Investigation of mantle kinematics beneath the Hellenic-subduction zone with teleseismic direct shear waves

Judith M. Confal*, Tuna Eken, Frederik Tilmann, Seda Yolsal-Çevikbilen, Yeşim Çubuk-Sabuncu, Erdinc Saygin, Tuncay Taymaz

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

20 Citations (Scopus)

Abstract

The subduction and roll-back of the African plate beneath the Eurasian plate along the arcuate Hellenic trench is the dominant geodynamic process in the Aegean and western Anatolia. Mantle flow and lithospheric kinematics in this region can potentially be understood better by mapping seismic anisotropy. This study uses direct shear-wave splitting measurements based on the Reference Station Technique in the southern Aegean Sea to reveal seismic anisotropy in the mantle. The technique overcomes possible contamination from source-side anisotropy on direct S-wave signals recorded at a station pair by maximizing the correlation between the seismic traces at reference and target stations after correcting the reference stations for known receiver-side anisotropy and the target stations for arbitrary splitting parameters probed via a grid search. We obtained splitting parameters at 35 stations with good-quality S-wave signals extracted from 81 teleseismic events. Employing direct S-waves enabled more stable and reliable splitting measurements than previously possible, based on sparse SKS data at temporary stations, with one to five events for local SKS studies, compared with an average of 12 events for each station in this study. The fast polarization directions mostly show NNE-SSW orientation with splitting time delays between 1.15 s and 1.62 s. Two stations in the west close to the Hellenic Trench and one in the east show N-S oriented fast polarizations. In the back-arc region three stations exhibit NE-SW orientation. The overall fast polarization variations tend to be similar to those obtained from previous SKS splitting studies in the region but indicate a more consistent pattern, most likely due to the usage of a larger number of individual observations in direct S-wave derived splitting measurements. Splitting analysis on direct shear waves typically resulted in larger split time delays compared to previous studies, possibly because S-waves travel along a longer path in the same anisotropic structure. Considering the S-derived splitting measurements of this study together with earlier SKS and Rayleigh wave anisotropy modelling results we suggest that the very consistent direct S-derived fast shear wave directions can be explained by the lattice-preferred orientation of olivine in the asthenospheric mantle due to mantle flow induced by the roll-back of the slab. It is possible that a small contribution originated in the lower crust beneath the study region where anisotropic fabric might have formed in response to extension in the Miocene.

Original languageEnglish
Pages (from-to)141-151
Number of pages11
JournalPhysics of the Earth and Planetary Interiors
Volume261
DOIs
Publication statusPublished - 1 Dec 2016

Bibliographical note

Publisher Copyright:
© 2016 Elsevier B.V.

Funding

This work was mainly conducted within the framework of 3501- Career Development Program (TÜBİTAK-ÇAYDAG-115Y248) supported by the Scientific and Technological Research Council of Turkey (TÜBİTAK). We further thank the Alexander-von–Humboldt foundation (AvH) and the Scientific Research Funding Program (İTÜ-BAP) of Istanbul Technical University for equipment subsidy. Tuncay Taymaz appreciates TÜBİTAK, AvH, and the Turkish Academy of Sciences (TÜBA) in the framework for Young Scientist Award Program (TÜBA-GEBİP) for the partial financial support. The manuscript was improved by a thoughtful and constructive review by an anonymous reviewer.

FundersFunder number
Alexander-von–Humboldt foundation
TÜBA
TÜBA-GEBİP
Türkiye Bilimsel ve Teknolojik Araştirma Kurumu
Türkiye Bilimler Akademisi
Istanbul Teknik Üniversitesi

    Keywords

    • Eastern Mediterranean
    • Kinematics of upper mantle deformation
    • Seismic anisotropy
    • Shear wave splitting
    • Subduction zone processes

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