جستجوی مقالات مرتبط با کلیدواژه "epigenetic" در نشریات گروه "زمین شناسی"

The studied area is structurally located in the western part of the Central Iranian structural zone atthe southwestern termination of the Qom-Zefreh Fault. Our structural data represent the older generation of E-W to NW-SE trending thrust faults that juxtapose Permian- Triassic (Nayband and Shotori Formations) over younger rock units. Most of the thrust faults have been crossed cut with the younger generation of the strike-slip fault system. Major thrust faulting of the area occurred during post Late Cretaceous time. The final post Oligocene strike slip faulting related to the activation of the Qom- Zefreh fault overprinted and crossed cut older structural features. Our economic geological studies in the south Natanz area represent syngeneic strati bond or Sedex-Like type Pb-Zn epigenetic occurrence of these deposits in Permian-Triassic carbonates and barite developed in the Lower Cretaceous carbonate and clastics. The ore deposit development in Permian-Triassic Carbonates have occurred along thrust faults and then redistributed along strike slip faults with normal component. Therefore, genetically, stratiform deposits developed in the Lower Cretaceous carbonates and clastics (Yazdan and Pinavand Ore deposit) occurred in a regional early Cretaceous extensional regime. However, epigenetic deposits developed in Permian-Triassic carbonates (Changarzeh deposit) were generated during the regional post Late Cretaceous compressional regime and redistributed during post Oligocene strike slip deformation.

Oilgocene-Miocene celestite occurrences are observed across the carbonate-evaporite formations of Asmari and Gachsaran in the Zagros fold - thrust belt. The aim of this research is the study of fluid inclusions in our celestite deposits (Tortab, Tarak, Likak and Babamohamad) to reveal the nature of ore-forming fluids. Abundant structures including: geodic and vein-like structures as open-space filling along with replacement textures like mosaic and vein-like in a carbonate matrix are present. Moreover, celestite, calcite, gypsum and anhydrite are observed as the major minerals in this deposits. Based on petrographic studies, 5 groups of fluid inclusions were recognised, which are categorized as: Liquid mono phase (L), vapour mono phase (V), liquid-rich two phase (LV), vapor-rich two phase (VL) and multi-phase fluids (LVS). The results obtained from the study of microthermometry data show 134.3 to 291.8°C as homogenisation temperatures and salinities of 2.5-18.17 wt%, NaCl equ, all are involved in forming celestite. Based on the results of microthermometry data, it can be deduced that formation mechanism of celestite is resulted from reaction between fluid and rocks of the area. Moreover, tectonic activities such as uplift and diagenesis of beds along with dissolution of minerals have caused release of strontium in the fluids responsible for ore-forming. This has generally undertaken by two fluids of meteoric and brine origins over different stages of ore-formation, replacing anhydrite with strontium at high temperatures during late- diagenetic and epigenetic processes.

Rock units in the Madabad celestite deposit are composed of medium to thick-bedded and massive limestone interlayered with marly limestone and marl units of the Qom Formation (lower Miocene). Mineralization occurs as lens-shaped orebody, hosted by limestone units of member of the Qom Formation usually crosscutting bedding of the host rocks. Three stages of mineralization occurred in the Madabad deposit. The first stage is characterized by calcite formation during syn-depositional to syn-diagenesis processes. The second stage is related to hydrothermal processes that are distinguished by formation of fine-grained and sugary crystals of massive stage-1 celestite, vein-veinlets of coarse-grained stage-2 celestite along with minor strontianite and barite, coarse-grained euhedral crystals of stage-3 celestite with vug infilling texture, and finally late-stage quartz and calcite vein-veinlets. Stage three includes supergene processes. Hydrothermal alteration includes dolomitization, calcitization and silicification. Celestite along with minor strontianite and barite are ore minerals, and calcite, dolomite, quartz and iron oxides-hydroxides are gangue minerals at Madabad. The ore minerals show vein-veinlets, vug infilling, brecciated and cataclastic textures. Microthermometric measurements of two-phase liquid-rich fluid inclusions hosted in celestite II indicate that salinities values range from 6 to 18 wt.% NaCl equiv. (avg. 10.6 wt.% NaCl equiv.). These inclusions have homogenization temperatures range from 248 to 365 °C, with an average of 278 °C. These data indicate a minimum trapping depth of 510 m for the Madabad deposit. Sr was originated from evaporate units within the marly parts of the Qom Formation and volcanic units of the Karaj Formation. Characteristics of the Madabad deposit are similar to epigenetic replacement celestite deposits.

