Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Mineralogy and origin of iron rich garnetites in Choogan area- North of Meimeh
3
12
FA
F.
ayati
Assistant Professor, Department of Geology, Payame Noor University, Iran
f.ayati@pnu.ac.ir
10.22071/gsj.2017.54125
In the studied area, the Cretaceous limestone rocks with abundant cracks are located on the Jurassic shales. Skarn producer fluids have influx into these cracks from a long distance and created distal skarns. The presence of a recrystallized and skarnified limestone rock layer within the shale, distinct the studied skarn from the most well-known skarns in Iran and puts it in the category of reaction skarns. There are some lenses of mineral deposites within skarns which is consisting mostly of magnetite and hematite. Iron-rich solutions which are drived from intrusive rocks, have left iron as magnetite in carbonate. In addition to the formation of magnetite by hydrothermal solutions, it can also be created in retrograde step by andradite alteration. These skarn is consisting mostly of pyroxene, garnet, tremolite-actinolite, chlorite and epidote. Skarnification process has occurred in two successive stages: progressive and regressive. In progressive stage, carbonate - silicate anhydrous minerals like garnet and pyroxene have occured. At later stages, because of the atmospheric water influence, garnets are altered to epidote, magnetite, calcite and quartz and pyroxenes are altered to tremolite, actinolite, calcite, quartz and opaque minerals. There are two set of garnet in studied skarn, the first one is massive (in progressive stage) and the other one is as veinlet (in regressive stage with epidote and has been created in quartz- calcit veins along with sulfide mineralization). Garnet compositions in iron deposits of studied area lie in grossular - andradite series. The compositions of studied garnet are the same as garnet compositions in Cu-Fe skarns in worldwide. <br /><strong> </strong>
Skarn,Garnetite,Magnetite,Meimeh,Urumieh-Dokhtar
http://www.gsjournal.ir/article_54125.html
http://www.gsjournal.ir/article_54125_1d7122fc9d9597d580ab0f8f670758ba.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Study on changing of stress Field and it,s role on deformation of Faraghan Structure in Eastern Zagros
13
24
FA
S. A.
Atapourfard
Ph.D. Student, Department of Geology, Tarbiat Modares University, Tehran, Iran
A.
Yassaghi
0000-0002-0984-7721
Associate Professor, Department of Geology, Tarbiat Modares University, Tehran, Iran
yassaghi@modares.ac.ir
M.
Rezaian
Assistant Professor, Department of Geology, Zanjan Advance Studies in Basic Science, Zanjan, Iran
E.
Shabanian
Assistant Professor, Department of Geology, Zanjan Advance Studies in Basic Science, Zanjan, Iran
10.22071/gsj.2017.54126
In the east of high Zagros – in Faraghan Anticline- sedimentary cover with more than 10 km thickness has decoupled from basement above the Hormuz salt and has deformed. Mention anticline is cut by High Zagros Fault. By attention to lack of paleostress study and kinematic interpretation on north east of Fars Arc structures, in this paper we reconstructed stress field and interoperated its role in evolution of Faraghan Anticline. Inversion method used for determination of reduced stress tensor parameters and discrimination faults of every brittle tectonic phase. Maximum shortening axis determined by using Stylolite's and attitude of Minimum main stress determined by using veins. The present stress field was calculated by inversion of earthquake focal mechanism data. According to our data and the deduced results, some of veins developed with an N27° - 29°E direction of σ1 stress axis before late of middle Miocene (before folding and faulting). During the late Miocene, sedimentary cover deformed as detachment and faults related folds in a general compressional stress regime with an N27° - 29°E direction of σ1. The basement faults were reactivated during late Miocene- early Pliocene in a general strike slip regime with an N4°E direction of σ1 stress axis. The High Zagros Fault was reactivated at that time and cross- cuts the entire cover section and its associated structures. In the late Pliocene, direction of σ1 stress axis temporally changed to N025°W in strike slip tectonic regime. Strike- slip and reverse faults were reactived in new stress field. Earthquakes Focal mechanism data analysis indicate that direction of σ1 stress axis is N-S now.
Faraghan Anticline,Inversion method of fault- slip data,Tension gashes,Stylolite,Focal mechanism data
http://www.gsjournal.ir/article_54126.html
http://www.gsjournal.ir/article_54126_afdd10c5cb3b18f7e7a0ecf64fa9cf66.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Microfacies analysis and depositional environments of the Asmari Formation at the Ghar-e Agha Seyyed section, Farsan area (Chaharmahal Bakhtiari province), High Zagros
25
32
FA
S. M.
Hamidzadeh
Ph.D. Student, Department of Geology, Faculty of Basic Science, Islamic Azad university, Science and Research Branch, Tehran, Iran
A.
Babazadeh
Assosiate Professor, Payame Noor university, Tehran, Iran
B.
Asgari – Pirbaluti
Assistant Professor, Department of Petroleum Engineering, Islamic Azad University, Masjed-Soleiman Branch Masjed-Soleiman, Iran
A.
Solgi
Assosiate Professor, Department of Geology, Faculty of Basic Science, Islamic Azad university, Science and Research Branch,Tehran, Iran
asolgi66@yahoo.com
10.22071/gsj.2017.54127
The Asmari Formation was measured and sampeled in Ghar-e Agha Seyyed at Farsan area in order to determine sedimentary environment based on facies analysis. In the study area, the Asmari Formation has a thickness of 183 m and conformably underlained the Pabdeh Formation. Based on microfacies studies, 8 microfacies were recognized such as:1) Porcelanouse foraminifera – bioclastic – red algal wackestone / packstone, 2) Rotalia grainstone, 3) Bioclastic –red algal grainstone, 4) Red algal – coral boundstone, 5) Red algal wackestone (Floatstone), 6) Red algal –large hyaline foraminifera – intraclast packstone, 7) Red algal – bioclastic - large hyaline foraminifera wackestone / packstone, 8) Large hyaline foraminifera packstone. These microfacies represent three facies belts including Inner ramp, Middle ramp and Outer ramp. On the other hand, based on the presence of benthic foraminifera, the age of the Asmari Formation is related to Oligocene (Rupelian – Chatian).
Asmari Formation,Microfacies,Farsan,Ghar-e Agha Seyyed
http://www.gsjournal.ir/article_54127.html
http://www.gsjournal.ir/article_54127_5edb5564703c107e71740c108d7e20fa.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Identifying interior sources of dust storms using remote sensing, GIS and geology (case study: Khuzestan province)
33
46
FA
Peyman
Heidarian
M.Sc., Geological Survey of Iran, Southwestern Area (Ahwaz Center), Ahwaz, Iran
peyman.2012rs@gmail.com
A.
Azhdari
M.Sc., Geological Survey of Iran, Southwestern Area (Ahwaz Center), Ahwaz, Iran
M.
Jodaki
Ph.D., Geological Survey of Iran, Southwestern Area (Ahwaz Center), Ahwaz, Iran
J.
Darvishi Khatooni
M.Sc., Geological Survey of Iran, Southwestern Area (Ahwaz Center), Ahwaz, Iran
R.
