Seismic anisotropy and subduction-induced mantle fabrics beneath the Arabian and Nubian Plates adjacent to the Red Sea

Elsheikh, Ahmed; Gao, Stephen S.; Liu, Kelly H.; Mohamed, A. A.; Yu, Youqiang; Fat-Helbary, R. E.

doi:10.1002/2014gl059536

Cited by 19 publications

(17 citation statements)

References 40 publications

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“…The fast polarization direction of shear‐wave splitting measurements (the α axis of olivine) tends to be parallel to the direction of upper mantle flow or the preferred orientation of melt shape. Shear‐wave splitting measurements show a consistent north‐south orientation of the fast direction [ Wolfe et al ., ; Hansen et al ., ; Elsheikh et al ., ; S. Chen et al ., ]. This seismic anisotropy indicates that northward flow of the asthenosphere may cause the observed seismic anisotropy in the upper mantle beneath the shield, which is in agreement with the north‐south geometry of the LVZ.…”

Section: Discussionsupporting

confidence: 88%

“…However, the geometry of the LVZ, with a nearly N‐S direction, does not parallel the Red Sea or the NE relative plate motion. Shear‐wave splitting directions [ Wolfe et al ., ; Hansen et al ., ; Elsheikh et al ., ; B. Chen et al ., ] are parallel to the trend of the LVZ. The geometry of the LVZ and the parallel shear‐wave splitting direction clearly indicate that the passive upwelling of the asthenosphere along the axis of the Red Sea rift is not the primary active process.…”

Section: Discussioncontrasting

confidence: 56%

“…[] show that there are strong density variations within the lithosphere in the Arabian plate and a strong low‐density anomaly in upper mantle of the Arabian shield, which is in agreement with seismic velocity structure. The fast polarization direction of shear wave splitting for teleseismic SKS waves has a roughly north‐south orientation across the shield [ Wolfe et al ., ; Hansen et al ., ; Elsheikh et al ., ] indicating strong lattice preferred alignment due to north‐directed shearing deformation. Some studies also investigated the seismic structure beneath Cenozoic volcanic region and margin of the Arabian plate [e.g., Koulakov and Sobolev , ; Hansen et al ., ; Korostelev et al ., , ; Koulakov et al ., ] and find evidence for dike intrusions within the crust.…”

Section: Introductionmentioning

confidence: 97%

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Upper mantle velocity structure beneath the Arabian shield from Rayleigh surface wave tomography and its implications

Yao

Mooney

Zahran³

et al. 2017

JGR Solid Earth

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We measured phase velocities at 13 periods from 20 s to 143 s using Rayleigh wave data recorded at recently installed, dense (135) broadband seismic stations in the Arabian shield and determined the shear‐wave velocity structure. Our results clearly reveal a 300 km wide upper mantle seismic low‐velocity zone (LVZ) beneath the western Arabian shield at a depth of 60 km and with a thickness of 130 km. The LVZ has a north‐south trend and follows the late‐Cenozoic volcanic areas. The lithosphere beneath the western Arabian shield is remarkably thin (60–90 km). The 130 km thick mantle LVZ does not appear beneath the western Red Sea and the spreading axis. Thus, the Red Sea at 20°–26°N is an asymmetric rift, with thin lithosphere located east of the Red Sea axis, as predicted by the low‐angle detachment model for rift development. Passive rifting at the Red Sea and extensional stresses in the shield are probably driven by slab pull from the Zagros subduction zone. The low shear‐wave velocity (4.0–4.2 km/s) and the geometry of LVZ beneath the western shield indicate northward flow of hot asthenosphere from the Afar hot spot. The upwelling of basaltic melt in fractures or zones of localized lithospheric thinning has produced extensive late Cenozoic volcanism on the western edge of the shield, and the buoyant LVZ has caused pronounced topography uplift there. Thus, the evolution of the Red Sea and the Arabian shield is driven by subduction of the Arabian plate along its northeastern boundary.

