A. S. Moradi; M. Tatar; D. Hatzfeld; A. Paul
Abstract
The North Tabriz Fault (NTF) is an active fault which poses a high seismic hazard to the areas of NW Iran, especially the city of Tabriz with a population of 1.6 million. In order to determine the geometry and the kinematics of this fault system, a local dense seismological network including forthy 3-component ...
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The North Tabriz Fault (NTF) is an active fault which poses a high seismic hazard to the areas of NW Iran, especially the city of Tabriz with a population of 1.6 million. In order to determine the geometry and the kinematics of this fault system, a local dense seismological network including forthy 3-component stations was installed around the central segment of Tabriz Fault which crosses the northern part of the city of Tabriz. This network operated for 3 months. Using microearthquakes recorded by our temporary network in addition of more than 6 years of local events recorded by 8 permanent stations of Tabriz telemetry network, the 1-D crustal velocity of the region was determined. Our results indicates that the upper crust consists of a ~6 km thick sedimentary layer (VP = 5.23 km s-1) overlying a ~18 km thick upper crystalline crust (VP = 5.85 km s-1). We estimate a velocity of 6.54 km s-1 for the lower crystalline crust, but the limited focal depths of our local events did not allow determining the thickness of this layer. The well-located earthquakes indicate the seismic activity along the Tabriz fault. Precise examination of the focal depths on different cross sections indicates that the western and central segment of this fault system dip northeast ward while the eastern part shows almost southwest dipping plane. Calculated focal mechanism all indicate the right-lateral strike-slip motion of the Tabriz Fault. The most reliable fault plane solutions are consistent with cross sections showing evidence of extension in Eastern part comparing to compression observed in Western segment. Our focal mechanisms and geodetic studies using GPS measurements indicate that the North Tabriz Fault helps to northeast motion of trapped crust in this area.
A. H. Rajaee; M. Mokhtari; K. Priestley; D. Hatsfeld
Abstract
Using teleseismic body waves, this paper presents the crustal and lithospheric structure in the central part of the AlborzMountains for the first time. The region has been known as a very active and seismogenic locations in the past, characterized by strong earthquakes and complex structures. Tehran, ...
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Using teleseismic body waves, this paper presents the crustal and lithospheric structure in the central part of the AlborzMountains for the first time. The region has been known as a very active and seismogenic locations in the past, characterized by strong earthquakes and complex structures. Tehran, the capital of Iran, is located on the southern part of the region. The aim of this study is to determine Moho depth and its variation beneath the Central Alborz with high resolution and accuracy. The crustal structure of the Central Alborz beneath 26 broadband stations from a temporary dense seismological network was determined by using recorded data deployed for a period of 4-6 months. We first summarize an analysis of the teleseismic P-wave receiver function beneath each station. Next, we use joint inversion of receiver functions with surface wave dispersion data calculated for the center of network. Results of this research are shown as cross-sections through N-S azimuth of the profiles which passes across the AlborzMountains. Our study shows a thickening in the central part of the AlborzMountains crust down to 55 km relative to 48-50 km crustal thickness beneath northern part of the Central Iran. The crustal thickness is close to 44 km beneath the southern coast of the South Caspian Sea Block. These results are completely unlike with most of the other previous suggested crustal thickness. Based on our results, the AlborzMountains with a high average elevation can be considered with a crustal root.