Shahbazi
Ph.D., Applied Geological Research Center of Iran, Karaj, Iran
10.22071/gsj.2017.53928
Significant damages have been caused by dust storm in Iran, particularly in Khuzestan province. Thus, as a primary step to fight with dust storms, it is necessary to map dust sources. The purpose of this study is to identify dust sources using a combination approach of remote sensing, GIS and sedimentology in Khuzestan province. For this, spatial data of soil, land use, climate, slope (collected from related organizations) and sedimentology were used as constraint layers, and vegetation, land surface temperature (LST) and soil moisture constitute the main layers. Sedimentology map was prepared by field sampling (900 samples) and remote sensing techniques. Also the main layers were extracted by performing the necessary computational processes on Landsat 8 satellite images. The constraint layers were applied to remove the areas without any potential of dust source. In next step, main layers weighting was done using pairwise comparison and Fuzzy Analytic Hierarchy Process (FAHP) methods. For preparing map of dust sources, each major layer was multiplied by corresponding weight and were then integrated to present a dust source zonation map. To validate the results, a field work was carried out in 180 points of source areas that verifies high accuracy of the prepared map. Results showed that 9 percent of Khuzestan plain, equivalent to 349254 hectares, are dust-generating sources. Based on land use type and area, the identified zones include destroyed range, rainfed agriculture lands, bare lands, wetlands, dried ponds and irrigated agriculture lands, respectively.
Dust Storms,Dust source identification,Remote Sensing,Sedimentology,GIS,Khuzestan Province
http://www.gsjournal.ir/article_53928.html
http://www.gsjournal.ir/article_53928_eee5c02b571f6694f3919bf3612105b5.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Mineral chemistry and petrogenesis of calc-alkaline lamprophyric dikes at Sungun and Haftcheshme mines (Alborz- Azarbaijan zone, Iran)
47
60
FA
Z.
Gharehchahi
Ph.D., Department of Earth Scinces, University of Tabriz, Tabriz, Iran
M.
Moayyed
Professor, Department of Earth Scinces, University of Tabriz, Tabriz, Iran
J.
Ahmadiyan
0000-0002-0937-2383
Assistant Professor, Department of Geology, Payame Noor University, Tehran, Iran
jamshidahmadian@yahoo.com
M.
Murata
Professor, Natural Scince Education (Scince), Naruto University of Education, Tokushima, Japan
10.22071/gsj.2017.54130
Sungun and Haftcheshme mines located in Arasbaran volcano-plutonic complex in the North West of Azarbaijan province. lamprophyric dikes of Sungun with younger age Oligo-Miocene including minerals, biotite, plagioclase and pyroxene, porphyritic texture, classified part of the calc-alkaline and kersantite and The area lamprophyric rocks are intruded in to Sungun quartz - monzonite. lamprophyric dikes of haftcheshme with with younger age Oligo-Miocene including minerals, biotite, alkali feldspar and pyroxene, the main textures microlitic porphyy and flow, Calc-alkaline Lamprophyre component - are classified minette and The area lamprophyric rocks are intruded in to Haftcheshme quartz - diorite. The behavior of trace elements studied by the means of spider diagrams show low enrichment of LREE relative to MREE and HREE. Review geochemical characteristics of the study show that the origin of mantle-derived magmas essentially lamprophyres. The lamprophyric rocks are generated from calc-alkaline lamprophyrecomponent, related to magmatic arc tectonic setting and these lamprophyres have gneated from lamprophyre low degree of partial melting of garnet lherzolite.
Calc-alkaline Lamprophyre,Kersantite,Minette,East Azarbaijan Province,Sungun,Haftcheshme
http://www.gsjournal.ir/article_54130.html
http://www.gsjournal.ir/article_54130_d64bcece92cce0560c7d228cd0488a86.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Delineation of seismic sources using an optimized fuzzy clustering
61
70
FA
R.
Ghasemi Nejad
M.Sc. Student, School of Surveying and Geospatial Information Engineering, College of Engineering, University of Tehran, Tehran, Iran
R. A.
Abbaspour
Assistant Professor, School of Surveying and Geospatial Information Engineering, College of Engineering, University of Tehran, Tehran, Iran
M.
Mojarab
Researcher, Geo-engineering laboratory, School of Mining Engineering, College of Engineering, University of Tehran, Tehran, Iran
mmojarab@gmail.com
10.22071/gsj.2017.54132
Seismic source zones have an important role in hazard assessment in probabilistic seismic hazard analysis. These zones often determined according to judgments by experts are, in most cases, non-uniform across a specific region and typically controversial. Thus, most of the uncertainty in probabilistic seismic hazard analysis can be related to the delineation of seismic sources. Another problem of probabilistic seismic hazard analysis is the way earthquakes are associated with the faults. Even though it is well-known that earthquakes happen on faults, but most of them are still unknown, this constrains the realization and assessment of seismic risks by experts. This paper attempts to determine seismic sources and associate events to faults using a fuzzy particle swarm optimization clustering algorithm. The algorithm works based on the minimization of two objective functions: distance from events to fault, and distance from events to their center of density (i.e. cluster center). The algorithm is applied on seismic data acquired from northwest of Iran, and its performance is evaluated based on the events assigned to the faults by previous researchers. Comparing associated earthquakes to faults by the algorithm in northwest of Iran with known and documented earthquakes, reveals that, 79.2% of the events are correctly induced by faults. Final result shows that, this methodology will help seismological engineers take a step forward in hazard analysis by determining seismic sources and assigning earthquakes to different active faults.
Fuzzy Clustering,Particle Swarm Optimization (PSO),Probabilistic Seismic Hazard Analysis (PSHA),Seismic Sources
http://www.gsjournal.ir/article_54132.html
http://www.gsjournal.ir/article_54132_cb36431cfef582f87e42e42e38c3a016.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Fractures analysis of the Asmari formation in the Kupal oil field (Dezful embayment, SW Iran)
71
80
FA
R.
Alipoor
Assistant Professor, Department of Geology, Faculty of Science, Bu-Ali Sina University, Hamedan, Iran
10.22071/gsj.2017.53930
The Kupal oil anticline is one of the most important structures in Dezful embayment that is located in northeast of the Ahvaz city and north of the Marun oil field. Recent deposits and Lahbari member of the Aghajari formation have formed the surface outcrops, and the Asmari formation with 7 reservoir layers is the main reservoir rock in this oil field. In this research fractures of the Asmari formation in this anticline have been analyzed based on well data, subsurface maps and seismic profiles. The Kupal oil anticline is a fault-related (detachment fold) and asymmetric fold, in which the middle parts have been distinguished as potential zones of of dense fractures development due to longitudinal curvature. The southwest limb in much parts and northeast limb in middle parts indicate zones with high fracture density, and the axial bending of the Kupal anticline is a result of movement of deep faults.
Seismic profile,Fractures,Asmari,Kupal,Anticline
http://www.gsjournal.ir/article_53930.html
http://www.gsjournal.ir/article_53930_8fb3f760ead4cdd6b34c2b24c1371738.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Deciphering the stress field changes in Shahr-e-Babak area using brittle tectonic analysis
81
96
FA
L.
