جستجوی مقالات مرتبط با کلیدواژه « ساختار سرعتی پوسته » در نشریات گروه « زمین شناسی »

Northeastern part of Iran islocated in the Kopeh Dagh seismotectonic province. This province is part of the Alpine-Himalayan orogenic belt. In the last two decades, a number of earthquakes occurred in this region. Therefore, investigating and relocating these earthquakes with adequate precise play a great role in seismicity research of the study area. Adequate crustal structure velocity has a key role in relocating the earthquakes. Since the earthquakes in this region are shallow earthquakes, the upper part of crustal structure can be acquired. So in this study, Mashhad and Quchan seismological networks data were used to determine the crustal structure velocity. In order to determine the velocity structure, Vp/Vs was first determined using the methods of Wadati and travel time of1.72 .Then by applying various filters and selection of several earthquakes 1D velocity structure of the arrival times was determined. Results reveal two velocity discontinuities approximately at 4 and 14 km depths. The resulting model consists of a 4-km-thick layer with VP = 5.9 kms−1 overlying a 10-km-thick layer with VP = 6.17 kms−1. Then the initial 1D velocity model was used to determine the three-dimensional velocity structure using LOTOS code. The results show significant changes in the vicinity of Mashhad. Two zones with higher velocity are observed in the north and south of Mashhad due to Kashaf Roud and Binaloud Faults. In the north of Mashhad, a change in velocity is observed, which might be due to the Tous fault. In the south of Mashhad, a sharp velocity discontinuity at the depth of 4 km is probably due to an alluvium cover above a bedrock of varying thickness. Also, the tomography results indicate that the area of Shandiz fault system in the south of Mashhad is associated with a lower velocity zone compared to its adjacent areas.

Summary: In this study we used seismic data available from the permanent stations in the NW Iran to study seismic activities and crustal structure beneath the Tabriz region. The region of study is situated in the seismically active NW tectonic province of Iran، where detailed seismic information on the crustal structure and seismicity is lacking. The availability of seismic data collected since 1996 by Tabriz permanent short-period seismological network provided us with an unprecedented opportunity to study the seismicity and crustal seismic structure of this region. Our seismic data consisted of waveforms of local events collected by Tabriz seismological network operated by the Institute of Geophysics of Tehran University (IGTU) and two broad-band permanent seismic stations from the Iranian National Seismic Network operated by the International Institute of Earthquake Engineering and Seismology (IIEES). We manually picked the P and S arrival times on all collected waveforms. The events were initially located using a 1-D model used by the Tabriz network for routine daily event location. Of a total number of 728 events of local magnitudes greater than 2 recorded between 1996 and 2006 by the seismic stations، 361events of azimuthal gaps of less than 180 degrees and time residual of less than 1. 0 second were selected for the subsequent analyses. We then simultaneously inverted the arrival times of the local events for one dimensional velocity-depth models and event relocation. By considering the nonuniqueness of the inversion process، we inverted the data using a sufficient number of initial models. Finally، the models showing consistency with each other were selected. Some standard tests were performed to make sure that the final models were in agreement with the observed data. These tests revealed that the results of inversion were stable. The final best 1-D model is a 5-layer model to a depth of 35 km. Since we used local shallow events recorded at a small-aperture local network، the models are not valid for the depths deeper than 35 km. The final 1-D model gave P and S velocities smaller than the global average values for the orogens. This was because the study area was an active orogenic belt. On the other hand، the Vp/Vs ratio (which was found to be equal to 1. 745 using the Wadati Method) of our 1-D models showed values comparable to the average values for a typical continental crust. This presumably indicates that sources of partial melts، if exist beneath the region، are most likely residing in the lower crust. We also examined the event distribution in depth in order to delineate the geometry of the active faults. The majority of events occurred at the north of the North Tabriz fault. Therefore، it seems to be a vertical fault with a gentle northward dip and the events frequently occur in a depth range of 10 to 25 km (within the crystalline basement). And also some hidden faults seem to exist، which are not traced on the surface geological maps.

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 moderate earthquake (Ms=6. 3) struck the coastal region of north of Iran and the central Alborz on 28 May, 2004 was responsible of several damages and about 35 casualties. The mainshock was followed by a large number of aftershocks, the largest one reaching Ml=4. 8, based on the analysis of local waveforms. We study the mainshock, first major aftershock, and about 240 aftershocks recorded by Iranian National Seismic Network (INSN), Tehran Telemetry Seismic Network (Institute of Geophysics, Tehran University), and our temporary local seismological stations, which were installed on 30 May, around the epicentral area of this earthquake. Using waveforms of all permanent stations, the coordinates of the mainshock was determined as 36. 30 °N for latitude and 51. 60 °E for longitude. The analysis of aftershocks indicates that the seismic activity migrate from east where the mainshock occurred toward west close to the location of the largest aftershock (36. 36 ° N, 51. 45 ° E). 140 selected aftershocks recorded at a minimum of 6 stations, having rms less than 0. 15 sec and uncertainties less than 2 km, were used to infer a precise geometry of the fault region. The aftershocks distribution has 30 km long and trends NW-SE parallel to the North Alborz and Khazar faults. The focal depths comprised between 10 and 28 km, unusually deep for Iran. Distribution of aftershocks cluster on cross-section defines a fault plane which dips at 40-50 degree south-westward. Its upward continuation can be related to either North Alborz or Khazar faults. Most of the focal mechanisms are consistent with reverse faulting on NW-SE trending faults, parallel to the main active structures of the region. Well constraint focal mechanisms which dip gently at a rate of 25-40ْ indicate the activity of the second mentioned faults during the Firozabad-Kojour earthquake. Existence of focal depths up to 28 km indicates an unusual brittle lower crystalline crust in this part of central Alborz.