Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Petrography and geochemistry of the Neyriz Miocene sediments (RoshanKuh and Kuh-e Asaki sections): implication for provenancePetrography and geochemistry of the Neyriz Miocene sediments (RoshanKuh and Kuh-e Asaki sections): implication for provenance3184067010.22071/gsj.2016.40670FAP Gholami ZadehPhD Student, Department of Geology, Faculty of Earth Sciences, Shahid Beheshti University, Tehran, IranM.H AdabiProfessor, Department of Geology, Faculty of Earth Sciences, Shahid Beheshti University, Tehran, IranM Hosseini-BarziAssociate Professor, Department of Geology, Faculty of Earth Sciences, Shahid Beheshti University, Tehran, IranA SadeghiAssociate Professor, Research Institute for Earth Sciences, Geological Survey of Iran, Tehran, IranM.R GhassemiAssociate Professor, Research Institute for Earth Sciences, Geological Survey of Iran, Tehran, IranJournal Article20151007Petrography and geochemistry of the Neyriz Miocene sediments at RoshanKuh and Kuh-e Asaki sections were carried out to determine their provenance, tectonic setting and paleoclimate conditions in the proximal part of Zagros Basin. The Miocene sediments are limited to the Zagros Main Fault at the northeast and the Neyrizophiolite zone at the southwest in the Neyriz region. They contain about 700 m red and green sandstone, conglomerate and marl which overlay the Jahrum Formation with a disconformity and covered by Bakhtiari conglomerate with an angular unconformity.Petrography of thin sections indicates that the rock fragments are the most constituent, and then quartz and feldspar respectively. The low compositional and textural maturity of the studied samples (angular grains and poorly sorted sandstones) shows the proximity to the source area. Petrography of the rock fragments and the bulk chemical composition of samples display that their provenance is multiple and the sediments were derived from Sanandaj-Sirjan Zone (Cretaceous limestone- metamorphic rocks- Eocene volcanic) and Zagros Zone (ophiolite sequence- radiolarites- Eocene limestone). Also, point-count data plotted on the QFL and QmFLt triangles indicate the recycled orogen and magmatic arc provenance. Based on geochemical data tectonic setting of Neyriz Miocene sediments is continental island arc and active continental margin. The averages of Cullers' index, CIW΄ (for calculation of the chemical weathering), ICV Index (to determine the maturity source), and SiO<sub>2</sub>versus Al<sub>2</sub>O<sub>3</sub> + K<sub>2</sub>O + Na<sub>2</sub>O diagram for these sediments show a poor weathering and dry climatic condition during their deposition which is supported by the high percentage of calcareous cement and frequency of the rock fragments. The results of this study suggest a sedimentlogical framework for the proximal part of Zagros Basin and the Miocene syn-depositional processes.Petrography and geochemistry of the Neyriz Miocene sediments at RoshanKuh and Kuh-e Asaki sections were carried out to determine their provenance, tectonic setting and paleoclimate conditions in the proximal part of Zagros Basin. The Miocene sediments are limited to the Zagros Main Fault at the northeast and the Neyrizophiolite zone at the southwest in the Neyriz region. They contain about 700 m red and green sandstone, conglomerate and marl which overlay the Jahrum Formation with a disconformity and covered by Bakhtiari conglomerate with an angular unconformity.Petrography of thin sections indicates that the rock fragments are the most constituent, and then quartz and feldspar respectively. The low compositional and textural maturity of the studied samples (angular grains and poorly sorted sandstones) shows the proximity to the source area. Petrography of the rock fragments and the bulk chemical composition of samples display that their provenance is multiple and the sediments were derived from Sanandaj-Sirjan Zone (Cretaceous limestone- metamorphic rocks- Eocene volcanic) and Zagros Zone (ophiolite sequence- radiolarites- Eocene limestone). Also, point-count data plotted on the QFL and QmFLt triangles indicate the recycled orogen and magmatic arc provenance. Based on geochemical data tectonic setting of Neyriz Miocene sediments is continental island arc and active continental margin. The averages of Cullers' index, CIW΄ (for calculation of the chemical weathering), ICV Index (to determine the maturity source), and SiO<sub>2</sub>versus Al<sub>2</sub>O<sub>3</sub> + K<sub>2</sub>O + Na<sub>2</sub>O diagram for these sediments show a poor weathering and dry climatic condition during their deposition which is supported by the high percentage of calcareous cement and frequency of the rock fragments. The results of this study suggest a sedimentlogical framework for the proximal part of Zagros Basin and the Miocene syn-depositional processes.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Mineral chemistry, thermobarometry and genesis of Clinopyroxenes in dyke swarm of northeast of meshkinshahr, NW IranMineral chemistry, thermobarometry and genesis of Clinopyroxenes in dyke swarm of northeast of meshkinshahr, NW Iran19364067210.22071/gsj.2016.40672FAM FadaeianPh.D. student, Department of Geology, Nature science branch, Tabriz University, IranA JahangiriInstructor, Department of Geology, Payame Noor University, Tehran, IranM MoayyedFull professors, Department of Geology, Faculty of Nature Science, Tabriz University, IranJournal Article20151026The study area is located in the Ardabil province and in the north east of Meshkinshahr city.More than 200 small and large Eocene age dykes have outcrops in this area with basaltic, tephritic, andesitic and trachy andesit composition. Clinopyroxene, plagioclase, analcime and sometimes coarse olivine crystals are present in these rocks. Mineral chemistry studies suggested that clinopyroxene type in rocks is Diopside type. Existence of normal and reverse zoning in clinopyroxens deduces differentiation were effective factors on evolution of the rocks. Enriched elements Ti, Al, Na, and K of pyroxene core to the rim of the effect of metasomatism to in these rocks. Tectonomagmatic diagrams and compare the chemical composition of study area clinopyroxenes with other tectonic environment suggested that characteristics of alkaline rocks related to volcanic arc. According to geotermobarometric studies clinopyroxenes in study rocks formed at temperature 1150-1200ºC and pressure of 7-14 Kbars. The depth for generation of magma between 55-65 Km and average 60 Km estimated for these rocks.The study area is located in the Ardabil province and in the north east of Meshkinshahr city.More than 200 small and large Eocene age dykes have outcrops in this area with basaltic, tephritic, andesitic and trachy andesit composition. Clinopyroxene, plagioclase, analcime and sometimes coarse olivine crystals are present in these rocks. Mineral chemistry studies suggested that clinopyroxene type in rocks is Diopside type. Existence of normal and reverse zoning in clinopyroxens deduces differentiation were effective factors on evolution of the rocks. Enriched elements Ti, Al, Na, and K of pyroxene core to the rim of the effect of metasomatism to in these rocks. Tectonomagmatic diagrams and compare the chemical composition of study area clinopyroxenes with other tectonic environment suggested that characteristics of alkaline rocks related to volcanic arc. According to geotermobarometric studies clinopyroxenes in study rocks formed at temperature 1150-1200ºC and pressure of 7-14 Kbars. The depth for generation of magma between 55-65 Km and average 60 Km estimated for these rocks.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Analysis of geometric and kinematic parameters of strain on the open gash veins within the Boushad shear zone (Birjand Ophiolitic Mélange, eastern Iran)Analysis of geometric and kinematic parameters of strain on the open gash veins within the Boushad shear zone (Birjand Ophiolitic Mélange, eastern Iran)37464067910.22071/gsj.2016.40679FAN Naimi-ghassabian1Department of Geology, University of Birjand, Birjand; Geological Survey of Iran,Mashhad, IranM. M KhatibDepartment of Geology, University of Birjand, Birjand, Iran,T Ghasemi RozvehDepartment of Geology, University of Birjand, Birjand, IranH NazariResearch Institute, Geological Survay of Iran, Tehran,Iran0000-0002-0004-6303M.R HeyhatDepartment of Geology, University of Birjand, Birjand, IranJournal Article20150105The Boushad shear zone (BSZ) is situated in the south of Birjand with at least 45 km length, about 9.2 Km width and strike N90E. The parts of the ophiolite mélange shear zone south of Birjand have changed by this shear zone. The earliest deformation, a polyphasesynmetamorphic deformation which occurred entirely in ductile conditions, D<sub>1</sub> and D<sub>2</sub> deformation phases are related to this deformation. The D<sub>3</sub> deformation affected the area after a period of sedimentation and erosion, Tension gash veins are formed simultaneously. The Strike-slip faults, thrust faults and fault related folds were classified as structures related to the D<sub>4</sub> tectonic event, the most recent phase of conflict in the region N055 ±10E is formed. Degree of convergence of the shear zone is R = 0.3, that indicating the formation of a dextral Transpression (Slightly oblique-convergent).The Boushad shear zone (BSZ) is situated in the south of Birjand with at least 45 km length, about 9.2 Km width and strike N90E. The parts of the ophiolite mélange shear zone south of Birjand have changed by this shear zone. The earliest deformation, a polyphasesynmetamorphic deformation which occurred entirely in ductile conditions, D<sub>1</sub> and D<sub>2</sub> deformation phases are related to this deformation. The D<sub>3</sub> deformation affected the area after a period of sedimentation and erosion, Tension gash veins are formed simultaneously. The Strike-slip faults, thrust faults and fault related folds were classified as structures related to the D<sub>4</sub> tectonic event, the most recent phase of conflict in the region N055 ±10E is formed. Degree of convergence of the shear zone is R = 0.3, that indicating the formation of a dextral Transpression (Slightly oblique-convergent).Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Kinematic architecture of fault damage zones in SW- RafsanjanKinematic architecture of fault damage zones in SW- Rafsanjan47604068710.22071/gsj.2016.40687FAL EbadiP.hD Student, Faculty of Earth sciences,Shahid Beheshti University, Tehran, IranA AlaviAssociate Professor, Faculty of Earth sciences,Shahid Beheshti University, Tehran, IranM.R GhassemiAssociate Professor Geological survey of Tehran, IranJournal Article20150620The study area is located in the SW Rafsanjan city and central Iran. In the area, strike- slip faults effected the Cenozoic unites. This paper analysis subsidiary fault data collected from damage zones associated with the Cenozoic Rafsanjan intraplate right-lateral strike-slip fault systems in SW Rafsanjan city. Fault sets, arranged in a consistent kinematic architecture that is compatible with the Cenozoic regional strike-slip environment. In the paper, kinematic architecture of fault zone interpret in the subsidiary fault. The results show that five peaks is prominence. Angular and kinematic relation among subsidiary fault set show that right-lateral strike- slip and revers fault are the dominant kinematic type in the area. Based on, the angular analysis in the damage zone, we have 5 subsets. 