Ebadi
Ph.D., Department of Geology, Faculty of Earth Sciences,Shahid Beheshti University, Tehran, Iran
S. A.
Alavi
Professor, Department of Geology, Faculty of Earth sciences, Shahid Beheshti University, Tehran, Iran
M. R.
Ghassemi
Associate Professor, Reaserch Institute for Earth Sciences, Geological Survey of Iran, Tehran, Iran
mrghassemi@yahoo.com
10.22071/gsj.2017.53931
In this paper a part of the Shahr-e-Babak area in NW-Kerman is studied, which is geologically located in Central Iran and Urumiyeh- Dokhtar Belt. The basin was strongly affected by compression in Miocene times, in which deformation is characterized by development of NW-SE trending fold and thrust belt. In this paper, we aim atdeciphering polyphase deformation and paleostress history of part of the Central Iran in the Shahr-e-Babak area, and that how various geological aspects may be related to a stress field that has been reoriented through time. Also, we indicate how the brittle deformation studies and paleostress analyses may contribute in the interpretations of the post-collisional tectonic evolution of this area. In this paper, by using systematic brittle tectonic analyses, including stress tensor inversion form fault-slip data, we decipher the succession of deformational events that resulted in present-day structures. Therefore, a statistical view of the brittle tectonic reconstructions taken as a whole leads one to better understand the relationships between the different stress fields and folding events that governed the history of compression in this area .The systematic reconstruction of brittle tectonic regimes led us to characterize an anticlockwise change in the main direction of compression through time. Thus, it can be seen that the late Cretaceous to late Miocene pre-folding N055° and N084° compression was followed by syn-folding N040° compression in the Miocene. The Miocene compression then continued into the Pliocene post-folding N029° direction, and changed afterward to the Pleistocene-Recent post-folding N003° direction. Although this general anticlockwise rotation of compression has probably been progressive through time, our data suggest three distinct stress regimes that (1) predate, (2) are contemporaneous with, and (3) post-date the more consistent compressional stress regime of the folding and thrusting process. According to this reconstruction, it is confirmed that many local right-lateral strike–slip faults were reactivated from NW-SE reverse faults in the Sahahr-e-Babak area of SW Central Iran .These results could properly support the hypothesis of a significant anticlockwise change in the movement direction of the Arabian plate with respect to the Eurasian plate and block rotation in Central Iran.
Paleostress,brittle tectonic,rotation,Fold,Shahr-e-Babak
http://www.gsjournal.ir/article_53931.html
http://www.gsjournal.ir/article_53931_a83c231a27834c05e2515016c800aeb2.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Determining microfacies of phosphate bearing Pabdeh Formation in paleogene carbonate ramp of Lar anticline (Northeast of Gachsaran)
97
104
FA
Sh.
Shariati
Assistant Professor, Department of Geology, Sari Branch, Islamic Azad University, Sari, Iran
shariati.shahram@gmail.com
10.22071/gsj.2017.54133
Pabdeh Formation comprised carbonate-siliciclastic succession of Zagros fold-thrust belt in south west of Iran. The studied area is located in Lar Mountains (North East of Khami anticline) which extend in a northwest-southeast direction Parallel to the Zagros sedimentary basin trend. Microfacies analysis especially in phosphate-bearing horizons and semiquantitative investigations of foraminiferal contents as an aid to determining the depositional environment of marine deposits was the aim of this study. For this purpose, 300 sample were collected from 410-m stratigraphical section in the Pabdeh Formation. From these 126 thin section were compiled based on lithology and facies alternations. Petrographical studies and microfacies analysis of Pabdeh Formation demonstrate that eight lithofacies can be recognized in this interval. Planktonic Foraminiferal mudstone and indicating the presence of turbidite microfacies suggest deposition in a ramp setting. On the other words the depositional environment of the Pabdeh Formation evolved into an outer ramp setting. Microfacies of the upper part of Pabdeh Formation reveal deposition in a shallowing-upward depositional environment. With attention to the items mentioned above the Pabdeh Formation is dominated by a pelagic microfauna that deposited in a deep ramp setting (Outer ramp) which passed into a shallower ramp parts (Middle ramp).
Pabdeh Formation,Carbonate ramp,Foraminiferal content,Middle ramp,Outer ramp
http://www.gsjournal.ir/article_54133.html
http://www.gsjournal.ir/article_54133_07d1e767c7ff9e0657ce95eb69b60582.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Mineralogy, texture and retrograde P-T evolutions of the granulites during cooling and exhumation, NE of Takht-e-Soleyman metamorphic complex (NW Iran)
105
116
FA
R.
Hajialioghli
Assosiate Professor, Earth Sciences Department, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iran
M.
Moazzen
Professor, Earth Sciences Department, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iran
moazzen@tabrizu.ac.ir
10.22071/gsj.2017.54134
The Takht-e-Soleyman metamorphic complex is located at NE of Takab town, West Azerbaijan province. This complex having Precambrian-Cambrian age has been formed from low to high metamorphic rock types. The retrograde granulites are subject of this project. The retrograde metamorphic assemblages of the granulites are including of Amp+Grt+Spl+Opaque phases. Amphibole overprinted primary mafic phases of clinopyroxene and orthopyroxene highly. Spinel at the klyphitic texture around garnet porphyroblast forms the main feature for retrograde metamorphism of granulites. Rutile occur as inclusion within amphibole. The compositional profile of garnet indicates chemical variations from the core to the rim. Compositional variations from the core to the mid is characterized with a minor increase in X<sub>Mg</sub> but decrease in X<sub>Ca</sub> and X<sub>Mn</sub>. This characteristic of garnet is indicative of pressure decompression with small increasing of temperature. Due to complete overprinting of high temperature phases by the retrograde phases as well as lack of preserved pick metamorphic minerals it is indeterminate pick metamorphic P-T estimations for M1 stage. On the basis of chemical compositions of porphyroblasts, retrograde evolutions of investigated granulites have been estimated at two stages: (1) pressure decompression (M<sub>2-a</sub>) and (2) cooling and exhumation (M<sub>2-b</sub>). The retrograde P-T conditions are obtained as T=810±10°C at P=10.5±0.7kbar for the first and second retrograde stages, respectively. Relatively coarse grained size of phases at the klyphitic margin are indicative of low cooling rate during uplifting of rocks from lower to upper levels. Highly overprinting of high temperature phases by amphiboles support this idea. Time of pick and retrograde metamorphism for the investigated granulites are not clear accurately. It seems reasonable to attribute pick metamorphic and granulite formation time to Oligocene-Miocene related to crustal thickening due to collision between the Central Iran microcontinent and the Arabia plate. The granulites have been metamorphosed under retrograde conditions in relation with thrusting and post collisional extensions which caused to uplifting, crustal thinning and exhumation of rocks. However more conclusions on tectonometomorphic evolutions need to precise studies.
Klyphitic margin,Granulites,P-T evolutions,Retrograde metamorphism,Takht-e-Soleyman,NW Iran
http://www.gsjournal.ir/article_54134.html
http://www.gsjournal.ir/article_54134_2b143115a09b0013b06bf01f334b05f9.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Depositional and diagenetic controls on reservoir quality of the Sarvak Formation in one of the Abadan plain oilfields (SW Iran)
117
130
FA
S.
Faramarzi
Ph.D. Student, Department of Geology, Islamic Azad University, Science and Research Branch, Tehran, Iran
s.faramarzi1393@gmail.com
H.
Rahimpour-Bonab
Professor, School of Geology, College of Science, University of Tehran, Tehran, Iran
M.
