Title of article
Seismic Velocity and Q Structure of the Middle Eastern Crust and Upper Mantle from Surface-wave Dispersion and Attenuation
Author/Authors
L. Cong ، نويسنده , , B. J. Mitchell ، نويسنده ,
Issue Information
ماهنامه با شماره پیاپی سال 1998
Pages
36
From page
503
To page
538
Abstract
Observed velocities and attenuation of fundamental-mode Rayleigh waves in the period
range 7–82 sec were inverted for shear-wave velocity and shear-wave Q structure in the Middle East
using a two-station method. Additional information on Q structure variation within each region was
obtained by studying amplitude spectra of fundamental-mode and higher-mode Rayleigh waves. We
obtained models for the Turkish and Iranian Plateaus (Region 1), areas surrounding and including the
Black and Caspian Seas (Region 2), and the Arabian Peninsula (Region 3). The effect of continent-ocean
boundaries and mixed paths in Region 2 may lead to unrealistic features in the models obtained there.
At lower crustal and upper-mantle depths, shear velocities are similar in all three regions. Shear
velocities vary significantly in the uppermost 10 km of the crust, being 3.21, 2.85, and 3.39 km:s for
Regions 1, 2, and 3, respectively. Q models obtained from an inversion of interstation attenuation data
show that crustal shear-wave Q is highest in Region 3 and lowest in Region 1. Q’s for the upper 10 km
of the crust are 63, 71, and 201 for Regions 1, 2, and 3, respectively. Crustal Q’s at 30 km depth for the
three regions are about 51, 71, and 134. The lower crustal Q values contrast sharply with results from
stable continental regions where shear-wave Q may reach one thousand or more. These low values may
indicate that fluids reside in faults, cracks, and permeable rock at lower crustal, as well as upper crustal
depths due to convergence and intense deformation at all depths in the Middle Eastern crust.
Keywords
surface waves , Attenuation , Q , Middle East.
Journal title
Pure and Applied Geophysics
Serial Year
1998
Journal title
Pure and Applied Geophysics
Record number
429077
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