2 subsets of 5 subsets named 1rev (NW-SE trending) and 2rev (E-W trending). In the strike- slip fault mechanism, 3 subsets is demined, three azimuth named 1rl (NW-SE striking), 2rl (E-W striking) and 3rl (WNW-ESE striking). Average strike of set 1rl and 1rev indicate the orientation of the PDZ for fault systems and the PDZ be produced by early localization of the principal displacement zone along pre-existing mechanical discontinuities inherited. Early formation of the PDZ by re-activating pre-existing mechanical discontinuities.The azimuthal value of the faults set in the kinematic architecture are similar to predicted by the simple shear Reidel model. By analysis with kinematic architecture in damage zone of strike- slip fault system indicated that the linking damage zone is very important to increase permeability and created void. The void is low pressure stress and magma can intrude in the area and the dikes formed. The PDZ induced stress and the second and third order fracture is created. Stress analysis in the study are show shear – compression regime convert to compression. The maximum principle axis show N20E to N-S in the Cenozoic. The change of stress regime is correlated by formation fault and fold with E-W trend. The change regime caused reactive pre-exiting fault. The study area is located in the SW Rafsanjan city and central Iran. In the area, strike- slip faults effected the Cenozoic unites. This paper analysis subsidiary fault data collected from damage zones associated with the Cenozoic Rafsanjan intraplate right-lateral strike-slip fault systems in SW Rafsanjan city. Fault sets, arranged in a consistent kinematic architecture that is compatible with the Cenozoic regional strike-slip environment. In the paper, kinematic architecture of fault zone interpret in the subsidiary fault. The results show that five peaks is prominence. Angular and kinematic relation among subsidiary fault set show that right-lateral strike- slip and revers fault are the dominant kinematic type in the area. Based on, the angular analysis in the damage zone, we have 5 subsets. 2 subsets of 5 subsets named 1rev (NW-SE trending) and 2rev (E-W trending). In the strike- slip fault mechanism, 3 subsets is demined, three azimuth named 1rl (NW-SE striking), 2rl (E-W striking) and 3rl (WNW-ESE striking). Average strike of set 1rl and 1rev indicate the orientation of the PDZ for fault systems and the PDZ be produced by early localization of the principal displacement zone along pre-existing mechanical discontinuities inherited. Early formation of the PDZ by re-activating pre-existing mechanical discontinuities.The azimuthal value of the faults set in the kinematic architecture are similar to predicted by the simple shear Reidel model. By analysis with kinematic architecture in damage zone of strike- slip fault system indicated that the linking damage zone is very important to increase permeability and created void. The void is low pressure stress and magma can intrude in the area and the dikes formed. The PDZ induced stress and the second and third order fracture is created. Stress analysis in the study are show shear – compression regime convert to compression. The maximum principle axis show N20E to N-S in the Cenozoic. The change of stress regime is correlated by formation fault and fold with E-W trend. The change regime caused reactive pre-exiting fault. Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901The geological study of the origin of boron contamination in the Issiso springs, North of UrmiaThe geological study of the origin of boron contamination in the Issiso springs, North of Urmia61664068810.22071/gsj.2016.40688FAM AsadpourAssistant Professor, Department of Geology, Faculty of Science, Urmia University, Urmia, IranE Abbas NovinpourAssistant Professor, Department of Geology, Faculty of Science, Urmia University, Urmia, IranR NikrouzAssistant Professor, Department of Geology, Faculty of Science, Urmia University, Urmia, IranJournal Article20150512Issiso hot springs are located 70 km of North of Urmia, within the northernmost part of the Sanandaj–Sirjan zone. The basement of study area is comprised by precambrian metamorphic rocks that consist of gneiss, schist and amphibolite are overlain by younger sediments. The boron concentration in the study area thermal waters is up to 451 mg/l. The warm waters of the region belong to the type of Na-(SO4)-HCO3. The Na/Cl ratio is more than 1 and B/Cl ratio is 0.37. It reflects the impact of specific geological phenomena in formation of rocks. Up to now there is no any geological study of the origin boron in this area. The main aim of this study is to determine geological factor(s) creating this high concentration which caused many environmental problems in the region. In this study it is determined that penetration meteoric water, heated by the deep intrusive magmatic bodies and then rises up with magmatic waters. At high levels, these waters collect in reservoirs including metamorphic host rocks and caused leaching of boron bearing mineral phases. The boron bearing water reaches the surface through faults. Part of the contamination water appears in the form of hot springs and another part through the faults caused spread contamination around the areas. This study shows that high boron contents in the Issiso thermal waters can be attributed to: 1) unstable boron bearing mineral phases same of muscovite, tourmaline, biotite and hornblende in the metamorphic rocks such as gneiss and mica schist, and 2) input of boron-bearing magmatic fluids, related to young volcanic activities. Due to the high temperature play a large role in leaching the boron from the path rocks, it is estimated that high content of boron in Issiso springs may indicate the presence high potential of reservoirs of hot water in depths of earth and also the presence of rocks with high boron content in the path of rising waters.Issiso hot springs are located 70 km of North of Urmia, within the northernmost part of the Sanandaj–Sirjan zone. The basement of study area is comprised by precambrian metamorphic rocks that consist of gneiss, schist and amphibolite are overlain by younger sediments. The boron concentration in the study area thermal waters is up to 451 mg/l. The warm waters of the region belong to the type of Na-(SO4)-HCO3. The Na/Cl ratio is more than 1 and B/Cl ratio is 0.37. It reflects the impact of specific geological phenomena in formation of rocks. Up to now there is no any geological study of the origin boron in this area. The main aim of this study is to determine geological factor(s) creating this high concentration which caused many environmental problems in the region. In this study it is determined that penetration meteoric water, heated by the deep intrusive magmatic bodies and then rises up with magmatic waters. At high levels, these waters collect in reservoirs including metamorphic host rocks and caused leaching of boron bearing mineral phases. The boron bearing water reaches the surface through faults. Part of the contamination water appears in the form of hot springs and another part through the faults caused spread contamination around the areas. This study shows that high boron contents in the Issiso thermal waters can be attributed to: 1) unstable boron bearing mineral phases same of muscovite, tourmaline, biotite and hornblende in the metamorphic rocks such as gneiss and mica schist, and 2) input of boron-bearing magmatic fluids, related to young volcanic activities. Due to the high temperature play a large role in leaching the boron from the path rocks, it is estimated that high content of boron in Issiso springs may indicate the presence high potential of reservoirs of hot water in depths of earth and also the presence of rocks with high boron content in the path of rising waters.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Geology and Mineralization of Khanik-Qazan titanium potential, Urmia, West Azarbaijan province, NW IranGeology and Mineralization of Khanik-Qazan titanium potential, Urmia, West Azarbaijan province, NW Iran67784069110.22071/gsj.2016.40691FAS AlipourAssociated Professor, Department of Geology, Faculty of Science, Urmia University, Urmia, Iran0000-0001-5945-5307B HosseinzadeM. Sc., Department of Geology, Faculty of Science, Urmia University, Urmia, IranY RahimsouriAssistant Professor, Department of Geology, Faculty of Science, Urmia University, Urmia, IranJournal Article20151031Khanik-Gazan titanium potential is located at 82 km northwest of Urmia at the extremity of NW of Sanandaj-Sirjan geological zone. This deposit has formed in the Qazan mafic-ultramafic intrusive complex that intruded into the early Paleozoic sedimentary rocks. It consist of two general rock units including 1) mafic unit as the main outcrop volume and 2) ultramafic unit in smaller volume. The mafic rock type is gabbro in general formed of medium grained and layered accompanying by anorthosite sill and microgabbro (diabase). Layered mela and meso-gabbro are the main host rocks for titanium mineralisation in the studied area. The main minerals of the host rock included clinopyroxene (mainly augite), and calcic plagioclases. Opaque minerals and rarely olivine and apatite are the minor minerals and tremolite-actinolite, epidote, zoisite, chlorite, albite, sericite and calcite are the secondary minerals. Saussuritization, uralitization, sericitization and chloritization are the main alterations of main silicate minerals. Ilmenite, titanomagnetite, magnetite, and some hematite and pyrrhotite are the main primary opaque ore minerals. Open-space filling textures including granular and exsolution are the major textures of the ore, while, Spherical, martitization, mylonitization are the minor textures. Total abundance of ilmenite, magnetite, titanomagnetite in the studied polished sections ranges between 5 to 12 vol%. Oxide and silicate phases are associated with the host rocks due to the relatively low oxygen fugacity, which don’t occurred in complete separation of the silicate melt from oxide melt. Based on geochemical studies, the primary magma had revealed an alkaline to sub-alkaline (mainly tholeitic trend) series. According to the mineralogical and petrographical evidences and chemical analyses, the Khanik-Qazan ilmenite-titanomagnetite deposit is similar to the low grade apatite- ilmenite–magnetite Kauhajarvi and Lumikangas deposits, in western Finland. Khanik-Gazan titanium potential is located at 82 km northwest of Urmia at the extremity of NW of Sanandaj-Sirjan geological zone. This deposit has formed in the Qazan mafic-ultramafic intrusive complex that intruded into the early Paleozoic sedimentary rocks. It consist of two general rock units including 1) mafic unit as the main outcrop volume and 2) ultramafic unit in smaller volume. The mafic rock type is gabbro in general formed of medium grained and layered accompanying by anorthosite sill and microgabbro (diabase). Layered mela and meso-gabbro are the main host rocks for titanium mineralisation in the studied area. The main minerals of the host rock included clinopyroxene (mainly augite), and calcic plagioclases. Opaque minerals and rarely olivine and apatite are the minor minerals and tremolite-actinolite, epidote, zoisite, chlorite, albite, sericite and calcite are the secondary minerals. Saussuritization, uralitization, sericitization and chloritization are the main alterations of main silicate minerals. Ilmenite, titanomagnetite, magnetite, and some hematite and pyrrhotite are the main primary opaque ore minerals. Open-space filling textures including granular and exsolution are the major textures of the ore, while, Spherical, martitization, mylonitization are the minor textures. Total abundance of ilmenite, magnetite, titanomagnetite in the studied polished sections ranges between 5 to 12 vol%. Oxide and silicate phases are associated with the host rocks due to the relatively low oxygen fugacity, which don’t occurred in complete separation of the silicate melt from oxide melt. Based on geochemical studies, the primary magma had revealed an alkaline to sub-alkaline (mainly tholeitic trend) series. According to the mineralogical and petrographical evidences and chemical analyses, the Khanik-Qazan ilmenite-titanomagnetite deposit is similar to the low grade apatite- ilmenite–magnetite Kauhajarvi and Lumikangas deposits, in western Finland. Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Origin of limestone conglomerates in the Unit 2 of Deh-Sufiyan Formatrion, Mila Group, Central Alborz, Northern IranOrigin of limestone conglomerates in the Unit 2 of Deh-Sufiyan Formatrion, Mila Group, Central Alborz, Northern Iran79904069310.22071/gsj.2016.40693FAA Bayet-GollInstitue for Advenced Studies in Basic Science, 45195-1159 Zanjan, IranR Moussavi-HaramiDepartment of Geology, Faculty of Science, Ferdowsi University of MashhadA MahboubiDepartment of Geology, Faculty of Science, Ferdowsi University of MashhadJournal Article20150714Carbonate deposits of members 1 to 2 of the Mila Group (Middle Cambrian) in Central Alborz that call the Deh-Sufiyan Formation in this research, were studied in Shahmirzad, Tueh-Darvar, Mila-Kuh and Deh-Molla sections. The Unit 2 of Deh-Sufiyan Formatrion in Central Alborz of Northern Iran consists mainly of shallow marine carbonates and contains a variety of limestone conglomerates. Limestone conglomerate is an important component of Unit 2 of Deh-Sufiyan Formatrion, but its origins remain enigmatic. These limestone conglomerates have a diverse set of characteristics that range from clast to matrix supported with scattered flat pebbles. These conglomerates are largely comprised of oligomictic, rounded lime–mudstone clasts of various sizes and shape (equant, oval, discoidal, tabular, and irregular). According to composition and characteristic sedimentary structures and fabric, limestone conglomerates in the Unit 2 of Deh-Sufiyan Formatrion consist of: (1) Intraformational limestone conglomerate beds were formed by depositional processes (2) Limestone pseudoconglomerate beds were produced by diagenetic processes. The common characteristics of the Unit 2 of Deh-Sufiyan Formatrion pseudoconglomerates, such as oligomictic lithology of lime–mudstone clasts, mosaic fabric, disorganized/edgewise fabric, variable and gradational fabric, transitions from adjacent or underlying facies and the complete lack of depositional structures, are typical of pseudoconglomerates formed by early diagenetic sediment deformation under shallow burial conditions. These characteristics are different from those of intraformational limestone conglomerate showing primary depositional features such as normal or inverse grading, internal stratification, (hummocky) cross-stratification and sharp erosional bases. Diagenetic conglomerates in ribbon rocks resulted from soft-sediment deformation of ribbon rocks during early diagenesis. In contrast, the dimension and thickness, sizes of the clasts, clast-rich beds, size ingredient of matrix, tendency to amalgamate with amalgamation scours within depositional conglomerates suggest that high energy and strong erosion above storm wave base was responsible for the disintegration of the carbonate material.Carbonate deposits of members 1 to 2 of the Mila Group (Middle Cambrian) in Central Alborz that call the Deh-Sufiyan Formation in this research, were studied in Shahmirzad, Tueh-Darvar, Mila-Kuh and Deh-Molla sections. The Unit 2 of Deh-Sufiyan Formatrion in Central Alborz of Northern Iran consists mainly of shallow marine carbonates and contains a variety of limestone conglomerates. Limestone conglomerate is an important component of Unit 2 of Deh-Sufiyan Formatrion, but its origins remain enigmatic. These limestone conglomerates have a diverse set of characteristics that range from clast to matrix supported with scattered flat pebbles. These conglomerates are largely comprised of oligomictic, rounded lime–mudstone clasts of various sizes and shape (equant, oval, discoidal, tabular, and irregular). According to composition and characteristic sedimentary structures and fabric, limestone conglomerates in the Unit 2 of Deh-Sufiyan Formatrion consist of: (1) Intraformational limestone conglomerate beds were formed by depositional processes (2) Limestone pseudoconglomerate beds were produced by diagenetic processes. The common characteristics of the Unit 2 of Deh-Sufiyan Formatrion pseudoconglomerates, such as oligomictic lithology of lime–mudstone clasts, mosaic fabric, disorganized/edgewise fabric, variable and gradational fabric, transitions from adjacent or underlying facies and the complete lack of depositional structures, are typical of pseudoconglomerates formed by early diagenetic sediment deformation under shallow burial conditions. These characteristics are different from those of intraformational limestone conglomerate showing primary depositional features such as normal or inverse grading, internal stratification, (hummocky) cross-stratification and sharp erosional bases. Diagenetic conglomerates in ribbon rocks resulted from soft-sediment deformation of ribbon rocks during early diagenesis. In contrast, the dimension and thickness, sizes of the clasts, clast-rich beds, size ingredient of matrix, tendency to amalgamate with amalgamation scours within depositional conglomerates suggest that high energy and strong erosion above storm wave base was responsible for the disintegration of the carbonate material.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Deformation and folding of mylonitic fabrics in Nowqan ductile shear zone: SW Golpaygan (Sanandaj - Sirjan zone)Deformation and folding of mylonitic fabrics in Nowqan ductile shear zone: SW Golpaygan (Sanandaj - Sirjan zone)91984069410.22071/gsj.2016.40694FAM MohajjelGeology Department, Tarbiat Modares UniversityS Houshmand, MaGeological survey of IranJournal Article20050227A NW-SE trending ductile shear zone has been generated in the metamorphic rocks of the southwest Golpaygan. Different pellitic and psammitic schists, meta-carbonates and igneous rocks were strongly deformed in this ductile shear zone and produced mylonites and ultra-mylonites. Structural analysis indicates three stages of foliations in the metamorphic rocks. Geometry and kinematics of the fabrics in Nowgan shear zone are divided into two northeastern and southwestern parts (limbs of Nowqan antiform). Mylonitic foliation moderately to steeply dip towards northeast in the northeastern part but dips to the southwest in the southwestern part. Mineral and stretching lineation, are shallowly to moderately plunging to the east-southeast in the northeastern part of the shear zone and, to the west-northwest in the southwestern part. The microstructural indicators of shear sense cleared that the northeastern part dextrally displaced along strike with normal component and the southwestern part sinisterly displaced with reverse component at the present situation. The fabrics evidence clear that this ductile shear zone were originally right-lateral strike–slip shear zone and during its structural evolution it was rotated around its strike during later folding stage. Structural analysis of the surrounded rocks of the shear zone indicates three superposed foliations. The mylonitic foliation in the shear zone and the axial plane foliations of the second stage folding are sub-parallel. Plunge directions of the second stage folds axes and the mineral/stretching lineation are also sub-parallel. Therefore, the initiation and development of the shear zone were synchronous with the second stage folding event. <br /> A NW-SE trending ductile shear zone has been generated in the metamorphic rocks of the southwest Golpaygan. Different pellitic and psammitic schists, meta-carbonates and igneous rocks were strongly deformed in this ductile shear zone and produced mylonites and ultra-mylonites. Structural analysis indicates three stages of foliations in the metamorphic rocks. Geometry and kinematics of the fabrics in Nowgan shear zone are divided into two northeastern and southwestern parts (limbs of Nowqan antiform). Mylonitic foliation moderately to steeply dip towards northeast in the northeastern part but dips to the southwest in the southwestern part. Mineral and stretching lineation, are shallowly to moderately plunging to the east-southeast in the northeastern part of the shear zone and, to the west-northwest in the southwestern part. The microstructural indicators of shear sense cleared that the northeastern part dextrally displaced along strike with normal component and the southwestern part sinisterly displaced with reverse component at the present situation. The fabrics evidence clear that this ductile shear zone were originally right-lateral strike–slip shear zone and during its structural evolution it was rotated around its strike during later folding stage. Structural analysis of the surrounded rocks of the shear zone indicates three superposed foliations. The mylonitic foliation in the shear zone and the axial plane foliations of the second stage folding are sub-parallel. Plunge directions of the second stage folds axes and the mineral/stretching lineation are also sub-parallel. Therefore, the initiation and development of the shear zone were synchronous with the second stage folding event. <br /> Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Evaluation of erodibility of Sefidroud Delta deposits based on engineering geological factorsEvaluation of erodibility of Sefidroud Delta deposits based on engineering geological factors991084072210.22071/gsj.2016.40722FAM HashemiAssistant Professor, Department of Geology, Faculty of Sciences, University of Isfahan, Isfahan, IranR AjalloeianProfessor, Department of Geology, Faculty of Sciences, University of Isfahan, Isfahan, IranM.R NikoudelAssociate Professor, Department of Engineering Geology, Faculty of Basic Sciences, Tarbiat Modares University, Tehran, IranJournal Article20151003In the present study, erodibility of various deposits of Sefidrud Delta was evaluated based on effective engineering geological factors. First of all, the study area was studied from geology and sedimentology point of view and various deposits were identified in this area. Then the engineering geological characteristics of deposits were determined based on existing geotechnical data, field investigation and performance of 32 dynamic cone penetrometer test (DCP). Finally, by development a simple and precise method, the erodibility of various deposits was evaluated based on texture and shear strength factors.
The results show that the erodibility of deposits has a close relationship to the sedimentological characteristics and erodibility could be analyzed regarding the geological history of deposits. According to the results of this research, natural levee deposits have highest erodibility and in other hand old deltaic deposits have lowest erodibility in Sefidrud Delta area. Such researches have a main role in sustainable development of the study area.In the present study, erodibility of various deposits of Sefidrud Delta was evaluated based on effective engineering geological factors. First of all, the study area was studied from geology and sedimentology point of view and various deposits were identified in this area. Then the engineering geological characteristics of deposits were determined based on existing geotechnical data, field investigation and performance of 32 dynamic cone penetrometer test (DCP). Finally, by development a simple and precise method, the erodibility of various deposits was evaluated based on texture and shear strength factors.