Ranjbaran
Assistant Professor, School of Geology, College of Science, University of Tehran, Tehran, Iran
mohsenranjbaran@gmail.com
10.22071/gsj.2017.53934
The Sarvak Formation is one of the most important carbonate reservoirs of Iran. The main objective of this study is to evaluate reservoir quality of the formation by integration of petrographic studies and core porosity-permeability data in three key wells in a giant oilfield of the Abadan Plain, SW Iran. Petrographic studies led to the identification of 13 microfacies that are grouped into three main facies belts including lagoon, shoal, and open marine (talus and slope) which deposited in an isolated carbonate platform. The main diagenetic processes affecting the Sarvak Formation are micritization, bioturbation, recrystallization, dissolution, cementation, physical and chemical compaction, dolomitization and silicification, along with fracturing. According to the results, the reservoir quality of the Sarvak reservoir is a function of both primary depositional facies and secondary diagenetic processes. Evaluation of impacts of depositional facies on reservoir quality indicated that the rudist-bearing intervals (especially rudist debris zones) have high reservoir quality. Dissolution and cementation are the most pervasive diagenetic processes affecting the formation, and occurred due to widespread meteoric diagenesis. Dissolution and fracturing are the chief factors that lead to the improvement of porosity-permeability, whilst calcite cementation and compaction have destructed reservoir quality of the studied interval. This study may assist better understand the geological parameters controlling reservoir quality of Sarvak Formation in the Abadan Plain oilfields.
Sarvak Formation,Abadan plain,Diagenetic Processes,Reservoir quality
http://www.gsjournal.ir/article_53934.html
http://www.gsjournal.ir/article_53934_fd6974cfe0aec56d75aafcc518eea517.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Engineering geological characteristics of Gachsaran formation of a leakage (Case Study: Dam Khersan 3)
131
142
FA
M.
Noori Sartangy
M.Sc., Faculty of Science, Tarbiat Modares University,Tehran, Iran
m.noori281@gmail.com
A.
Uromeiea
Professor, Faculty of Science, Tarbiat Modares University,Tehran, Iran
K.
Zarea Mozafary
M.Sc., Iran Water and Power Resources Development Company, Tehran, Iran
10.22071/gsj.2017.54177
Engineering geological characteristics they Dam Khersan 3 Gachsaran in order to evaluate the solubility of gypsum and leakage problems and select a suitable method for sealing Gachsaran formation that includes part of the reservoir was investigated. Khersan 3 dam, the concrete arch dam with a height of 195 meters on the 40 km south Lordegan city on Khersan river is under construction. Geological formations site includes Asmari limestone , marl, gypsum and gypsum formations Gachsaran marl and shale Pabdeh and Gurpi formations and River alluvium is. The seepag, dissolution, XRF, XRD in some samples was determined and the leakage of water from the reservoir was evaluated using numerical analysis. Results and due to the presence of large marl, Lvzhan make up less than 3 and High RQD Gachsaran formations no Kataf wall construction or grout curtains, are suggested.
Khersan 3 Dam,Solubility,Gachsaran formation,Water escape
http://www.gsjournal.ir/article_54177.html
http://www.gsjournal.ir/article_54177_1c9de822722f95d71eb6a4d1d81993ef.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Mineralization and geochemical characteristics of ore-forming fluids in Bahr Aseman area, southeast of Kerman magmatic belt
143
156
FA
M. R.
Hosseini
Ph.D., Department of Geology, Faculty of Earth Sciences, Shahid Beheshti University, Tehran, Iran
S.
Alirezaei
Assosiate Professor, Department of Geology, Faculty of Earth Sciences, Shahid Beheshti University, Tehran, Iran
alirezaei@sb.ac.ir
J.
Hassanzadeh
Assosiate Professor, Division of Geological and Planetary Sciences, California Institute of Technology, California, USA
10.22071/gsj.2017.54183
The Bahr Aseman volcanic-plutonic complex is located to the southeast of the Kerman magmatic belt. Unlike Kerman magmatic belt which formed and evolved during Cenozoic in a dominantly continental arc and post-collision tectonic setting, Bahr Aseman complex formed during Late Cretaceous in an oceanic island-arc setting. The complex is composed of andesitic and andesitic-basaltic lava flows and subordinate pyroclastic materials and carbonate interlayers, as well as abyssal tonalite to quartz-diorite and quartz- monzodiorite intrusive bodies and shallow dioritic intrusions. Vein- type copper deposits, iron skarn and copper skarn are the main ore deposit types in Bahr Aseman. Chalcopyrite is the main ore mineral in vein-type and skarn-type copper deposits; the mineral is converted to oxide copper ores at surface and shallow depths. Magnetite is the main commodity in skarn type iron deposit. Highly altered porphyritic bodies associated with copper oxide ore were identified that are comparable, in some aspects, with porphyry type copper deposits; subsurface data, however, is required for conclusive remarks. <br />The various types of deposits are distinguished by distinct fluid inclusion characteristics. In the vein type copper deposits, fluids in association with mineralization represent dominant homogenization temperature (Th) of 150-220 ºC and salinity of 5-10 and 25-30 wt% NaCl. Fluids in the skarn type copper deposits represent 170-250 ºC and ranges of 5-15 and 27-35 wt% NaCl as dominant Th and salinity, respectively. <br />The δ<sup>34</sup>S values in the vein-type copper deposits vary between +3.9 and +5‰, suggesting a magmatic origin for sulfur and probably metals (directly derived from magma or leached from magmatic rocks). Sulfur isotope ratios for two samples from Moka are +4.3 and +7.1‰, slightly different from typical magmatic δ<sup>34</sup>S ranges. Oxygen and hydrogen isotope ratios for the vein-type copper deposits, measured on quartz and fluids extracted from inclusions in the mineral, are -6.6 to +1.9‰ and -79.4 to -51.8‰, respectively. This values suggest mixing of magmatic and meteoric fluids and/or fluid-rock interactions at different ratios. It appears that larger deposits have more shares of fluids with magmatic origin. With regards to the island-arc tectonic setting, recognized deposit types and ore minerals paragenesis, finding new copper and iron and probably gold deposits are possible in the Bahr Aseman area. <br /><strong> </strong>
Kerman magmatic belt,Bahr Aseman,Oceanic arc,Vein-type copper,Iron-copper skarn,Porphyry copper deposit,Fluid inclusion,Stable isotopes
http://www.gsjournal.ir/article_54183.html
http://www.gsjournal.ir/article_54183_9eb1d208d58d5024ff69d76c2527219a.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
The Study of relation between fault and fracture systems based on subsurface data and analogue modeling: one of the Eastern Persian Gulf hydrocarbon fields
157
166
FA
E.
Kosari
M.Sc., Research Institute for Earth Sciences, Geological Survey of Iran, Tehran, Iran
A.
Bahroudi
Associate Professor, Exploration Department, School of Mining Engineering, College of Engineering, University of Tehran, Tehran, Iran
M.
Talebian
Associate Professor, Research Institute for Earth Sciences, Geological Survey of Iran, Tehran, Iran
morteza.talebian@gmail.com
A.
Chehrazi
Ph.D., Geophysics and Exploration Plans Department, Iranian Offshore Oil Company, Tehran, Iran
10.22071/gsj.2017.53939
One of the essential studies in exploration, exploitation and development of hydrocarbon fields is to evaluate the fault and fracture systems and the role that they can play in reservoir quality and geometry. If the hydrocarbon reservoir is a fractured carbonate reservoir, assessing the mentioned properties is of great importance. Assessment of the structures should be done simultaneously because of their close relations, and the their probable genesis connection should be revealed. In this research, subsurface data including 2D seismic profiles, underground contour maps and FMI log and eventually analogue modeling have been used for evaluation of probable scenarios explaining formation of faults and fractures. The studied area is located at the front of Zagros deformation belt and the Zagros stresses have apparently not affected it. Two sets of faults of different geometry and role have been detected; the first reverse set (N-S trending) was apparently controller of the reservoir geometry in the structure; the second normal set (NW-SE trending) are most likely causative of the main fractures in the field. It is likely that positive inversion tectonic of the basin led to the development of this field in form of a pop-up structure. Based on the interpretations, the internal normal faults have been formed probably by the rise of Hormuz salt or by local stretching due to left-lateral component of the boundary reverse faults. Using interpretation of drilling-induced fractures and break-outs derived from FMI, trends of the Shmax and Shmin are determined. Also it was revealed that the natural fractures and the main set 2 of faults are sub-parallel with the fractures induced by drilling. Therefore, the compatibility between trends of the natural fractures, breakouts and local normal faults can suggest a tectonic origin for the natural fractures.
