نرم افزار میکروسکوپ مجازی: جهت شناسایی کانی ها در زیر میکروسکپ

شناسایی کانی ها در مقاطع نازک میکروسکوپی از دغدغه های دانشجویان در حین تحصیل و کارشناسان در حین کار است. به کمک این نرم افزار مشخصات نوری حدود 100 کانی را در نور طبیعی و پلاریزه می توانید ببینید. از سایت فارسروئید بخاطر ارائه این نرم افزار و از آقای آندره آپوپر سازنده آن تشکر می کنم.

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جهت استفاده حتما ضروری است که دیتابیس نرم افزار را در فولدر Android/Data و Obb قرار دهید.

نرم افزار سیکلولاگ و کاربرد آن در سکانس استراتیگرافی

قصد از این نوشتار کوتاه آموزش نرم افزار سیکلولاگ نیست زیرا کما بیش دوستان در مورد این نرم افزار می دانند. در این پست ضمن معرفی و ارائه کتاب چینه شناسی اقلیمی به اشتباهی رایج در تعیین سطوح کلیدی سکانسی در باره نرم افزار سیکلولاگ اشاره می شود.

کتاب چینه شناسی اقلیمی نوشته نیو و همکاران (2014) می باشد که در مورد چرخه های رسوبی موجود در توالی چینه شناسی، نحوه زایش و شناسایی آنها بحث می کند. به بهانه این موضوع نویسندگان نسبت به معرفی نرم افزار سیکلولاگ و نحوه کاربرد آن در تعیین سطوح کلیدی سکانسی و استفاده آن در تطابق می پردازند. این کتاب را از لینک موجود در عکس یا اینجا می توانید دانلود کنید.

اگرچه امروزه توسعه دهندگان نرم افزار سیکلولاگ اشاره دارند که این نرم افزار برای تطابق توالی های رسوبی مناسب است و تأکید ویژه ای به کاربرد آن در سکانس استراتیگرافی (بویژه در توالی های کربناتی) ندارند ولی باید اذعان کرد تجربه نشان داده است که این روش در توالی های آواری ممکن است کاربرد خوبی داشته باشد.

موضوع مهمی که به نظر می رسد در بیشتر مقالات داخلی و حتی خارجی به اشتباه تکرار می شود نحوه ارتباط دادن سطوح تعیین شده در منحنی INPEFA به سطوح اصلی سکانسی است. در واقع سطوح NBS (پیک به طرف مثبت یا سطح تغییر روند مثبت شدگی به روند منفی شدگی در منحنی INPEFA) معرف سطوح فرسایشی و نماینده خوبی از سطوح سکانسی (SB) است. درحالیکه سطوح PBS ( پیک به طرف مقادیر منفی یا سطح تغییر روند منفی شدگی به مثبت شدگی در منحنی INPEFA) نمایانگر سطوح آنلپ و غرقابی سکانسی (mfs) است. این درحالی است که در بیشتر مقالات داخلی این امر معکوس اجرا می شود و سطوح NBS به اشتباه به mfs و سطوح PBS به اشتباه به SB نسبت داده می شود. شکل زیر اشاره به تعیین صحیح این سطوح دارد (رجوع شود به صفحات 74 تا 77 این کتاب). لطفاً بعد از خواندن این بخش از کتاب نظر خود را درج نمایید.

 

اطلس رنگی سنگ های تخریبی (2014)

اطلس رنگی سنگ های تخریبی (2014)

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چهار مقاله مهم در زمینه مخازن نفتی و گازی زاگرس و خلیج فارس

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دانلود مقاله "شکستگی های طبیعی در مخازن کربناتی جنوب باختری ایران"

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Geological reservoir characterization of the Lower Cretaceous Dariyan Formation (Shu'aiba equivalent

Geological reservoir characterization of the Lower Cretaceous Dariyan Formation (Shu'aiba equivalent) in the Persian Gulf, southern Iran