The results show that the erodibility of deposits has a close relationship to the sedimentological characteristics and erodibility could be analyzed regarding the geological history of deposits. According to the results of this research, natural levee deposits have highest erodibility and in other hand old deltaic deposits have lowest erodibility in Sefidrud Delta area. Such researches have a main role in sustainable development of the study area.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Geochemistry and U-Pb dating of North Saman granitoid rocksGeochemistry and U-Pb dating of North Saman granitoid rocks1091204072310.22071/gsj.2016.40723FAB HosseiniAssistant professor, Department of Geology, Payame Noor UniversityA.R AhmadiAssistant professor, Department of Geology, Payame Noor UniversityJournal Article20150617Deformed granitoid rocks from North Saman represent part of magmatic activity in Sanandaj-Sirjan during the Mesozoic. The granitoid rocks intruded as separate intrusions into metamorphosed rocks which have protolith ages of the Palaeozoic and Mezosoic. The intruded granitoid rocks have been deformed as a result of subsequent tectonic activities. Zircon U-Pb ages of crystals extracted from the granitoid rocks gave ages of 182 ± 4 Ma and indicate that the granitoid rocks crystallized in the Toarcian stage of the lower Jurassic. The major and trace element goechemistry suggests a subduction-related, active continental margin setting for the granitoid bodies. The occurrences of numerous Jurassic granitoids reveal the importance of magmatic activities of this period in the Sanandaj-Sirjan zone. Deformed granitoid rocks from North Saman represent part of magmatic activity in Sanandaj-Sirjan during the Mesozoic. The granitoid rocks intruded as separate intrusions into metamorphosed rocks which have protolith ages of the Palaeozoic and Mezosoic. The intruded granitoid rocks have been deformed as a result of subsequent tectonic activities. Zircon U-Pb ages of crystals extracted from the granitoid rocks gave ages of 182 ± 4 Ma and indicate that the granitoid rocks crystallized in the Toarcian stage of the lower Jurassic. The major and trace element goechemistry suggests a subduction-related, active continental margin setting for the granitoid bodies. The occurrences of numerous Jurassic granitoids reveal the importance of magmatic activities of this period in the Sanandaj-Sirjan zone. Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Investigation of methods the assessment of critical and strategic minerals and elements, with a special focus on geoeconomics of fluorspar in IranInvestigation of methods the assessment of critical and strategic minerals and elements, with a special focus on geoeconomics of fluorspar in Iran1211304072410.22071/gsj.2016.40724FAS. M MasoudiPh.D. student, Political Geography Group, Imam Reza University, Mashhad, IranE EzatiAssociate Professor & Manager of Political Geography Group, Imam Reza University, Mashhad, IranN Rashidnejad OmranAssociate Professor & Manager of Petrology Group, Dept. of Basic Sciences, Tarbiat Modares University,
Tehran, IranJournal Article20150726Before the Cold War, strategic materials supply and studies related to them were more affected by military competition between East and West, the example was the assessment of the geopolitical risk factors by Anderson for the North Atlantic Treaty Organization. But after the Cold War and the collapse of the Berlin Wall in 1989 and the development of Chinese economy, more and more Western countries were concerned of the vulnerability against the suppliers of minerals. The main reason for it is geopolitical developments and turning of militarism and Geostrategy to Geoeconomics and priority the economy. The methods of assessment the post-Cold War based on confrontation between the north and south and provide more economic security or economic power and provide needed goods and protection of the environment. New methods started with research of the National Council of United States of America by novation the criticality matrix with two-dimensional in economic importance and supply risk, and Graedel studies was actually follow its principles. According to investigations of Geological Survey and Department of Defense in the United States and the European Union and German industry represent fluorspar is strategic mineral in the world. Economic value of fluorspar is used in the production of steel, aluminum, hydrofluorocarbon, Teflon, new and clean energy. In this research with investigations of fluorspar producer countries in the last fifteen years, however, Iran has achieved tenth grade with one percent, but still one of the main importers of intermediate goods made of this mineral is between neighboring countries. Therefore, the first step is essential the investment for systematic and in-depth exploration in the country and especially in the central Alborz, with the goal of increasing fluorspar reserves and supply raw materials for the aluminum industry of the country. The industrial that south competitors of Iran, due to the low cost of energy in the region, have been activated by investing in it seriously.Before the Cold War, strategic materials supply and studies related to them were more affected by military competition between East and West, the example was the assessment of the geopolitical risk factors by Anderson for the North Atlantic Treaty Organization. But after the Cold War and the collapse of the Berlin Wall in 1989 and the development of Chinese economy, more and more Western countries were concerned of the vulnerability against the suppliers of minerals. The main reason for it is geopolitical developments and turning of militarism and Geostrategy to Geoeconomics and priority the economy. The methods of assessment the post-Cold War based on confrontation between the north and south and provide more economic security or economic power and provide needed goods and protection of the environment. New methods started with research of the National Council of United States of America by novation the criticality matrix with two-dimensional in economic importance and supply risk, and Graedel studies was actually follow its principles. According to investigations of Geological Survey and Department of Defense in the United States and the European Union and German industry represent fluorspar is strategic mineral in the world. Economic value of fluorspar is used in the production of steel, aluminum, hydrofluorocarbon, Teflon, new and clean energy. In this research with investigations of fluorspar producer countries in the last fifteen years, however, Iran has achieved tenth grade with one percent, but still one of the main importers of intermediate goods made of this mineral is between neighboring countries. Therefore, the first step is essential the investment for systematic and in-depth exploration in the country and especially in the central Alborz, with the goal of increasing fluorspar reserves and supply raw materials for the aluminum industry of the country. The industrial that south competitors of Iran, due to the low cost of energy in the region, have been activated by investing in it seriously.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Late Devonian-Early Carboniferous fish microremains from KermanLate Devonian-Early Carboniferous fish microremains from Kerman1311424072510.22071/gsj.2016.40725FAT AhmadiAssistant Professor, Department of geology, Payame Noor University (PNU), Iran.V HairapetianAssistant Professor, Department of geology, Islamic Azad University, Khorasgan Branch, Esfahan, Iran0000-0001-6202-0152H GholamalianAssistant Professor, Department of geology, Hormozgan University, Bandar Abbas, Iran. .0000-0002-1752-6872M.R VaziriAssociate Professor, Department of geology, Shahid Bahonar University of Kerman, Kerman, Iran.M DastanpourProfessor, Department of geology, Kerman institute of Higher Education, Kerman, Iran.Journal Article20151031From Late Devonian-Early Carboniferous strata in the Kerman area fourteen chondrichthyan taxa were identified. The abundance of chondrichthyan teeth in Famennian strata is considerable. The high abundance of protacrodonts and larger proportion of shallower shelves of pheobodonts appeared to dominate in a shallow environment at the Famennian. The chondricthyan assemblage from the Famennian of the Hutk section resembles the Chahriseh fauna in Esfahan district that reveals similar palaeoenvironmental conditions in Central Iran basin. The occurrence of <em>Deihim mansureae</em> in <em>duplicate</em> Zone marks the youngest record for the species up to Early Tournaisian.From Late Devonian-Early Carboniferous strata in the Kerman area fourteen chondrichthyan taxa were identified. The abundance of chondrichthyan teeth in Famennian strata is considerable. The high abundance of protacrodonts and larger proportion of shallower shelves of pheobodonts appeared to dominate in a shallow environment at the Famennian. The chondricthyan assemblage from the Famennian of the Hutk section resembles the Chahriseh fauna in Esfahan district that reveals similar palaeoenvironmental conditions in Central Iran basin. The occurrence of <em>Deihim mansureae</em> in <em>duplicate</em> Zone marks the youngest record for the species up to Early Tournaisian.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Sequence stratigraphy of the Carboniferous deposits in Ayenehvarzan–Dalichai anticline, east of Tehran, Central AlborzSequence stratigraphy of the Carboniferous deposits in Ayenehvarzan–Dalichai anticline, east of Tehran, Central Alborz1431544072610.22071/gsj.2016.40726FAN Kohansal-GhadimvandAssistant professor, Department of Geology, Faculty of science, Islamic Azad University, North Tehran branch, Tehran, Iran0000-0003-0706-5897SH GholipouriPh. D. Student, Department of Geology, Faculty of science, Islamic Azad University, North Tehran branch, Tehran, IranM.R MajidifardAssistant professor, Geosciences Research Center, Geological survey of Iran, Tehran, IranJournal Article20151104The early carboniferous Mobarak Formation was studied in southern flank of Ayenehvarzan–Dalichai anticline, in Aru and Seyedabad sections, east of Tehran. The aim of this study is to determine microfacies, interpretation of depositional environments and sequence stratigraphy of the Mobarak Formation. In this study, the thickness of Mobarak Formation in Aru and Seyedabad sections varies from 133 to 65 meters and consists of limestone with intercalations of shale and marl. According to lithological characteristics, the Mobarak Formation subdivided into several rock units. The Mobarak Formation is disconformably overlain by Jirud Formation and underlain by Dorod Formation. Ten microfacies have been recognized on the basis of depositional remarks and petrographic analysis. These carbonate facies belong to 4 major sub-environments including beach/tidal flat, lagoon, barrier/sand shoal and open marine. These facies deposited in a homoclinal carbonate ramp and include two sedimentary sequences. The early carboniferous Mobarak Formation was studied in southern flank of Ayenehvarzan–Dalichai anticline, in Aru and Seyedabad sections, east of Tehran. The aim of this study is to determine microfacies, interpretation of depositional environments and sequence stratigraphy of the Mobarak Formation. In this study, the thickness of Mobarak Formation in Aru and Seyedabad sections varies from 133 to 65 meters and consists of limestone with intercalations of shale and marl. According to lithological characteristics, the Mobarak Formation subdivided into several rock units. The Mobarak Formation is disconformably overlain by Jirud Formation and underlain by Dorod Formation. Ten microfacies have been recognized on the basis of depositional remarks and petrographic analysis. These carbonate facies belong to 4 major sub-environments including beach/tidal flat, lagoon, barrier/sand shoal and open marine. These facies deposited in a homoclinal carbonate ramp and include two sedimentary sequences. Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Recognition of Qahr-Abad fluorite deposit occurrence based on REE data, southeast Saqqez, Kurdistan provinceRecognition of Qahr-Abad fluorite deposit occurrence based on REE data, southeast Saqqez, Kurdistan province1551644072710.22071/gsj.2016.40727FAM BaratiDepartment of earth sciences, Faculty of earth sciences, Bu-Ali Sina UniversityA AkbarpourResearch institute earth sciences G.S.I .E Fazel TaleDepartment of earth sciences, Faculty of earth sciences, Bu-Ali Sina University.B TalaiDepartment of earth sciences, Faculty of earth sciences, Shiraz University.M MoslehiParsi Kan Kav consulting engineers company.Journal Article20130914The Qahr-abad fluorite deposit is located ~58 km southeast of Saqqez city, Kurdistan province. This deposit is developed as scatter lenses, veins, and veinlets (stockwork structure) within carbonate rocks. Violet, green and colorless fluorites are recognized. Quartz, dolomite, calcite and barite are gangues. REE geochemistry of the area suggests that the REE content of the fluorites lies between 20.18 and 48.38 ppm. The relatively higher concentration of LREEs in violet and colorless fluorites suggests that they formed in the first stages of mineralization. The calculation of Eu anomalies suggest that the fluorites formed in alkaline to neutral and to some extent oxidizing conditions because the Eu anomaly cover a narrow range around 1. The calculation of Ce anomaly which is negative, also confirms the oxidizing conditions for mineralizing fluids. Finally, by the studies of REE geochemistry it can be concluded that Qahr-Abad fluorite deposit is a product of hydrothermal activity of epithermal type and the mineralizing fluids are of magmatic or basinal origin by which the presence of magmatic activity in this district, it can be explained. The Qahr-abad fluorite deposit is located ~58 km southeast of Saqqez city, Kurdistan province. This deposit is developed as scatter lenses, veins, and veinlets (stockwork structure) within carbonate rocks. Violet, green and colorless fluorites are recognized. Quartz, dolomite, calcite and barite are gangues. REE geochemistry of the area suggests that the REE content of the fluorites lies between 20.18 and 48.38 ppm. The relatively higher concentration of LREEs in violet and colorless fluorites suggests that they formed in the first stages of mineralization. The calculation of Eu anomalies suggest that the fluorites formed in alkaline to neutral and to some extent oxidizing conditions because the Eu anomaly cover a narrow range around 1. The calculation of Ce anomaly which is negative, also confirms the oxidizing conditions for mineralizing fluids. Finally, by the studies of REE geochemistry it can be concluded that Qahr-Abad fluorite deposit is a product of hydrothermal activity of epithermal type and the mineralizing fluids are of magmatic or basinal origin by which the presence of magmatic activity in this district, it can be explained. Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Affection of Diagenesis on Reservoir Quality of Dariyan Formation in South Pars FieldAffection of Diagenesis on Reservoir Quality of Dariyan Formation in South Pars Field1651784072910.22071/gsj.2016.40729FAM.R RahmaniPh. D. Student, Department of Geology, Science and Research Branch, Islamic Azad University (IAU), Tehran, IranR Moussavi – HaramiProfessor, Department of Geology, Faculty of Science, Ferdowsi University of Mashhad, Mashhad, IranM ArianAssociate Professor, Department of Geology, Science and Research Branch, Islamic Azad University (IAU), Tehran, IranJournal Article20151014Dariyan formation is one of the oil reservoirs in the south pars field. This formation has been studied in wells SPO-1, SPO -2 and Spo-3. Thickness of Dariyan formation in mentioned wells are 109, 113 and 114 meters respectively. Based on the studies of thin sections from the Dariyan formation of three above mentioned wells, nine carbonate and one detrital facies have been identified within four facies associations including tidal flat (Mudstone), lagoon (Bioclast mudstone to wackstone, Bioclast peloid wackstone to packstone, Bioclast peloid packstone to grainstone, Algal boundstone), Mid ramp (Echinoid mollusk wackstone to packstone, Orbitolina wackstone to packstone, Framestone, Floatstone) and outer ramp (Shale). Facies studies indicate that Dariyan formation has been deposited in a homoclinal ramp.The Dariyan formation has been affected by four diagenetic stages, including marine, meteoric, burial and uplift. The most important identified diagenetic processes are micritization, bioturbation, geopetal, physical and chemical compaction, cementation, neomorphism, replacement, dissolution, fracturing and filling. Among the all diagenesis process, dissolution and fracturing are the major processes improving reservoir quality. In Contrary, physical compaction and especially cementation are the main processes redusing reservoir quality. Dissolution process with generating secondary porosity consists of vuggy and moldic, has important effect on increasing of porosity. Most of the dissolution features have been produced during the meteoric diagenesis and less through burial diagenesis. Dissolution process with develop the vuggy pores caused to connect them in some case and also affected on fractures , stylolites and previous diagenetic cements in upper and lower members of daryian formation which eventually has been increased permeability and reservoir quality. Also, Fracturing, the main other diagenetic process with connect the some individual vuggy and moldic pores together has effective role to increase the permeability and reservoir quality in upper and lower parts of Dariyan formation. Dariyan formation is one of the oil reservoirs in the south pars field. This formation has been studied in wells SPO-1, SPO -2 and Spo-3. Thickness of Dariyan formation in mentioned wells are 109, 113 and 114 meters respectively. Based on the studies of thin sections from the Dariyan formation of three above mentioned wells, nine carbonate and one detrital facies have been identified within four facies associations including tidal flat (Mudstone), lagoon (Bioclast mudstone to wackstone, Bioclast peloid wackstone to packstone, Bioclast peloid packstone to grainstone, Algal boundstone), Mid ramp (Echinoid mollusk wackstone to packstone, Orbitolina wackstone to packstone, Framestone, Floatstone) and outer ramp (Shale). Facies studies indicate that Dariyan formation has been deposited in a homoclinal ramp.The Dariyan formation has been affected by four diagenetic stages, including marine, meteoric, burial and uplift. The most important identified diagenetic processes are micritization, bioturbation, geopetal, physical and chemical compaction, cementation, neomorphism, replacement, dissolution, fracturing and filling. Among the all diagenesis process, dissolution and fracturing are the major processes improving reservoir quality. In Contrary, physical compaction and especially cementation are the main processes redusing reservoir quality. Dissolution process with generating secondary porosity consists of vuggy and moldic, has important effect on increasing of porosity. Most of the dissolution features have been produced during the meteoric diagenesis and less through burial diagenesis. Dissolution process with develop the vuggy pores caused to connect them in some case and also affected on fractures , stylolites and previous diagenetic cements in upper and lower members of daryian formation which eventually has been increased permeability and reservoir quality. Also, Fracturing, the main other diagenetic process with connect the some individual vuggy and moldic pores together has effective role to increase the permeability and reservoir quality in upper and lower parts of Dariyan formation. Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Investigation of geology, petrology and petrogenesis of igneous rocks from the Mahour Mining exploration area, west Dehsalm: Implication for Lut tectonomagmatic settingInvestigation of geology, petrology and petrogenesis of igneous rocks from the Mahour Mining exploration area, west Dehsalm: Implication for Lut tectonomagmatic setting1791984073310.22071/gsj.2016.40733FAS YounesiPh.D. Student, Department of Earth Sciences, Faculty of Natural Sciences, University of Tabriz, Tabriz, IranM.R HosseinzadehAssociate Professor, Department of Earth Sciences, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iran0000-0002-6319-5840M MoayyedProfessor, Department of Earth Sciences, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iranorcid 0000-0002-7600A MaghsoudiAssistant Professor, Department of Mining and Metallurgy Engineering, Amirkabir University of Technology, Tehran, IranJournal Article20160411The study area is located at the center of the Lut area and the southern part of the Eocene- Oligocene Lut volcano-plutonic belt. The main exposed igneous rocks include widespread and thick units of Middle Eocene volcanic (basaltic andesite, andesiteand trachy-andesite) and Eocene-Oligocene volcanic-subvolcanic (dacite and rhyodacite) with related tuffs, intruded by microdioritic stock and dykes of Oligocene with gabbrodiorite to quartzdiorite compositions. Texture is dominantly porphyritic and the main minerals are plagioclase, clinopyroxene, hornblende, K-feldspar, quartz and minor amounts of biotite with apatite, zircon, rutile and opaque minerals as accessory phases. These rocks with predominant K-high calc-alkaline to shoshonitic affinities, are I type and metaluminous and are characterized by LILE, LREE and Th enrichment relative to HFSE, depletion in Nb,Ti,Ta and weak depletion in HREE and Y. These features are characteristic of the post-collisional calc-alkaline rocks along with a continental active margin tectonic setting. In spite of the low ratios of Nb/U, Nb/La and Ce/Pb, the Sm/Yb (1.6-2.1) ratio reveals low contamination of magmas with relatively thin crust which is in accordance with low crustal thickness in this area (36-38Km). According to geochemistry of trace elements and REEs, the main cause of magmatism in Mahour was melting of a metasomatized lithospheric mantle (E-MORB like) with spinel lherzolite composition accompanied by very small amount of garnet in the presence of phlogopite. On the basis of the phenocrysts assemblage, REE pattern with negative Eu anomaly (Eu/Eu*= 0.63- 0.9) and also La/Yb calibration to crustal thickness, magmas have undergone relatively dry crystallization in the magma chamber at shallow depths (The study area is located at the center of the Lut area and the southern part of the Eocene- Oligocene Lut volcano-plutonic belt. The main exposed igneous rocks include widespread and thick units of Middle Eocene volcanic (basaltic andesite, andesiteand trachy-andesite) and Eocene-Oligocene volcanic-subvolcanic (dacite and rhyodacite) with related tuffs, intruded by microdioritic stock and dykes of Oligocene with gabbrodiorite to quartzdiorite compositions. Texture is dominantly porphyritic and the main minerals are plagioclase, clinopyroxene, hornblende, K-feldspar, quartz and minor amounts of biotite with apatite, zircon, rutile and opaque minerals as accessory phases. These rocks with predominant K-high calc-alkaline to shoshonitic affinities, are I type and metaluminous and are characterized by LILE, LREE and Th enrichment relative to HFSE, depletion in Nb,Ti,Ta and weak depletion in HREE and Y. These features are characteristic of the post-collisional calc-alkaline rocks along with a continental active margin tectonic setting. In spite of the low ratios of Nb/U, Nb/La and Ce/Pb, the Sm/Yb (1.6-2.1) ratio reveals low contamination of magmas with relatively thin crust which is in accordance with low crustal thickness in this area (36-38Km). According to geochemistry of trace elements and REEs, the main cause of magmatism in Mahour was melting of a metasomatized lithospheric mantle (E-MORB like) with spinel lherzolite composition accompanied by very small amount of garnet in the presence of phlogopite. On the basis of the phenocrysts assemblage, REE pattern with negative Eu anomaly (Eu/Eu*= 0.63- 0.9) and also La/Yb calibration to crustal thickness, magmas have undergone relatively dry crystallization in the magma chamber at shallow depths (Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Calcareous nannofossil biostratigraphy of Sarcheshmeh and Sanganeh formations at Qaleh Zoo section (North-West of Shirvan)Calcareous nannofossil biostratigraphy of Sarcheshmeh and Sanganeh formations at Qaleh Zoo section (North-West of Shirvan)1992084073810.22071/gsj.2016.40738FAA Gholami FardPh.D. Student, Faculty of Earth Science, Shahid Beheshti University, Tehran, IranA KaniAssociate Professor, Faculty of Earth Science, Shahid Beheshti University, Tehran, IranA MahanipourAssistant Professor, Faculty of Science, Geology group, Shahid Bahonar University, Kerman, IranJournal Article20151020This study investigates the Lower Cretaceous sedimentary succession comprising Sarcheshmeh Formation and Sanganeh Formation in the Ghaleh zoo Section from the standpoint of Calcareous Nannofossils. The results reveals presence of 60 species from 33 genera of 15 families. Based on the index nannofossil taxa, the upper part of NC6, NC7A, NC7(B&C) and NC8(A&B) nannofossil zones (equivalent to the upper part of of CC7a, CC7b and CC8 zones), are present in this section. The calcareous nannofossils found in this section point to an Early Aptian to Late Aptian age of deposition for the rocks of Sarcheshmeh Formation and Late Aptian to Early Albian for the rocks of Sanganeh Formation. <br /> This study investigates the Lower Cretaceous sedimentary succession comprising Sarcheshmeh Formation and Sanganeh Formation in the Ghaleh zoo Section from the standpoint of Calcareous Nannofossils. The results reveals presence of 60 species from 33 genera of 15 families. Based on the index nannofossil taxa, the upper part of NC6, NC7A, NC7(B&C) and NC8(A&B) nannofossil zones (equivalent to the upper part of of CC7a, CC7b and CC8 zones), are present in this section. The calcareous nannofossils found in this section point to an Early Aptian to Late Aptian age of deposition for the rocks of Sarcheshmeh Formation and Late Aptian to Early Albian for the rocks of Sanganeh Formation. <br /> Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Geochemistry, petrogenesis and tectonic setting of the Sarcheshmeh Eocene mafic lava flows, Southwest of RafsanjanGeochemistry, petrogenesis and tectonic setting of the Sarcheshmeh Eocene mafic lava flows, Southwest of Rafsanjan2092204226410.22071/gsj.2016.42264FAS.Z HosseiniAssistant Professor, Department of Geology, Payam Noor University, IranJournal Article20150829The Eocene mafic lava flows of Sarcheshmehare cropped out in the southwest of Rafsanjan area at the central part of the Urmia – Dokhtar magmatic belt. The rocks are basalt, basaltic andesite and andesite in composition and consist of clinopyroxene + plagioclase ± olivine ± hornblende phenocrysts. The geochemical characteristics show calc-alkaline nature for the lavas that are formed in an active continental margin tectonic environment. Low amounts of MgO, Cr and Ni in the Sarcheshmeh Eocene basaltic lavas points to the role of evolution in their parental magma. The MORB normalized multi-element patterns of the lava flows show enrichment in LILE (e.g. Sr, K, Rb and Ba) and depletion in HFSE (e.g. Ta, Nb and Ti). The Chondrite-normalized REE patterns show moderate enrichments in LREE with (La/Yb)<sub>n</sub>< 3 for all samples. The geochemical features such as (La/Yb)<sub>n</sub>The Eocene mafic lava flows of Sarcheshmehare cropped out in the southwest of Rafsanjan area at the central part of the Urmia – Dokhtar magmatic belt. The rocks are basalt, basaltic andesite and andesite in composition and consist of clinopyroxene + plagioclase ± olivine ± hornblende phenocrysts. The geochemical characteristics show calc-alkaline nature for the lavas that are formed in an active continental margin tectonic environment. Low amounts of MgO, Cr and Ni in the Sarcheshmeh Eocene basaltic lavas points to the role of evolution in their parental magma. The MORB normalized multi-element patterns of the lava flows show enrichment in LILE (e.g. Sr, K, Rb and Ba) and depletion in HFSE (e.g. Ta, Nb and Ti). The Chondrite-normalized REE patterns show moderate enrichments in LREE with (La/Yb)<sub>n</sub>< 3 for all samples. The geochemical features such as (La/Yb)<sub>n</sub>Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Investigation of geochemical characteristics of Sarvak Formation of the Persian Gulf in Block DInvestigation of geochemical characteristics of Sarvak Formation of the Persian Gulf in Block D2212344074310.22071/gsj.2016.40743FAN Mohammadi AkbariScience and Research Branch, Islamic Azad University, Tehran, Iran.M.R KamaliResearch Institute of Petroleum Industry of Iran (RIPI).Journal Article20150615Sarvak Formation (with the age span of Cretaceous) is considered as one of the most prominent oil reservoirs in the south of Iran and a significant volume of oil accumulation in the Persian Gulf basin is attributed to this formation. In the present research plan, in order to evaluate the hydrocarbon generation capacity of this formation, cores, cuttings and oil samples collected from fields’ wells located in block D underwent some investigations which were in the Iranian sector of the Persian Gulf. Correlation is defined as the geochemical comparison between hydrocarbons themselves, or also hydrocarbons with source rocks, and furthermore defining the quality of the genetic relation between them. In order to achieve this goal a variety of gadgets and parameters are used, some of them being biomarkers and stable isotopes.