Analogue Modeling,Fault,fracture,Image well logging,Persian Gulf
http://www.gsjournal.ir/article_53939.html
http://www.gsjournal.ir/article_53939_fc5c534ec715e582ac031f54bd796e96.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Mineral chemistry and petrogenesis of metabasites of metamorphic - igneous Shotor-Kuh complex (SE Shahrood) an indicator for evolution of intracontinental extensional basins of late Neoproterozoic
167
182
FA
S.
Shekari
Ph.D. Student, Department of Petrology and Economic Geology, Faculty of Earth Sciences, Shahrood University of Technology, Shahrood, Iran
s.shekari@shahroodut.ac.ir
M.
Sadeghian
Assocciated Professor, Department of Petrology and Economic Geology, Faculty of Earth Sciences, Shahrood University of Technology, Shahrood, Iran
m.sadeghian1392@gmail.com
M.
Zhai
Professor, Institute of Geology and Geophysics, Chinese Academy of Science, Beijing; Northwest University, Xian, China
H.
Ghasemi
0000000154469961
Professor, Department of Petrology and Economic Geology, Faculty of Earth Sciences, Shahrood University of Technology, Shahrood, Iran
h-ghasemi@shahroodut.ac.ir
Y.
Zou
Ph.D Student, Institute of Geology and Geophysics, Chinese Academy of Science, Beijing, China
10.22071/gsj.2017.54181
Metamorphic - igneous Shotor-Kuh complex is located in the 80 km of SE Shahrood and in the northern edge of the central Iran structural zone. This complex includes a wide lithological composition range such as metapelite (micaschists and gneisses), metapsammites, metabasites (amphibolite and garnet amphibolite), metacarbonate (limestone and dolomitic marbles) and metrhyolites. Protolith of metabasites have been basaltic lavas, diabasic swarm dikes and small scale gabbro-dioritic intrusions. With respect to abundance and importance of metamorphosed basaltic intercalations and diabasic swarm dikes in comparison to the other basic rocks, this article specially advocated to investigation of their evolution. Based on the field evidence and petrography, increasing the degree of metamorphism of metabasites resulted in producing of amphibole schist, amphibolite, garnet amphibolite and eventually amphibolitic migmatites. Thermobarometery based on the chemical analysis of garnet, amphibole and plagioclase of the metabasites indicates that the thermal range of 602-711 °C and 9-11 Kbar pressure for their formation, stop of exchange and final equilibrium, which accommodate with P-T condition of amphibolite and upper amphibolites facies. From the geochemical points of view, the magmas forming of these metabasites have tholeitic to calc-alkaline nature. These magmas originated from the subcontinental lithospheric mantel source. Submarine basaltic lava flows and diabasic swarm dikes originated during extensional tectonic regimes which affected Late Neoproterozoic Iranian Gondwanan terrains. These extensional tectonic regimes are associated with producing of intracontinental sea to oceanic basins (riffitic or back arc). The mentioned basins closed in a short time and lead to generate tectonic melange or accretionary prisms on the continental crust. Based on the U- Pb age dating of the Zircons extracted from these metasbasites, these metamorphism event occurred in the interval time of 526-577 Million years (corresponds to the late Neoproterozoic and Cadomian orogeny in the Iranian Gondwanan landforms).
Diabasic swarm dike,Metabasite,Amphibolite,Cadomian,Central Iran,Shotor-Kuh,Shahrood
http://www.gsjournal.ir/article_54181.html
http://www.gsjournal.ir/article_54181_f47c34a99e890490986f8ad737d008dd.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Estimation of hydraulic conductivity by using of SCMAI model. A case study: Maraghe-bonab aquifer.
183
192
FA
S.
Yusefzadeh
M.Sc. Student, Department of Earth Sciences, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iran
A. A.
Nadiri
Associated Professor, Department of Earth Sciences, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iran
10.22071/gsj.2017.54184
Today Ground water is the main source of drinking, agriculture and other uses for humans. The demand for this critical and strategic natural resource increased with population growth and development of society. This increasing has been declining water resources and damage aquifers environment. Therefore, we need to manage aquifers and understanding the hydrogeological parameters to deal with the water crisis and prevent the distraction of aquifers. The one of most important parameter is hydraulic conductivity. Although, the ground water system is a complex system and estimation of hydrogeological parameters is associated with inherent uncertainty and also is costly and time consuming that usually done with classical methods such as laboratory tests, slug test, tracing test and pumping tests. So recently use artificial intelligence methods for estimation of hydraulic conductivity, reduced the uncertainty of this parameter and it adds up some accuracy. So that it can overcome on the shortcoming of classical methods. In this study, four artificial intelligence methods; mamdani fuzzy logic(MFL) system, sugeno fuzzy logic(SFL) system, Wavelet-neural network method and Least square support vector machine(LS-SVM) method were used as individual models to estimate the hydraulic conductivity by using of surface geophysical data in Maragheh-Bonab aquifer. Given that each these models based on their inherent properties, they presented good results in some parts of area. Therefore, for concurrent use of performance of all these models the nonlinear combination method as a supervised committee machine artificial intelligence (SCMAI) model were used to estimate the hydraulic conductivity in maragheh-bonab aquifer. The result of this model showed that this new combinational model has high performance than other single models that presented by using different evaluation criteria. Therefore, this model could also be used for estimation hydrogeological parameters in areas with high complexity. The SCMAI model was tested against 15 data. The RMSE and for SCMAI prediction were computed as 0.045 and 0.97, respectively. Comparing the error measure values with dose of individual models above, it is seen that SCMAI outperforms individual AI models with low RMSE and high values. This result implies that SCMAI model shows high performance for estimation the hydraulic conductivity values in the heterogeneous unconfined aquifer in Maragheh-Boanb plain.
Wavelet-neural network,Support Vector Machine,Fuzzy logic,Hydraulic conductivity,Supervised compound artificial intelligence
http://www.gsjournal.ir/article_54184.html
http://www.gsjournal.ir/article_54184_2cc1c775684d1d9e05ea92f6b90a39b7.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Computing maximum seismic acceleration of North Tabriz Fault using earthquake simulation based on finite fault source
193
198
FA
H.
Amiranlou
Ph.D. Student, Department of Geology, Faculty of Basic Science, North Tehran Branch, Islamic Azad University, Tehran, Iran
M.
Pourkermani
0000-0003-3445-760X
Professor, Department of Geology, Faculty of Basic Science, North Tehran Branch, Islamic Azad University, Tehran, Iran
mohsen.pourkermani@gmail.com
R.
Dabiri
0000-0002-1807-1945
Assistant Professor, Department of Civil Engineering, Tabriz Branch, Islamic Azad University, Tabriz, Iran
rouzbehdabiri@gmail.com
M.