Hamzeh Mehrabi, Hossain Rhimpour, Elham Hajikazemi, Behrooz Esrafili-Dizaji

The Aptian carbonate reservoirs of Persian Gulf, known as the Dariyan Formation (Shu'aiba equivalent), are among the most important oil reservoirs of Iran. Despite its significance, a little is known about the facies characteristics, diagenetic history, sequence stratigraphy, and reservoir quality of this formation. Using the new core data, this study presents an integrated geological reservoir characterization of this formation in four giant fields in the Persian Gulf. Using the results of the facies analysis it could be suggested that this unit formed in a shallow carbonate platform surrounding intra-shelf basins of Kazhdumi and Bab in the western and eastern Persian Gulf, respectively. A major relative sea-level fall in the Late Aptian resulted in exposure of this unit and subsequent clastic influx as well as meteoric diagenesis. This phase of meteoric diagenesis has resulted in some important diagenetic features, special geochemical trends, and considerable variations in reservoir quality of the Dariyan Formation. Sequence stratigraphic interpretation of this formation has resulted in the recognition of 2nd and 3rd order depositional sequences in the studied wells. They are closely correlated across the studied wells in the Persian Gulf, SW Iran, and other places in the Arabian Plate. Reservoir characterization has revealed that the high quality units are positioned at two stratigraphic intervals in the concerned reservoir. The first reservoir zone is located beneath the unconformity surfaces, where meteoric dissolution of grain-to mud-dominated facies has resulted in considerable amounts (10–40%) of vuggy, moldic, and micro-porosity in the highstand systems tracts (HSTs). The second reservoir zone of this formation has formed within the Lithocodium-algal facies, floatstone and boundstone, of inner ramp setting. The latter reservoir facies are mainly concentrated within the fields of the eastern Persian Gulf.

Characterization of rudist-dominated units as potential reservoirs in the middle Cretaceous Sarvak F

Characterization of rudist-dominated units as potential reservoirs in the middle Cretaceous Sarvak Formation, SW Iran

Behrooz Esrafili-Dizaji, Hossain Rahimpour-Bonab, Hamzeh Mehrabi, Samineh Afshin, Farkhondeh Kiani Harchegani, Nayyer Shahverdi

The Sarvak reservoirs are characterized by thick rudist-dominated intervals in the south and southwest Iran. During the middle Cretaceous, rudistid communities were widely developed on the shallow parts of the Sarvak platform, mainly in the central Zagros and eastern Persian Gulf. Regional distribution and subsequent diagenesis of the rudist-dominated facies were strongly controlled by a number of paleostructures (i.e., fault-related paleohighs and salt domes) in the area. Facies analysis in 16 Sarvak reservoirs reveals the rudistid units can be classified into three main facies groups, developing thick depositional cycles in the Sarvak Formation. Integrated petrographic and geochemical data shows the rudist-dominated facies were subjected to fresh water diagenesis caused by a considerable drop in relative sea level after the deposition. Subsequently, where they were subaerially exposed over the crests and flanks of the paleohighs, the initial porosity of the rudist facies was enhanced by extensive meteoric dissolution (types A and B). Farther away from the paleohighs, same facies have poor reservoir quality, because the porosity was reduced by meteoric and shallow to deep burial cements, and mechanical/chemical compaction (type C). Despite their deep burial depth, significant amounts of porosity (>10 %) are still preserved in the rudist-dominated facies of the Sarvak Formation, especially below disconformity surfaces. Results of this study reveal the controls of early diagenesis on later diagenetic modification and porosity evolution in the Sarvak Formation, as the second important oil-producing reservoir of Iran.

Controls on Reservoir Quality in the Early Triassic Kangan Formation, Iran

Controls on Reservoir Quality in the Early Triassic Kangan Formation, Iran

B. Esrafili-Dizaji, F. Kiani Harchegani, H. Rahimpour-Bonab and M.R. Kamali

 

The Early Triassic Kangan Formation is one of the most prolific gas reservoirs in Iran. The formation consists in two reservoir units: K2 and K1 in the area of investigation. Ten facies are distinguished in the Kangan Formation. These facies are interpreted as peritidal, lagoonal, shoal and fore shoal deposits. Two depositional sequences, Khuff sequence-2 (KS-2) and KS-1 are differentiated based on facies stacking patterns. Detailed diagenetic studies suggest that the Kangan sequence was exposed to early diagenesis after deposition. Two styles of early diagenetic processes are interpreted: dissolution with cementation (type A) and dolomitisation with anhydrite plugging (type B). Differences in early diagenesis are interpreted as a function of palaeosalinity on the platform. This in turn is controlled by relative sea-level fluctuations and palaeoclimatic conditions. The Kangan Formation is now buried at over 2.7 km and exposed to temperatures of about 100°C. This study indicates that the spatial and temporal development of fracturing and stylolites (types, diversity and frequency) are related to early diagenetic modifications. Our investigations conclude that the pattern and intensity of burial diagenetic and reservoir quality are mainly controlled by primary textural variation in the Kangan Formation.