The Borujerd-Kermanshah ophiolite is a part of the ophiolite complex belonging to the Zagros Mountains and is a part of the Alpes-Himalayan belt (Alavi, 1994). The Boroujerd-Kermanshah Ophiolite complex consists of serpentinized peridotite, layered metagabbro, isotropic gabbro, diabase dyke, plagiogranite, pillow lavas and sedimentary rocks (Miocene radiolarite and limestone). In the upper part, the radiolarite layers are covered by jasperoid rocks and pelagic limestone (Mohajjel et al., 2003; Saccani et al., 2013). The Noorabad Delfan manganese deposit is subjected to mineralogical and geochemical studies in order to elucidate its petrogenesis. The Noorabad Delfan manganese deposit is located along the ophiolite belt of the upper Jurassic-lower Cretaceous period. Manganese mineralization occurs as syngenetic to epigenetic with jasperoid and silicified veins in the carbonate and radiolarian chert units. Geochemical studies show that some elements such as Ce, Cu, Ni are enriched in the mineralized zone. Mobile and trace elements (Sr, As, Zn, Ba, Fe, Mn, Si) and the ratio of Mn/Fe, Al/Ti, show similar characteristics with submarine hydrothermal-hydrogenous manganese deposits. In geochemical studies, SEM, XRD and EPMA results show that pyrolusite is the majar mineral in the ore deposit, and nsutite and rhodochrosite are formed as the accessory phase.

During the field work, 53 samples were collected from the mineralization zone and host rocks. A total of 30 polished and thin sections were studied by Zeiss polarized microscope (Axioplan-2), in the Kharazmi University and the Iran Mineral Processing Research Center (IMPRC). Suitable sections were selected for more study by Zeiss 1450vp SEM at the Iranian Mineral Processing Research Center (IMPRC). The SEM-EDS analyses and secondary electron (SEM-SE) images at the IMPRC were acquired on beam currents between 0.05 and 5 nA, and electron acceleration potentials of 5 to 20 kV. The Electron microprobe analysis of selected points by SEM was carried out using a Cameca SX100 at IMPRC in the 20 kV and 20 nA current and 1 to 5 mm beam long. The Cameca PAP correction software was used for data reduction. Backscattered electron images were used in order to select more analytical points. A total of 15 samples were selected for whole rock chemical analysis. Samples were prepared with regular methods and finally they were analyzed for major and rare elements by the XRF and ICP-MS methods in Zarazma and Iran Minerals Processing Research Center Laboratory.

Manganese deposits with hydrothermal origin are usually related to silica gels. These deposits are associated with submarine volcanic eruptions and hydrothermal-hydrogenous activity and they are rich in metal elements. This kind of deposits, is basically emplaced with interlayer marine sediments (Roy, 1992). Titanium in the hydrothermal fluids is an immobile element and can be used as an indicator for measuring the amount of continental crest sediment. The relatively high TiO2 levels in the manganese deposits indicate the composition of the material during sedimentation (Sugisaki, 1984). Therefore, in the hydrothermal deposits, the TiO2 ratio is lower than other kinds of manganese ore mineralization types. Nicholson (Nicholson, 1992a) believes that hydrothermal manganese deposits are known by enrichment of As, Ba, Cu, Pb, Sb, Sr, Li, Cd, Mo, V, Zn, Co, Cu, Ni and sedimentary deposits are distinguished by K, Na, Ca, Mg, Sr (Nicholson, 1992b). According to this statement, the manganese mineralization of the Noorabad Delfan deposit may be classified as hydrothermal to hydrogenous ore deposits related to oceanic crust ophiolitics.

The Noorabad Delfan deposit with 5 km long is formed in radiolarite sequences in the west of Iran. Based on field observation, mineralogy and geochemistry and the major/trace and rare elements ratio, Noorabad Delfan mineralization is classified as a hydrothermal-hydrogenous deposit. In the study area, the manganese mineralization is formed with interlayer of radiolarite as syngenetic to epigenetic mineralized zones.The hydrothermal systems are generated by submarine volcanic activity and seawater. Due to the rotation of submarine volcanic activity related fluids, the hot oceanic water carries metalliferous phases. The metalliferous phase has been deposited during cooling, pressure reductions and Eh-pH changes. The hydrothermal to hydrogenous activity is the main factor in manganese mineralization in the Noorabad Delphan deposit. Mineralogical and geochemical evidences support a primary hydrothermal source for Mn-mineralization.

Base-metals sulfide mineralization in Galena and sphalerite forms with little amount of pyrite, in Mobarak and Elika formation have been occurred in the studied region. Chemically, all deposit phases have compositing hemogen region. Mineralization has been followed the fault general process in the region, and the main textures in the ore are vein texture and open space filing. Genetically, studied deposits are epigenetic. Field features essentially have resulted mineralogical investigations and geochemical surveys on trace elements and rare earth elements (REE), they have included ore metals source in sulfide Pb-Zn mineralization in Kelardasht region showed carbonate - hosted mineralized rocks (upper Paleozoic, lower Triassic) in deposit. In genetic relation between Pb-Zn mineralization in this deposit with Akapol monzonit quartz - monzodiorite intrusion (aged to upper Eocene - lower Paleocene), Were located near to studied Pb-Zn deposits, Akapol intrusion have played as required heating source that heated ore fluids. According to Eu negative anomalies in ore and host rock samples,and were seemed The source of hydrothermal fluids in the studied region have been the surface and atmospheric full - oxygen water (meteoric) have been warm through closing Akapol intrusion and have been solved the elements and then have been deposited them in the host rock fault crushes, cracks and joints, and then circulation in base-metals have enriched carbonate hosted units.