Qoreshi
0000-0002-1600-0350
Assosiate Professor, Research Institute for Earth Sciences, Geological Survey of Iran, Tehran, Iran
ghorashi_manouchehr@yahoo.com
S.
Bouzari
Assosiate Professor, Department of Geology, Faculty of Basic Science, North Tehran Branch, Islamic Azad University, Tehran, Iran
10.22071/gsj.2017.53948
The occurrence of historical and instrumental earthquakes near the North Tabriz Fault in NW Iran is an evidence for seismic activity of this fault, which recorded historical earthquakes with magnitudes greater than 7. In this study, existing experimental relations, historical seismicity, and the fault geometry were used to define a Mw 7.7 earthquake scenario. The stochastic finite fault modeling based on a dynamic corner frequency shows a good agreement between maximum estimated acceleration and common attenuation patterns. The derived shake map illustrates that the stongest ground motion is observed in the NW, N and NE of the tabriz city along a zone parallel to the fault. In addition, the maximum acceleration derived from simulation is almost equal to that computed from attenuation patterns.
Maximum acceleration,Ground motion,North Tabriz Fault,Finite fault source
http://www.gsjournal.ir/article_53948.html
http://www.gsjournal.ir/article_53948_ddd057db942e30cb6aa09b5f93e9e7f0.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Separation of geochemical anomalies using concentration- area and concentration- number methods in the Alut 1:100,000 sheet, Kurdistan
199
206
FA
S. A.
Hosseini
M.Sc., Department of Geology, Khoram Abad Branch, Islamic Azad University, Khoram Abad, Iran
S. V.
Shahrokhi
0000-0002-5960-8243
Assistant Professor, Department of Geology, Khoram Abad Branch, Islamic Azad University, Khoram Abad, Iran
vahid.shahrokhi@gmail.com
P.
Afzal
Associate Profesor, Department of Mining Engineering, South Tehran Branch, Islamic Azad University, Tehran, Iran
paymanafzal@yahoo.com
T.
Farhadinejad
0000-0001-9263-1608
Assistant Professor, Watershed Management Research Department, Lorestan Agricultural and Education Center Soil Conservation Khoram Abad, Iran
farhadinejad@gmail.com
H.
Imanzadeh
M.Sc., Geological Survey of Iran, Tehran, Iran
10.22071/gsj.2017.54178
Collected geochemical data from stream sediments, can be used in regional exploration and identifying anomalies in reconnaissance stages. In this research in order to regional exploration studies, multifractal modeling approaches include concentration-area and concentration-number has been used and geochemical anomalies for index elements (As,Sb,Au and Cu) has examined. 855 of stream sediment samples were collected The Alut 1:100,000 sheet and analyzed by ICP-MS method in the laboratory of Geological Survey of Iran (GSI). Then, statistical parameters and histograms were performed on the elements. Then, using fractal methods concentration-area and concentration-number, related anomalies in this sheet has prepared and anomaly maps were drawn. Respect to the Geological setting, existing structures and predominant lithology the results of two methods (concentration - area and concentration – number) has compared in the area. The results of the two methods showed that concentration of these elements has increased in central and southeast regions and formed promising areas. Although concentration-number method due to more extensive geochemical halo included well-known deposits (Barika mine) and also accommodate expected mineralization in Sanandaj - Sirjan zone.
Concentration-Area (C-A),Concentration-Number (C-N),multifractal modeling,Stream sediments,Alut
http://www.gsjournal.ir/article_54178.html
http://www.gsjournal.ir/article_54178_b868ccba6d312c254eb0c0b31832fe9c.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Evaluating the causes of increased salinity of deep groundwater in Gol Gohar iron ore mine
207
214
FA
M.
Siavash haghighi
M. Sc. Kusha Madan Consulting Eng., Tehran, Iran
10.22071/gsj.2017.53951
One of the factors reducing the chemical quality of groundwater used in the industry is a gradual increase of ions concentration. These ions can affect the mineral processing and reduce mining efficiency by corrosion or sedimentation in the path of water circulation. In Gol Gohar Iron ore mine, the rate of salinity in groundwater has increased significantly in recent years. Because brine groundwater in the mine is used to produce pulp in concentrators, its quality has been a matter of concern. In this study, different factors affecting the groundwater quality and causing salinity increase are studied. These factors include quality of groundwater inflow, surface water infiltration, lithology of the region, depth of mining, saturated thickness of the aquifer, changes of hydraulic gradient, ground water circulation path, water budget, isotopic properties of water and groundwater evaporation.
Gole Gohar mine,Chemical Quality,Groundwater,Salinity increase,Hydrochemical cycle
http://www.gsjournal.ir/article_53951.html
http://www.gsjournal.ir/article_53951_05f8f4dba65fb98decff56be8aea8a71.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Petrology, geochemistry and geochronology of Nodoushan intrusive complex, West of Yazd
215
232
FA
B.
Shahsavari Alavijeh
Ph.D. Student, Department of Geology, Faculty of Basic Sciences, Tarbiat Modares University, Tehran, Iran
N.
Rashidnejad Omran
Associate Professor, Department of Geology, Faculty of Basic Sciences, Tarbiat Modares University, Tehran, Iran
rashid@modares.ac.ir
J.
Ghalamghash
Assistant Professor, Research Institute for Earth Sciences, Geological Survey of Iran, Tehran, Iran
jalilghalamghash@gmail.com
10.22071/gsj.2017.53952
The Nodoushan intrusive complex is a part of Cenozoic plutonism, which located in the central part of the Urumieh–Dokhtar Magmatic Belt (UDMB). This complex consists of four main intrusives, including diorite, granite-granodiorite, diorite porphyry and granodiorite. Mafic microgranular enclaves (MMEs) are abundant in the diorite porphyry and granodioritic intrusives and also in some parts of Granitegranodiorite intrusives, which consist of diorite, monzodiorite and rarely gabbro -diorite. According to geochemical data, the Nodoushan intrusive complex is metalominous to moderately peraluminous, I-type and shows medium to high potassium calc-alkaline affinity. Geochemical investigations show that contamination and mafic-felsic magma mixing played significant role in the evolution and petrogenesis of the mentioned intrusions magmas and formation of MMEs. Using U-Pb zircon dating method, the obtained magma crystallization ages are about 30 Ma for the dioritic and granite-granodiorite intrusives, 24 Ma for the diorite porphyry and 25 Ma for the granodioritic intrusives. In addition, the age for part of the granite-granodiorite unit that is located in the northeast corner of the region, at the north of the Nain-Dehshir fault (NDF) and the western part of the Central Iranian Microcontinent (CIM), was determined 40 Ma. The geochemical evidences suggest that the studied intrusions magmas were derived from partial melting of continental crust caused by the mantle melts in an active continental margin. It seems that the melting of rocks with combination of metabasalt and metagraywacke in the lower crust in balance with the residual consisting of clinopyroxene, amphibole and to a lesser extent plagioclase; have the greatest harmony with geochemical characteristics of the studied intrusions.
Partial Melting,Active continental margin,Urumieh–Dokhtar magmatic belt,Nodoushan Intrusive Complex,West of Yazd
http://www.gsjournal.ir/article_53952.html
http://www.gsjournal.ir/article_53952_95b40b10eb254a7c516f1b25a1fc9c28.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
The genesis of iron oxide-apatite (IOA) deposits: evidence from the geochemistry of apatite in Bafq-Saghand district, Central Iran
233
244
FA
S. A.
Majidi
0000-0002-0680-6895
Ph.D., Department of Geology, Islamic Azad University, Science and Research Branch, Tehran, Iran
afshinmajidi@gmail.com
M.