A review of Permo‐Triassic reservoir rocks in the Zagros area, SW Iran

A review of Permo‐Triassic reservoir rocks in the Zagros area, SW Iran: influence of the Qatar‐Fars Arch

 B Esrafili‐Dizaji, H Rahimpour‐Bonab

2013; Journal of Petroleum Geology

Abstract: Four “supergiant” and numerous giant gasfields have been discovered in the Zagros area of SW Iran. The gasfields are concentrated in the eastern part of the foldbelt, in Fars Province and the adjacent offshore, and produce from Permo-Triassic carbonates equivalent to the Khuff Formation. The carbonates belong to the upper member of the Dalan Formation and the overlying Kangan Formation. Reservoir rock quality is strongly influenced by tectonic setting and depositional environment, and also by diagenesis. The highest quality reservoirs occur in oolitic shoal facies; fracturing (especially in onshore fields) and dolomitisation (in offshore fields) have also influenced reservoir quality. Anhydrite plugging is common in reservoirs in offshore fields, while calcite cementation is dominant in onshore reservoirs. Facies variations in the Dalan-Kangan Formations appear to correspond to syndepositional palaeohighs and depocentres. In the Eastern Zagros (Fars area), thickening of the Dalan Formation corresponds to a Mid-Late Permian depocentre referred to here as the Permian Fars Basin. As a result of sea level fall, this depocentre evolved into a hypersaline lagoon with evaporite deposition (Nar Member). In the Triassic, the depocentre evolved into a palaeohigh as indicated by thinning and facies changes in the Kangan Formation. The results of this study draw attention to variations in the reservoir quality of the Dalan-Kangan Formations. Much of this variation was due to the influence of the Qatar-Fars Arch.

DOLOMITIZATION AND ANHYDRITE PRECIPITATION IN PERMO-TRIASSIC

DOLOMITIZATION AND ANHYDRITE PRECIPITATION IN PERMO-TRIASSIC CARBONATES AT THE SOUTH PARS GASFIELD, OFFSHORE IRAN: CONTROLS ON RESERVOIR QUALITY

H Rahimpour‐Bonab, B Esrafili‐Dizaji, V Tavakoli

Journal of Petroleum Geology 33 (1), 43-66

 

Abstract : Dolomitization and related anhydrite cementation can complicate the characterization of carbonate reservoirs. Both processes have affected the Permo-Triassic Upper Dalan – Kangan carbonates, the main reservoir at the South Pars gasfield, offshore Iran. The carbonates were deposited in a shallow-marine ramp or epeiric platform and, according to previous studies, underwent intense near-surface diagenesis and minor burial modification. Detailed petrographical and geochemical analyses indicate that dolomitization and anhydrite precipitation can be explained in terms of the sabkha/seepage-reflux models. The early dolomites then re-equilibrated or re-crystallized in a shallow burial setting. Evaluation of poroperm values in different reservoir intervals indicates that replacive dolomitization in the absence of anhydrite precipitation or with only patchy anhydrite has enhanced the reservoir quality. Where anhydrite cement is pervasive and has plugged the rock fabric, poroperm values are significantly decreased. As emphasized in previous studies and confirmed here, dolomitization and anhydrite cementation, together with original facies type, are the major factors controlling reservoir quality in the Dalan – Kangan carbonates at South Pars. When associated with minor anhydrite cementation, replacive dolomitization has enhanced reservoir quality by increasing permeability. However, porosity in fabric-retentive dolomite was apparently inherited from the precursor rock and therefore reflects the original depositional environment.Low-temperature dolomitization is commonly fabric-selective and partially fabric-retentive. Whole rock stable isotope thermometry indicates that fabric-destructive dolomites in the reservoir rocks formed at temperatures above 22°C, whereas fabric-retentive dolomites and associated anhydrites formed in surface and near-surface conditions. Fabric-destructive dolomite or dolomite neomorphism post-date fabric-retentive dolomite and continued to form in deep burial conditions (∼1400m). These observations may explain why fabric-retentive dolomite and anhydrite fabrics are traversed by stylolites.