TY - JOUR
T1 - Strength and elastic thickness variations in the Arabian Plat
T2 - A combination of temperature, composition and strain rates of the lithosphere
AU - Tesauro, M.
AU - Kaban, Mikhail K.
AU - Petrunin, A.G.
AU - El Khrepy, S.
AU - Al-Arifi, N.
N1 - Export Date: 15 December 2017
PY - 2018/10/30
Y1 - 2018/10/30
N2 - The Arabian Plate shows a strong asymmetry between its Shield and Platform, in terms of topography, seismic velocity and density structure of the upper mantle. This asymmetry also results in significant rheological differences between these blocks, as revealed by the effective elastic thickness (EET) estimates, obtained using a spectral gravity method. However, these estimates may be biased due to various factors. Therefore, other approaches based on a direct rheological modeling of the lithospheric structure should be employed to verify these results. In this study, we use a recent model of the lithosphere, based on an integrative interpretation of the gravity field and seismic tomography, to correct an initial thermal model obtained from the inversion of seismic velocity, assuming a uniform composition. The results are used together with the most recent crustal model of the Arabian Plate to construct two alternative models of strength and EET of the lithosphere. The first model (Model I) assumes a constant value of 10− 15 s− 1 for the strain rates. In the second model (Model II), we used the strain rates obtained from a global mantle flow model. Model I confirms the asymmetry in the rigidity of the Shield and Platform. In contrast, Model II shows that the influence of the variable strain rates causes a significant increase in the strength and EET of the central and eastern part of the Shield and in contrast to previous studies, reveals that most of the Arabian Plate is a long-term stable tectonic feature, predominantly characterized by large EET values (≥ 70 km).
AB - The Arabian Plate shows a strong asymmetry between its Shield and Platform, in terms of topography, seismic velocity and density structure of the upper mantle. This asymmetry also results in significant rheological differences between these blocks, as revealed by the effective elastic thickness (EET) estimates, obtained using a spectral gravity method. However, these estimates may be biased due to various factors. Therefore, other approaches based on a direct rheological modeling of the lithospheric structure should be employed to verify these results. In this study, we use a recent model of the lithosphere, based on an integrative interpretation of the gravity field and seismic tomography, to correct an initial thermal model obtained from the inversion of seismic velocity, assuming a uniform composition. The results are used together with the most recent crustal model of the Arabian Plate to construct two alternative models of strength and EET of the lithosphere. The first model (Model I) assumes a constant value of 10− 15 s− 1 for the strain rates. In the second model (Model II), we used the strain rates obtained from a global mantle flow model. Model I confirms the asymmetry in the rigidity of the Shield and Platform. In contrast, Model II shows that the influence of the variable strain rates causes a significant increase in the strength and EET of the central and eastern part of the Shield and in contrast to previous studies, reveals that most of the Arabian Plate is a long-term stable tectonic feature, predominantly characterized by large EET values (≥ 70 km).
KW - Arabian
KW - Plate
KW - Lithospheric structure
KW - Strain rate variations
KW - Strength and effective elastic thickness of the lithosphere
UR - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85015276643&doi=10.1016%2fj.tecto.2017.03.004&partnerID=40&md5=559a1e9893c26d4542c1a532694e15f9
U2 - 10.1016/j.tecto.2017.03.004
DO - 10.1016/j.tecto.2017.03.004
M3 - Article
SN - 0040-1951
VL - 746
SP - 398
EP - 411
JO - Tectonophysics
JF - Tectonophysics
ER -