Lotfi
Assosiate Professor, Department of Geology, Islamic Azad University, North Tehran Branch, Tehran, Iran
mo_lotfi@iautnb.ac.ir
M. H.
Emami
Assosiate Professor, Department of Geology, Islamic Azad University, Islamshahr Branch, Tehran, Iran
hashememami@yahoo.com
N.
Nezafati
Assistant Professor, Department of Geology, Islamic Azad University, Science and Research Branch, Tehran, Iran
nnezafati@gmail.com
10.22071/gsj.2017.54185
The Origin of Iron Oxide-Apatite deposits (IOA) with low Ti or Kiruna type deposits has long been a matter of debate. In this case, several provenances have been proposed for these deposits which include: magmatic, magmatic-hydrothermal, hydrothermal, banded iron formations, and sedimentary-exhalative. Bafq-Saghand metallogenic zone is located in central Iran and hosts several large IOA type deposits including Chadormalu, Choghart, Se-Chahun, and Esfordi with nearly ~1500 mt ore with an average grade of 55%. Mineralization of REE-rich apatite is very common in these deposits, an issue that could be utilized for the study of their genesis. Fifteen apatite samples from the deposits of Chadormalu, Choghart, Se-Chahun, and Esfordi were taken and analyzed using LA ICP-MS. According to the geochemical analysis, the apatite of the abovemnetioned deposits show high enrichment of Y, Na, and Si, while very low content of Cl. Total REE content varies from 0.36-2.25% in which the LREE show an enrichment indicating strongly fractionation from HREE. Strong negative Eu anomaly (0.69-0.256) is observed. Sr and Y contents in apatites are 165-365 and 743-1410 ppm, respectively. The Fe-OH-Cl diagram shows that apatites is situated in the Hydroxil-fluoroapatite domain. The results show that these deposits are similar to those of IOA type deposits (e.g. Kiruna, El Laco, Abagong, Avnik, etc.). Apatite mineralization is unlikely related to carbonatitic magmatism, but situated in the Kiruna type and mafic rocks domain. The main mineralization event was likely related to tonalite-trondhjemite-granodiorite (TTG) and diorite-granite of arc magmatism (525-532 Ma) which were intruded into the Cambrian volcano sedimentary units (as country rock). Then the hydrothermal processes following alkaline intrusion (syenite and monzosyenite) led to mineralization. In general, the iron oxide-apatite (IOA) mineralization with low Ti has occurred through the magmatic-hydrothermal processes in the Bafgh-Saghand zone.
Kiruna type deposits,Geochemistry,Rare earth elements,Magmatic-Hydrothermal,Bfaq-Saghand,Central Iran
http://www.gsjournal.ir/article_54185.html
http://www.gsjournal.ir/article_54185_147a092660663a3ba3502239f7fce45b.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Paleoclimate changes recorded in Gurpi Formation in south of Ilam based on Playnomorphs and Foraminifera
245
252
FA
E.
Zarei
https://orcid.org/00
Assistant Professor, School of Earth Sciences, Damghan University, Damghan, Iran
ezarei@du.ac.ir
E.
Ghasemi-Nejad
Professor, Geological School, Tehran University, Tehran, Iran
eghaseminejad@khayam.ut.ac.ir
A.
Dehbozorgi
Assistant Professor, Faculty of Science, Imam Khomeini International University, Ghazvin, Iran
10.22071/gsj.2017.53956
The Gurpi Formation was studied from different aspects at two sections, Farhadabad and Kavar, in southwest and southeast of Ilam where it is composed of 205 m and 158 m of grey to blue marl and shale beds and occasionally thin beds of argillaceous limestones with two formal members of Seymareh (Lopha) and Emam-Hassan. In order to reconstruct paleoclimate during depositional course of the formation, paleontological and palynological data (ratio of specialist to generalist foraminifera (e.s/e.g) and warm-temperate waters dinocysts and spore and pollen grains) were used statistically. The results show that the Gurpi Formation is mainly deposited in a warm-humid climate with two sharp decreases happening in temperature in early Maastrichtian and Danian.
Paleoclimate change,Gurpi Formation,Foraminifera,Playnomorphs,Zagros Basin
http://www.gsjournal.ir/article_53956.html
http://www.gsjournal.ir/article_53956_88f3688e27f03ade4b4bf13c6879e066.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Sediment-hosted epithermal gold mineralization at Arabshah, SE Takab, NW Iran
265
282
FA
S. M.
Heidari
Ph.D., Department of Economic Geology, Tarbiat Modares University, Tehran, Iran
sm.heidari@gmail.com
M.
Ghaderi
0000-0002-6156-7516
Associate Professor, Department of Economic Geology, Tarbiat Modares University, Tehran, Iran
mghaderi@modares.ac.ir
H.
Kouhestani
0000-0002-3031-9042
Assistant Professor, Department of Geology, University of Zanjan, Zanjan, Iran
kouhestani@znu.ac.ir
10.22071/gsj.2017.53971
Arabshah gold deposit formed through hydrothermal activity with an age of ~11 Ma (based on zircon U-Pb dating by LA-ICP-MS), in northwestern Iran. This hydrothermal activity is a part of the Urumieh-Dokhtar magmatic arc (UDMA), leading to mineralization in this area, similar to Zarshouran, Aghdarreh and Sarigunay gold deposits. Host rocks are a series of lower Paleozoic sedimentary sequences, cut by calc-alkaline to alkaline (high potassium) dacitic domes. Gold mineralization is mainly observed as vein-veinlets, open space filling, disseminated and brecciation in the deposit. The mineralization in terms of hydrothermal alteration (decalcification, minor argillic, sulfidization, dolomitization and silicification) and mineralization development process is associated with brecciation and deposition of base metal sulfides, iron, arsenic and antimony, similar to deposits associated with geothermal systems (low sulfidation epithermal) in volcanic arcs, but the host rock here is sedimentary. Sulfide minerals in the ore include pyrite, arsenopyrite, orpiment and realgar, stibnite, galena, sphalerite and minor amounts of chalcopyrite. Gold mineralization occurred in the form of released grains of oxidized pyrite, the tiny (invisible) in the sulfide phases such as arsenian pyrite for solid solution. The Arabshah deposit shows characteristic alteration assemblages and ore minerals (As, Sb, Hg, base metals) of epithermal low sulfidation deposits. It has been formed in relation to the mid-upper Miocene, high-level magmatic-hydrothermal activity within an extensional regime at the last stages of the UDMA activity in northwestern Iran.
Epithermal,U-Pb dating,Geochemistry,Arabshah,Urumieh-Dokhtar
http://www.gsjournal.ir/article_53971.html
http://www.gsjournal.ir/article_53971_3a1488ee8d4c35d09fdd7a44232093b0.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Reconstruction of geological setting for the protolith of Gole-Gohar, Ruchun and Khabr metamorphic complex (South-west of Baft, Kerman province)
253
264
FA
H.
Fatehi
Ph.D. Student, Department of Geology, Shahid Bahonar University of Kerman, Kerman, Iran
H.
