connection to other approaches, and its potential for further studying some other important features of the mantle: the existence of double 660-km discontinuities, existence of low-velocity channels near major discontinuities and anisotropy varying with depth.
doi_str_mv	10.1007/s10712-009-9073-3
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For deep events, we show examples of how array triplication data can be used to constrain the detailed structures of a certain discontinuity: velocity gradients above and below the discontinuity, velocity jumps across the discontinuity and depth extents of different velocity gradients. 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subjects	Anisotropy Arrays Astronomy Data analysis Earth and Environmental Science Earth Sciences Geophysics/Geodesy Observations and Techniques Original Paper Seismology Upper mantle Wave propagation
title	Array Triplication Data Constraining Seismic Structure and Composition in the Mantle
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