The results obtained from geochemical analyses including primary analyses (pyrolysis rock-eval), bitumen extraction and separation, complementary analyses (gas chromatography), gas chromatography-mass spectrometry and stable isotope studies on samples indicate that kerogen of studied samples is a combination of types II and III and it implies that most organic matter generating hydrocarbon were formed in a marine environment along with a little entering from land. The hydrocarbons existing in Sarvak Formation were generated from a semi carbonated clastic source rock and were sedimented under a reduced or semi-reduced environment. The saturate sections of the Chromatograms samples indicate the lack of environmental biodegradation in the studied samples. The Oil and inter bed shaly-marl samples of the Sarvak Formation show a fair to good hydrocarbon potential. The set of under study samples are located in the beginning of the oil generation window (late diagenesis) and early catagenesis in terms of their maturity degree. Furthermore, hydrocarbons show a paraffinic-naphthenic characteristic. It seems the shaly-marl layers existing in some parts of the Sarvak Formation (Ahmadi member), in Block D, in the Persian Gulf, have been the cause for the generation of hydrocarbons available in the Sarvak reservoir.Sarvak Formation (with the age span of Cretaceous) is considered as one of the most prominent oil reservoirs in the south of Iran and a significant volume of oil accumulation in the Persian Gulf basin is attributed to this formation. In the present research plan, in order to evaluate the hydrocarbon generation capacity of this formation, cores, cuttings and oil samples collected from fields’ wells located in block D underwent some investigations which were in the Iranian sector of the Persian Gulf. Correlation is defined as the geochemical comparison between hydrocarbons themselves, or also hydrocarbons with source rocks, and furthermore defining the quality of the genetic relation between them. In order to achieve this goal a variety of gadgets and parameters are used, some of them being biomarkers and stable isotopes.
The results obtained from geochemical analyses including primary analyses (pyrolysis rock-eval), bitumen extraction and separation, complementary analyses (gas chromatography), gas chromatography-mass spectrometry and stable isotope studies on samples indicate that kerogen of studied samples is a combination of types II and III and it implies that most organic matter generating hydrocarbon were formed in a marine environment along with a little entering from land. The hydrocarbons existing in Sarvak Formation were generated from a semi carbonated clastic source rock and were sedimented under a reduced or semi-reduced environment. The saturate sections of the Chromatograms samples indicate the lack of environmental biodegradation in the studied samples. The Oil and inter bed shaly-marl samples of the Sarvak Formation show a fair to good hydrocarbon potential. The set of under study samples are located in the beginning of the oil generation window (late diagenesis) and early catagenesis in terms of their maturity degree. Furthermore, hydrocarbons show a paraffinic-naphthenic characteristic. It seems the shaly-marl layers existing in some parts of the Sarvak Formation (Ahmadi member), in Block D, in the Persian Gulf, have been the cause for the generation of hydrocarbons available in the Sarvak reservoir.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Geochemistry of intrusive rocks, petrology of skarn, and mineralogy and chemistry of orebodies in Senjedak-I area, east of Sangan mine, Khaf, NE IranGeochemistry of intrusive rocks, petrology of skarn, and mineralogy and chemistry of orebodies in Senjedak-I area, east of Sangan mine, Khaf, NE Iran2352464074410.22071/gsj.2016.40744FAN MazhariPh.D. Student, Department of Geology, Ferdowsi University of Mashhad, Mashhad, IranA Malekzadeh ShafaroudiAssociate Professor, Department of Geology, Ferdowsi University of Mashhad, Mashhad, IranM Ghaderi- Associate Professor, Department of Economic Geology, Tarbiat Modares University, Tehran, Iran0000-0002-6156-7516Journal Article20150906The Senjedak-I prospect area is one of the six eastern anomalies of Sangan iron mine. Geologic units in the area consist of Jurassic shales and sandstones, skarn rocks and Tertiary biotite monzonite and biotite syenogranite intrusive rocks. Due to the severe alteration of biotite monzonite porphyry intrusive, geochemical studies have focused on the biotite syenogranite.
This granular intrusive consists of alkali feldspar, plagioclase, quartz, biotite and accessory minerals such as zircon, sphene, apatite and magnetite, with weak sericitic, argillic and silicic alteration. Biotite syenogranite rock is rich in silica (68.7 to 77.2 wt.%) and is chemically peraluminous and has generated by fractional crystallization from an I-type granitic magma poor in P (average 0.1% P<sub>2</sub>O<sub>5</sub>). This intrusive rock falls in the range of I-type granites and is oxidized. REE values indicate negative Eu anomaly, mild enrichment of LREE, a positive pattern close to flat HREE, negative anomalies of Ba, Sr, La, Ce, Ti, and Eu. On the basis of Rb, Nb, Yb, Hf, and Ta, tectonic setting of samples fall in Volcanic Arc Granite (VAG) and Post Collision Granite (post-COLG) divisions.
The most important event in Senjedak-I area is the penetration of Fe-bearing fluids in carbonate rocks, their recrystallization, skarnification (prograde and retrograde), and iron ore deposition that could be explained by the occurrence of calc-silicate minerals.
The skarn has been separated into 4 zones on the basis of abundance of the calc-silicates: garnet skarn, phlogopite skarn, epidote skarn, and amphibole skarn.
According to Electron Probe Micro Analysis (EPMA), the composition of garnets is andradite-grossular (An 100-42.6 Gr 0-55.32 Sps 0-1.39) and pyroxenes are diopside-hedenbergite (Di 63-92 Hd 4-35 Jo 0.5-3.9).
Mineralization in this prospect area formed as stratabound and massive bodies in the carbonate rocks. The main ore mineral is magnetite (40%) with minor amounts of pyrite. Secondary minerals are hematite and malachite. The FeO in the magnetite is 91.7% and the S content is 0.03%. The Senjedak-I anomaly places along the eastern part of Dardvay deposit (in central division of Sangan mine) and the geochemical similarities of intrusive rocks, chemistry of skarn minerals, and pyroxene and garnet composition confirms that the Senjedak-I is a part of Dardvay, which is separated by a main fault with southeast-northwest trend.The Senjedak-I prospect area is one of the six eastern anomalies of Sangan iron mine. Geologic units in the area consist of Jurassic shales and sandstones, skarn rocks and Tertiary biotite monzonite and biotite syenogranite intrusive rocks. Due to the severe alteration of biotite monzonite porphyry intrusive, geochemical studies have focused on the biotite syenogranite.
This granular intrusive consists of alkali feldspar, plagioclase, quartz, biotite and accessory minerals such as zircon, sphene, apatite and magnetite, with weak sericitic, argillic and silicic alteration. Biotite syenogranite rock is rich in silica (68.7 to 77.2 wt.%) and is chemically peraluminous and has generated by fractional crystallization from an I-type granitic magma poor in P (average 0.1% P<sub>2</sub>O<sub>5</sub>). This intrusive rock falls in the range of I-type granites and is oxidized. REE values indicate negative Eu anomaly, mild enrichment of LREE, a positive pattern close to flat HREE, negative anomalies of Ba, Sr, La, Ce, Ti, and Eu. On the basis of Rb, Nb, Yb, Hf, and Ta, tectonic setting of samples fall in Volcanic Arc Granite (VAG) and Post Collision Granite (post-COLG) divisions.
The most important event in Senjedak-I area is the penetration of Fe-bearing fluids in carbonate rocks, their recrystallization, skarnification (prograde and retrograde), and iron ore deposition that could be explained by the occurrence of calc-silicate minerals.
The skarn has been separated into 4 zones on the basis of abundance of the calc-silicates: garnet skarn, phlogopite skarn, epidote skarn, and amphibole skarn.
According to Electron Probe Micro Analysis (EPMA), the composition of garnets is andradite-grossular (An 100-42.6 Gr 0-55.32 Sps 0-1.39) and pyroxenes are diopside-hedenbergite (Di 63-92 Hd 4-35 Jo 0.5-3.9).