Ahmadipour
Assistant Professor, Department of Geology, Shahid Bahonar University of Kerman, Kerman, Iran
10.22071/gsj.2017.53963
Gole-Gohar, Ruchun and Khabr metamorphic complexes (South-west of Baft, Kerman province), form a part of the Sanandaj-Sirjan metamorphic zone and contain an alternation of metamorphosed impure limestone, sedimentary rocks and basic igneous rocks. Different studies show that the first metamorphic event has been associated with the first deformational phase and orientation of muscovite, garnet, quartz and feldspar in these rocks. At this stage, a foliation parallel to the primary bedding (S0) formed. The second metamorphic event which has accompanied with the second deformational phase, caused the formation of microfolds and preferred orientation of muscovite, biotite, garnet and amphibole in the second foliation (S2), but the third event has been acted as retrograde metamorphism that are corresponding to early Cimmerian orogenic phase. Geochemical characteristics of metamorphosed sedimentary rocks in the area suggest a shale origin for them. Correlations between units and lithological variations in stratigraphic columns from north-west to the south-east, indicate that in Gole-Gohar complex (western part of the area), metamorphosed detrital sedimentary rocks are frequent. This means that the primary sediments have been settled in a turbulent shallow environment and the basic magmas have been entered into the basin simultaneously. With the passing of time, toward the east and at the time of the formation of Ruchun complex protolith rocks, sedimentary basin has been deepened more and occasionally, limestone layers were formed between detritic sediments and igneous rocks. Then the basin became very deep and large volume of limestone precipitated during formation of Khabr protolith rocks. At this time, igneous activity had been ceased. Stratigraphic relationships in the studied complex suggest that Gole Gohar complex rocks formed first and placed at deeper levels at the time of the formation of their parental rocks. Therefore, the highest grade of metamorphism occurred at the western part of the area (Gole Gohar complex) and the lowest grade is observed at the eastern part (Khabr complex).
Sanandaj-Sirjan zone,Baft,Gole Gohar complexe,Ruchun complexe,Khabr complexe,Deformational phases,Metamorphosed sedimentary rocks,Metabasites,Metamorphosed impure limestones
http://www.gsjournal.ir/article_53963.html
http://www.gsjournal.ir/article_53963_bb36fc2a4008541ca15043b4afa5a35c.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Petrology and geochemistry of intrusions in the Karaj-Taleghan axis (Central Alborz)
283
294
FA
E.
Keshtkar
Ph.D., Department of Geology, Faculty of Earth Sciences, Shahid Beheshti University, Tehran, Iran
10.22071/gsj.2017.53973
The Intrusive bodies of the Karaj-Taleghan Axis, situated in the Central Alborz zone have lithological compositions including gabbro, monzogabbro, monzodiorite, monzonite andfelsic dikes of alkali feldspar syenite to syenite. Furthermore, they are accompanied by pyroclastic rocks of the Karaj formation, for which Oligocene age is considered. Geological surveys, mineralogical and geochemical studies indicated that the parental magma of this complex had shoshonitic and meta-aluminous nature. Petrological evidence show that fractional crystallization from gabbro to monzonite had main role in genesis of these rocks. Enrichment in LILE) Ba, Rb and Th(and depletion in HFSE (Nb and Ti) in Rare Earth Elements distribution patterns of spider diagrams, indicate an subduction-related environment for formation of these rocks. Also they are enriched in LREE rather than HREE, the characteristics which are usually observed in the rocks from subduction environments and active continental margins. Chemical and petrological studies indicate a common source for these igneous rocks and the main role of fractional crystallization in the evolution of magma, although, minor amounts of assimilation and contamination of magma by crustal rocks occurred. The alkaline magma formed by low degree partial melting of an enriched sub-continental lithospheric garnet-lherzolite mantle. Contribution of both the lithospheric and asthenospheric mantles in petrogenesis of the Karaj-Taleghan basic rocks might be attributed to a tensional geodynamic setting with change in subduction dip in the form of roll back, dominated at the final stage of the subduction of Neotethyan plate beneath Iran in upper Oligocene (Chattian).
Karaj-Taleghan,Gabbro,Monzonite,Karaj formation,Subduction zone
http://www.gsjournal.ir/article_53973.html
http://www.gsjournal.ir/article_53973_c3c89df9e8fcf6ad4150e9eee3adca37.pdf
Geological Survey of Iran
Scientific Quarterly Journal of Geosciences
1023-7429
2645-4963
27
105
2017
11
22
Mineralogy of Mahour Zn-Cu-(Pb-Bi-Ag) deposit, west of Dehsalm: implications for genesis and mineralization type
295
308
FA
S.
Younesi
Ph.D. Student, Department of Earth Sciences, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iran
M. R.
Hosseinzadeh
0000-0002-6319-5840
Associate Professor, Department of Earth Sciences, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iran
mr-hosseinzadeh@tabrizu.ac.ir
M.
Moayyed
orcid 0000-0002-7600
Professor, Department of Earth Sciences, Faculty of Natural Sciences, University of Tabriz, Tabriz, Iran
moayyed@tabrizu.ac.ir
10.22071/gsj.2017.53975
The Mahour Zn-Cu-(Pb-Bi-Ag) deposit located in central Lut Block, formed in an intensely crushed fault zone, dominantly in dacite-rhyodacite volcanic-subvolcanic unit of Late Eocene- Oligocene age. Mineralization occurred as veins, veinlets and breccia massive sulfide and/or as quartz , quartz-carbonate or quartz-muscovite (sericite)- carbonate vein-veinlets. Apart from negligible dark sphalerite, only fine-grained pyrite is observed as disseminated phase within the host rocks. Hypogene mineralization is complex and the main minerals, in order of abundance, are pyrite, Fe-bearing sphalerite and chalcopyrite, with subordinate galena, Cu-sulfosalts, Bi-sulfosalts, Fe-poor sphalerite, and afew greenokite, arsenopyrite, digenite and probably covellite. The Considerable amounts of Ag exist in lattice of some sulfosalt and sulfide minerals, as well as locally negligible Au-bearing W minerals. Mineralization is dominantly associated with sericitic, intermediate argillic and propyllitic alterations and rarely with advanced argillic and quartz- adularia that formed at three main stages including: 1- quartz- pyrite, 2- Fe- bearing sphalerite, and 3- chalcopyrite stage with sulfosalts and minor high sulfidation minerals. Mineralization occurred after silicification and disseminated pyritization that comprise tourmaline (sericitic alteration prior to mineralization) and then weathering process affected it. According to very low dissolution of Cu in Cu-Zn-S equilibrium system, high density of chalcopyrite inclusions in Fe-bearing dark sphalerites in Mahour reveals replacement origin of chalcopyrite disease texture. This texture and mineralogy (ore and alteration) indicate formation of Mahour polymetal mineralization at temperature range of 200-400°C and from an intermediate sulfidation state and low acidity fluid which was neutralized to alkaline by interaction with wall rock. Although, a minor evidence for evolution to high sulfidation state, more acidic and oxidation conditions is recorded in Cu- rich zone. Mineralogical features of the Mahour deposit indicate predominantly magmatic origin for mineralizing hydrothermal fluid, and in combination with mineralization structure, association with calc-alkaline to shoshonitic igneous rocks and tectonic setting of host rocks, are very similar to cordilleran style polymetal lode deposits.
Mineralogy,Microprob,Chalcopyrite disease,Sulfosalt,Intermediate to high sulfidation,Cordilleran Polymetal Lode,Mahour,Lut block
http://www.gsjournal.ir/article_53975.html
http://www.gsjournal.ir/article_53975_088c302c562dc3109351b3f26c9fb6f2.pdf