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Section: Discussionsupporting

confidence: 88%

Section: Discussioncontrasting

confidence: 56%

Section: Introductionmentioning

confidence: 97%

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Upper mantle velocity structure beneath the Arabian shield from Rayleigh surface wave tomography and its implications

Yao

Mooney

Zahran³

et al. 2017

JGR Solid Earth

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“…Such a long term movement may produce preferred orientation of olivine in the lower lithosphere and the upper asthenosphere, leading to observable anisotropy. This mechanism has been used by Elsheikh et al (2014) to explain dominantly N-S fast orientations observed in Arabia and northern Africa.…”

Section: Formation Mechanisms Of the Observed Anisotropymentioning

confidence: 99%

Complex seismic anisotropy beneath western Tibet and its geodynamic implications

Zhang

Kong

et al. 2015

Earth and Planetary Science Letters

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“…Shear wave splitting measurements obtained adjacent to the Tanzania Craton, the Main Ethiopian Rift, and the Arabian Peninsula [ Bagley and Nyblade , ] are attributed to mantle flow modulated by northward advection of the African superplume which upwells through the mantle transition zone (MTZ) beneath the northern MRZ. However, shear wave splitting studies conducted throughout north central Africa and Saudi Arabia also demonstrate north‐south mantle flow patterns which are attributed to basal traction‐generated anisotropy from simple northward plate migration relative to the underlying asthenosphere [ Elsheikh et al , ; Lemnifi et al , ]. Similarly, shear wave splitting evidence from the Okavango rift zone (ORZ, Figure a) and southern Africa [ Silver et al , ; Yu et al , ] indicates that subcrustal mantle anisotropy can be explained by plate motion and lithospheric Archean structures and are not associated with a contemporary flow system related to the proposed African superplume.…”

Section: Introductionmentioning

confidence: 99%

Passive rifting of thick lithosphere in the southern East African Rift: Evidence from mantle transition zone discontinuity topography

Reed

Liu

Chindandali³

et al. 2016

JGR Solid Earth

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To investigate the mechanisms for the initiation and early‐stage evolution of the nonvolcanic southernmost segments of the East African Rift System (EARS), we installed and operated 35 broadband seismic stations across the Malawi and Luangwa rift zones over a 2 year period from mid‐2012 to mid‐2014. Stacking of over 1900 high‐quality receiver functions provides the first regional‐scale image of the 410 and 660 km seismic discontinuities bounding the mantle transition zone (MTZ) within the vicinity of the rift zones. When a 1‐D standard Earth model is used for time‐depth conversion, a normal MTZ thickness of 250 km is found beneath most of the study area. In addition, the apparent depths of both discontinuities are shallower than normal with a maximum apparent uplift of 20 km, suggesting widespread upper mantle high‐velocity anomalies. These findings suggest that it is unlikely for a low‐velocity province to reside within the upper mantle or MTZ beneath the nonvolcanic southern EARS. They also support the existence of relatively thick and strong lithosphere corresponding to the widest section of the Malawi rift zone, an observation that is consistent with strain localization models and fault polarity and geometry observations. We postulate that the Malawi rift is driven primarily by passive extension within the lithosphere attributed to the divergent rotation of the Rovuma microplate relative to the Nubian plate, and that contributions of thermal upwelling from the lower mantle are insignificant in the initiation and early‐stage development of rift zones in southern Africa.

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Seismic anisotropy and subduction-induced mantle fabrics beneath the Arabian and Nubian Plates adjacent to the Red Sea

Cited by 19 publications

References 40 publications

Upper mantle velocity structure beneath the Arabian shield from Rayleigh surface wave tomography and its implications

Upper mantle velocity structure beneath the Arabian shield from Rayleigh surface wave tomography and its implications

Complex seismic anisotropy beneath western Tibet and its geodynamic implications

Passive rifting of thick lithosphere in the southern East African Rift: Evidence from mantle transition zone discontinuity topography

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