Mineralization in this prospect area formed as stratabound and massive bodies in the carbonate rocks. The main ore mineral is magnetite (40%) with minor amounts of pyrite. Secondary minerals are hematite and malachite. The FeO in the magnetite is 91.7% and the S content is 0.03%. The Senjedak-I anomaly places along the eastern part of Dardvay deposit (in central division of Sangan mine) and the geochemical similarities of intrusive rocks, chemistry of skarn minerals, and pyroxene and garnet composition confirms that the Senjedak-I is a part of Dardvay, which is separated by a main fault with southeast-northwest trend.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Electrical Resistivity and Induced Polarization Data Correlation for Copper Exploration and Associated Elements in Sahebdivan Area, MeshkinshahrElectrical Resistivity and Induced Polarization Data Correlation for Copper Exploration and Associated Elements in Sahebdivan Area, Meshkinshahr2472584075010.22071/gsj.2016.40750FAM.J Mohammadzadeh-Associate Professor, Faculty of Mining Engineering, Sahand University of Technology, Tabriz, IranA NasseriAssistant Professor, Department of Mining Engineering, Islamic Azad University –Ahar Branch, Ahar, IranS AnsariPh.D student, Faculty of Mining Engineering, Sahand university of Technology, Tabriz, Iran.Journal Article20150630Sahebdivan area is located at 20.km of Meshkinshahr in Ardebil province. The study area is comprises of volcanic rocks and intrusive masses consisting of quartz monzonite and granite along with several vast epithermal alterations. The main objective of this paper is to recognize the present alteration zones indicating metal promising areas using geophysical methods such as induced polarization (IP) surveying and resistivity (RS) in order to assess the presence of minerals and delineate the subsurface masses at depth. Therefore, IP<em>/</em>resistivity survey was carried out based on rectangular array in the area and their corresponding maps were prepared. Accordingly, their promising anomalous zones for mineralization were initially detected. Furthermore, a new IP survey was attempted based on a dipole-dipole electrode array for detailed potential mapping.
Considering IP/RS pseudo-sections, the position, depth, intensity and extent of mineralization was defined. Correlating the anomalous zones obtained from geophysical results with Lithology and alteration zones in the area indicate Cu mineralization along E-W trend in Sahebdivan which is associated with increase in chargeability and reduction in resistivity. Furthermore topographic corrections were attempted resulting in anomalous halos enhancement. Discriminating the important alteration zones in the area were carried out based on chargeability variations where higher chargeability indicate phyllic alteration with pyrite and in contrast the Potassic alteration with low chargeability that coincide with igneous intrusive.
It can be deduced from this study that the porphyry micro quartz monzonite - micro quartz diorite generator fluids was recognized as source of mineralization along with surrounding andesite–dacite andesite as source of the anomalous zones in Sahebdivan area. Summing all the evidences from field studies and their compliance with geophysical results, Lithology, alterations and ultimately considering the susceptible mineralization zones, the optimal drilling points was proposed with priority of SABH-1 according to the Potassic zone in terms of potential copper mineralization.Sahebdivan area is located at 20.km of Meshkinshahr in Ardebil province. The study area is comprises of volcanic rocks and intrusive masses consisting of quartz monzonite and granite along with several vast epithermal alterations. The main objective of this paper is to recognize the present alteration zones indicating metal promising areas using geophysical methods such as induced polarization (IP) surveying and resistivity (RS) in order to assess the presence of minerals and delineate the subsurface masses at depth. Therefore, IP<em>/</em>resistivity survey was carried out based on rectangular array in the area and their corresponding maps were prepared. Accordingly, their promising anomalous zones for mineralization were initially detected. Furthermore, a new IP survey was attempted based on a dipole-dipole electrode array for detailed potential mapping.
Considering IP/RS pseudo-sections, the position, depth, intensity and extent of mineralization was defined. Correlating the anomalous zones obtained from geophysical results with Lithology and alteration zones in the area indicate Cu mineralization along E-W trend in Sahebdivan which is associated with increase in chargeability and reduction in resistivity. Furthermore topographic corrections were attempted resulting in anomalous halos enhancement. Discriminating the important alteration zones in the area were carried out based on chargeability variations where higher chargeability indicate phyllic alteration with pyrite and in contrast the Potassic alteration with low chargeability that coincide with igneous intrusive.
It can be deduced from this study that the porphyry micro quartz monzonite - micro quartz diorite generator fluids was recognized as source of mineralization along with surrounding andesite–dacite andesite as source of the anomalous zones in Sahebdivan area. Summing all the evidences from field studies and their compliance with geophysical results, Lithology, alterations and ultimately considering the susceptible mineralization zones, the optimal drilling points was proposed with priority of SABH-1 according to the Potassic zone in terms of potential copper mineralization.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Investigation on type and origin of copper mineralization at Aliabad Mousavi- Khanchy occurrence, east of Zanjan, using petrological, mineralogical and geochemical data
Mir Ali Asghar Mokhtari, Hossein Kouhestani*, Arefeh SaeediInvestigation on type and origin of copper mineralization at Aliabad Mousavi- Khanchy occurrence, east of Zanjan, using petrological, mineralogical and geochemical data
Mir Ali Asghar Mokhtari, Hossein Kouhestani*, Arefeh Saeedi2592704075610.22071/gsj.2016.40756FAM.A.A MokhtariDepartment of Geology, University of Zanjan, Zanjan, IranH KouhestaniDepartment of Geology, University of Zanjan, Zanjan, IranA SaeediDepartment of Geology, University of Zanjan, Zanjan, IranJournal Article20150727Aliabad Mousavi- Khanchy Cu occurrence is located in the Tarom area, 30 km east of Zanjan. Rock units exposed in this area consist of Eocene volcanic and volcano-sedimentary units (equal to Karaj Formation) which are intruded by Oligocene quartz-monzonitic plutons. In this area, Cu mineralization occurs as Cu-bearing quartz veins and veinlets within the intermediate tuffs and andesitic lavas. Based on microscopic studies, ore minerals are include chalcopyrite with minor pyrite and oligist, and quartz and chlorite are present as gangue minerals at the Aliabad Mousavi- Khanchy Cu occurrence. The ore minerals show disseminated, vein and veinlets, breccia, open space filling and replacement textures. Alteration is restricted to the silicified and chloritic altered parts of the ore zones. Two stages of hypogene and supergene mineralization can be distinguished at the Aliabad Mousavi- Khanchy Cu occurrence. The hypogene stage of mineralization is progressed from disseminated crystals of pyrite and chalcopyrite within the tuffs and lavas (substage 1) to quartz- chalcopyrite- pyrite‒cemented veins and breccias (substage 2), individual or sets of quartz veins and veinlets (substage 3) and finally quartz- oligist veins and veinlets (substage 4). Malachite, azurite and Fe-hydroxides with veins and veinlets and open space filling textures are formed during supergene stage. REE pattern of the host rocks and the mineralized samples indicate that mineralized samples are enriched in REE. This signature may indicates high concentration of REE in ore-forming fluids and/or high W/R interaction at Aliabad Mousavi- Khanchy area. Enrichment of ore-forming elements (Cu, Pb, Zn) in ore zones is also specifies leaching of elements from altered host rocks to ore zones by ore-forming fluids. Characteristics of Aliabad Mousavi- Khanchy Cu occurrence are comparable with vein type of Cu deposits.Aliabad Mousavi- Khanchy Cu occurrence is located in the Tarom area, 30 km east of Zanjan. Rock units exposed in this area consist of Eocene volcanic and volcano-sedimentary units (equal to Karaj Formation) which are intruded by Oligocene quartz-monzonitic plutons. In this area, Cu mineralization occurs as Cu-bearing quartz veins and veinlets within the intermediate tuffs and andesitic lavas. Based on microscopic studies, ore minerals are include chalcopyrite with minor pyrite and oligist, and quartz and chlorite are present as gangue minerals at the Aliabad Mousavi- Khanchy Cu occurrence. The ore minerals show disseminated, vein and veinlets, breccia, open space filling and replacement textures. Alteration is restricted to the silicified and chloritic altered parts of the ore zones. Two stages of hypogene and supergene mineralization can be distinguished at the Aliabad Mousavi- Khanchy Cu occurrence. The hypogene stage of mineralization is progressed from disseminated crystals of pyrite and chalcopyrite within the tuffs and lavas (substage 1) to quartz- chalcopyrite- pyrite‒cemented veins and breccias (substage 2), individual or sets of quartz veins and veinlets (substage 3) and finally quartz- oligist veins and veinlets (substage 4). Malachite, azurite and Fe-hydroxides with veins and veinlets and open space filling textures are formed during supergene stage. REE pattern of the host rocks and the mineralized samples indicate that mineralized samples are enriched in REE. This signature may indicates high concentration of REE in ore-forming fluids and/or high W/R interaction at Aliabad Mousavi- Khanchy area. Enrichment of ore-forming elements (Cu, Pb, Zn) in ore zones is also specifies leaching of elements from altered host rocks to ore zones by ore-forming fluids. Characteristics of Aliabad Mousavi- Khanchy Cu occurrence are comparable with vein type of Cu deposits.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Determination of Coda Wave quality factor in the north-west of the Iranian plateauDetermination of Coda Wave quality factor in the north-west of the Iranian plateau2712804075710.22071/gsj.2016.40757FAM NaghaviPhD. Student, Earth Physics Department, Institute of Geophysics, University of Tehran, Tehran, IranH RahimiAssistant Professor, Earth Physics Department, Institute of Geophysics, University of Tehran, Tehran, IranA MoradiAssistant Professor, Earth Physics Department, Institute of Geophysics, University of Tehran, Tehran, IranJournal Article20150831The energy of a seismic wave decays while passing through a “real” medium such as the earth which is not completely elastic. Scattering and attenuation of high-frequency seismic waves are substantial parameters to quantify and to physically characterize the earth medium and from which useful information on medium properties can be inferred. The coda waves in seismograms are one of the most prominent observations supporting the existence random heterogeneities in the earth. Determination of source parameters must take into account the proper attenuation characteristic of the wave path. Moreover, it is essential for seismic risk studies and seismic hazard assessment, and consequently for seismic risk mitigation and engineering seismology. Many researchers used coda waves from small earthquakes to determine local attenuation properties of the crust.
The S-coda has a common amplitude decay curve for lapse time greater than the twice the S-wave travel time. The shape of this decay curve is quantified by using a parameter knows coda attenuation Qc<sup>-1</sup>. The time domain coda decay method of a single back scattering model is employed to estimate frequency dependence of the quality factor of coda waves modeled using, where is the coda quality factor at frequency of 1 Hz and is the frequency parameter.
The purpose of this study is to determine the coda quality factors from recorded events at 17 stations in the NW of Iranian plateau, using the single backscattering method (Aki and Chouet 1975). Scattering models have been developed in order to infer physical properties of the lithosphere from observations of seismic codas.
In this study, the coda quality factors of seismic waves have been estimated by using local earthquakes with recorded in NW of Iranian plateau. This region includes major faults such North Tabriz Fault and two volcanoes (Sahand and Sabalan) and many thermal units.
The data used in this study consists more than 13000 earthquakes and 26724 high-quality waveform recorded by Iranian National Seismic Network (INSN) and Iranian Seismological Center (IRSC) stations to estimate lateral variations of coda wave quality factor. By using these data set, Qc and its frequency dependency were estimated, in NW of Iranian plateau.
