Seismic anisotropy and mantle deformation in NW Iran through splitting measurements of SKS and direct S phases
- 1Institute for Advanced Studies in Basic Sciences (IASBS), Zanjan, Iran (sh.arvin@iasbs.ac.ir)
- 2University of Cambridge, Cambridge, UK
- 3Deutsches GeoForschungsZentrum (GFZ), Potsdam, Germany
- 4Department of Geophysical Engineering, Faculty of Mines, Istanbul Technical University, Turkey
The present tectonics of Iran has resulted from the continental convergence of the Arabian and Eurasian plates. Our study area, in NW Iran comprises a part of this collision zone and consists of an assemblage of distinct lithospheric blocks including the central Iranian Plateau, the South Caspian Basin, and the Talesh western Alborz Mountains. A proper knowledge of mantle flow field is required to bettwer constrain mantle kinematics in relation to the dynamics of continental deformation in NW Iran. To achieve this aim, we examined splitting of teleseismic shear waves (e.g. SKS and S) arriving with steep arrival angles beneath the receiver, which provide excellent lateral resolution in the upper mantle. We used data from 68 temporary broadband stations with varying operation periods (4 to 31 months) along 3 linear profiles. We perfomed splitting analyses on SK(K)S and direct S waves. Resultant splitting parameters obtained from both shear phases exhibit broad similarities. Relatively large time delays observed for direct S-waves, however, are anticipated since these waves travel longer than SKS along a non-vertical propagation path in an anisotropic layer. Overall, the fast polarization directions (FPDs) in the Alborz, Talesh, Tarom Mountain and in NW Iran indicate a strong consistency with NE-SW anisotropic orientations. Besides, we observe a good accordance between S and SKS results. A comparison of splitting parameters with the absolute plate motion (APM) vector and structural trends in Iran and eastern Turkey suggests asthenospheric flow field as the dominant source for observed seismic anisotropy. The lithospheric layer beneath these regions is relatively thin (compared to the adjacent Zagros region), explaining why it appears to only make a partial contribution to the observed anisotropy. The stations located in central Iran just southwest of the Alborz yield angular deviations from the general NE-SW trend as this may be explained by changing style of deformation across the different tectonic blocks. These stations indicate significant misfit between SK(K)S and direct S-waves that could be caused by local heterogeneities developed due to a diffuse boundary from the flow organization in the upper mantle of central Iran. Another possibility for large differences between two types of waves might be reflect the anisotropic structure of a remnant slab segment or a foundered lithospheric root beneath central Iran with a volume small enough to be detected by SKS phases, but not by the direct S waves.
How to cite: Arvin, S., Sobouti, F., Priestley, K., Ghods, A., Motaghi, S. K., Tilmann, F., and Eken, T.: Seismic anisotropy and mantle deformation in NW Iran through splitting measurements of SKS and direct S phases, EGU General Assembly 2020, Online, 4–8 May 2020, EGU2020-11368, https://doi.org/10.5194/egusphere-egu2020-11368, 2020.