We also investigated lateral and depth variation of Qc in this region. The average frequency relations for NW of Iranian plateau and around North Tabriz Fault (NTF) are , and, respectively. These values show this region is very active region tectonically and seismically. To investigate the attenuation variation with depth, Qc value was calculated for 18 lapse-times (5, 10, 15, 90s) for two data sets comprising epicentral distance range R < 100 km (data set 1) and 100 < R < 200 km (data set 2). As the quality factor is related to the heat flow, as the mechanisms show, it decrease with increasing temperature, because active region greater absorption than stable region. We should note that in this study the results, are taken as mean values of each propagation-path. It is observed that generally with increasing coda wave lapse-time, Q0 (quality factor at 1 Hz) and n (frequency dependence factor) values show increasing and decreasing trend, respectively.
Determinations of and n in the attenuation relationships for different tectonic regions, have been the focus of many studies. Both these parameters appear to represent the level of tectonic activity of a seismic region. According to the results, we observed well correlation between reported lithosphere thickness and trends of and n in longer lapse-times (larger depths). The lateral variation of correlates well with the large scale tectonic units of the studied area. According to the results obtained in this study NTF, Sahand volcano and its surrounding regions are characterized by relatively low and a high gradient of can be observed in the region. Furthermore NW Iran is a region of significant geothermal activity and anomalously high crustal temperatures. These geothermal activities result in smaller values for quality factor and higher attenuation of seismic waves. Such of the and n variations can be attributed to variability in the depth and severity of the crustal velocity gradient.The energy of a seismic wave decays while passing through a “real” medium such as the earth which is not completely elastic. Scattering and attenuation of high-frequency seismic waves are substantial parameters to quantify and to physically characterize the earth medium and from which useful information on medium properties can be inferred. The coda waves in seismograms are one of the most prominent observations supporting the existence random heterogeneities in the earth. Determination of source parameters must take into account the proper attenuation characteristic of the wave path. Moreover, it is essential for seismic risk studies and seismic hazard assessment, and consequently for seismic risk mitigation and engineering seismology. Many researchers used coda waves from small earthquakes to determine local attenuation properties of the crust.
The S-coda has a common amplitude decay curve for lapse time greater than the twice the S-wave travel time. The shape of this decay curve is quantified by using a parameter knows coda attenuation Qc<sup>-1</sup>. The time domain coda decay method of a single back scattering model is employed to estimate frequency dependence of the quality factor of coda waves modeled using, where is the coda quality factor at frequency of 1 Hz and is the frequency parameter.
The purpose of this study is to determine the coda quality factors from recorded events at 17 stations in the NW of Iranian plateau, using the single backscattering method (Aki and Chouet 1975). Scattering models have been developed in order to infer physical properties of the lithosphere from observations of seismic codas.
In this study, the coda quality factors of seismic waves have been estimated by using local earthquakes with recorded in NW of Iranian plateau. This region includes major faults such North Tabriz Fault and two volcanoes (Sahand and Sabalan) and many thermal units.
The data used in this study consists more than 13000 earthquakes and 26724 high-quality waveform recorded by Iranian National Seismic Network (INSN) and Iranian Seismological Center (IRSC) stations to estimate lateral variations of coda wave quality factor. By using these data set, Qc and its frequency dependency were estimated, in NW of Iranian plateau.
We also investigated lateral and depth variation of Qc in this region. The average frequency relations for NW of Iranian plateau and around North Tabriz Fault (NTF) are , and, respectively. These values show this region is very active region tectonically and seismically. To investigate the attenuation variation with depth, Qc value was calculated for 18 lapse-times (5, 10, 15, 90s) for two data sets comprising epicentral distance range R < 100 km (data set 1) and 100 < R < 200 km (data set 2). As the quality factor is related to the heat flow, as the mechanisms show, it decrease with increasing temperature, because active region greater absorption than stable region. We should note that in this study the results, are taken as mean values of each propagation-path. It is observed that generally with increasing coda wave lapse-time, Q0 (quality factor at 1 Hz) and n (frequency dependence factor) values show increasing and decreasing trend, respectively.
Determinations of and n in the attenuation relationships for different tectonic regions, have been the focus of many studies. Both these parameters appear to represent the level of tectonic activity of a seismic region. According to the results, we observed well correlation between reported lithosphere thickness and trends of and n in longer lapse-times (larger depths). The lateral variation of correlates well with the large scale tectonic units of the studied area. According to the results obtained in this study NTF, Sahand volcano and its surrounding regions are characterized by relatively low and a high gradient of can be observed in the region. Furthermore NW Iran is a region of significant geothermal activity and anomalously high crustal temperatures. These geothermal activities result in smaller values for quality factor and higher attenuation of seismic waves. Such of the and n variations can be attributed to variability in the depth and severity of the crustal velocity gradient.Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Microfacies, depositional model and sequence stratigraphy of Dariyan
Formation in northern high Zagros faultMicrofacies, depositional model and sequence stratigraphy of Dariyan
Formation in northern high Zagros fault2812904076210.22071/gsj.2016.40762FAM YavariPh.D student, Department of Geology, University of Isfahan, Isfahan, IranM YazdiProfessor, Department of Geology, University of Isfahan, Isfahan, IranM.H AdabiProfessor, Department of Geology, Faculty of Earth Sciences, Shahid Beheshti University, Tehran IranH Ghalavand4Manager, Exploration Directorate of the National Iranian Oil Company, 1st Dead end, Sheikh Bahaee Sq., Seoul Ave., P.O.Box 19395–6669, Tehran, IranJournal Article20151007Dariyan Formation deposited in two different sedimentary settings. In some places it consists of shallow Limestone with algae and Orbitolina and in the other places in addition to limestone, it represents black shales and marls associated with planktonic foraminifera and radiolarian. In this research Draiyan Formation was studied in order to microfacies, depositional model and sequences stratigraphy of two sections so called, Kuh-e Gadvan and Kuh-e Banesh in high Zagros belt. Detailed petrographic studies led to the recognition of five main facies belts including: lagoon, bar, shallow open marine, outer ramp and deep marine. According to the vertical and lateral variations of facies, the Dariyan Formation deposited on a carbonate ramp platform and intrashelf basin. Depositional sequences have been presented on the basis of analysis of facies, fauna assemblages, Gama and Neutron logs. Three 3rd orders depositional sequences have been recognized during deposition of sediments. There is Type I sequence boundary in the top of third sequence and the other two sequences was considered as Type II sequence. Sea level fluctuations of the studied area correlated with Arabian platform and these changes follow of regional factors. <br /> Dariyan Formation deposited in two different sedimentary settings. In some places it consists of shallow Limestone with algae and Orbitolina and in the other places in addition to limestone, it represents black shales and marls associated with planktonic foraminifera and radiolarian. In this research Draiyan Formation was studied in order to microfacies, depositional model and sequences stratigraphy of two sections so called, Kuh-e Gadvan and Kuh-e Banesh in high Zagros belt. Detailed petrographic studies led to the recognition of five main facies belts including: lagoon, bar, shallow open marine, outer ramp and deep marine. According to the vertical and lateral variations of facies, the Dariyan Formation deposited on a carbonate ramp platform and intrashelf basin. Depositional sequences have been presented on the basis of analysis of facies, fauna assemblages, Gama and Neutron logs. Three 3rd orders depositional sequences have been recognized during deposition of sediments. There is Type I sequence boundary in the top of third sequence and the other two sequences was considered as Type II sequence. Sea level fluctuations of the studied area correlated with Arabian platform and these changes follow of regional factors. <br /> Geological Survey of IranScientific Quarterly Journal of Geosciences1023-74292510020160901Geochemistry and Tectonic setting of high silica adakitic domes
Of Ahmad Abad Khartouran (South East of Shahrood)Geochemistry and Tectonic setting of high silica adakitic domes
Of Ahmad Abad Khartouran (South East of Shahrood)2912984076310.22071/gsj.2016.40763FAF YousefiPhD Student of petrology, Department of Petrology and Economic Geology, Faculty of Earth Sciences, Shahrood University of Technology, Shahrood, Iran.M SadeghianAssociate Professor, Department of Petrology and Economic Geology, Faculty of Earth Sciences, Shahrood University of Technology, Shahrood, Iran.S SamyariM.Sc Student, Department of Petrology and Economic Geology, Faculty of Earth Sciences, Shahrood University of Technology, Shahrood, IranH GhasemiProfessor, Department of Petrology and Economic Geology, Faculty of Earth Sciences, Shahrood University of Technology, Shahrood, Iran.0000000154469961Journal Article20150929In Ahmadabad Khartouran region located in 175 Km southeast of Shahrood, A significant number of adakitic domes crop out, which intruded into the Paleocene- Eocene volcanosedimentary rocks. Lithological compositions of these domes include andesite, trachyandesite, trachyandesite and dacite. Pyroxene (augite), green hornblende and plagioclase are typical mafic and felsic rock forming minerals. With respect to low HREE and high LREE along with other characteristic such as silica content (58.91- 63.41), Na<sub>2</sub>O more than 3%, Al<sub>2</sub>O<sub>3</sub> more than16%, Yb less than 1.8 ppm, Y less than 18 ppm and K<sub>2</sub>O/Na<sub>2</sub>O ratio between .98- 2.3, these rocks can be classified as the high silica adakite. Enrichment of LREE relative to the HREE and depletion of Nb, Ti, and high concentration of Rb, Ba, K and Th, which imply crustal contamination of the mentioned adakitic domes. Enclaves with different size and composition have been seen in these domes which indicate contamination and magma mixing with continental crust. The evidence of petrographic and geochemical show that the magma forming of these rocks originated from melting of subducted metamorphosed Neotethys oceanic slab (Sabzevar – Darouneh branch) in P-T conditions of amphibolite facies. In Ahmadabad Khartouran region located in 175 Km southeast of Shahrood, A significant number of adakitic domes crop out, which intruded into the Paleocene- Eocene volcanosedimentary rocks. Lithological compositions of these domes include andesite, trachyandesite, trachyandesite and dacite. Pyroxene (augite), green hornblende and plagioclase are typical mafic and felsic rock forming minerals. With respect to low HREE and high LREE along with other characteristic such as silica content (58.91- 63.41), Na<sub>2</sub>O more than 3%, Al<sub>2</sub>O<sub>3</sub> more than16%, Yb less than 1.8 ppm, Y less than 18 ppm and K<sub>2</sub>O/Na<sub>2</sub>O ratio between .98- 2.3, these rocks can be classified as the high silica adakite. Enrichment of LREE relative to the HREE and depletion of Nb, Ti, and high concentration of Rb, Ba, K and Th, which imply crustal contamination of the mentioned adakitic domes. Enclaves with different size and composition have been seen in these domes which indicate contamination and magma mixing with continental crust. The evidence of petrographic and geochemical show that the magma forming of these rocks originated from melting of subducted metamorphosed Neotethys oceanic slab (Sabzevar – Darouneh branch) in P-T conditions of amphibolite facies.