ispg-140503200714050320075720CMV Verlagkhoffmann@cmv-verlag.comCMV VerlagIranian Journal of Petroleum Geologyispg2251-8738122520221121AtefehChenaraniMeysamShafiee ArdestaniMohammadVahidinia12252022789710.52547/ispg.33928.11.21.78http://journal.ispg.ir/fa/Article/33928http://journal.ispg.ir/fa/Article/Download/33928http://journal.ispg.ir/fa/Article/Download/33928http://journal.ispg.ir/fa/Article/Download/33928http://journal.ispg.ir/fa/Article/Download/33928http://journal.ispg.ir/fa/Article/Download/33928http://journal.ispg.ir/fa/Article/Download/33928http://journal.ispg.ir/fa/Article/Download/3392811.منابع[1]افشار حرب، ع.، 1373: زمین شناسی کپه داق، طرح تدوین کتاب سازمان زمین شناسی کشور، 275 صفحه.[2] توکلی راحله، آقانباتی سید علی 1388. بررسی و مقایسه رسوبات کرتاسه زیرین در دو حوضه رسوبی کپه داغ و ایران مرکزی. فصلنامه علوم زمین. سال نوزدهم. شماره 73، صفحه 115 تا 122. [3] شامیر مهسا، صادقی عباس، برزی محبوبه، جمالی امیر محمد 1395. رخساره ها و محیط های رسوبی سازند تیرگان در برش چینه شناسی بیگان، کپه داغ غربی. مجله علمی- پژوهشی اکتشاف نفت صفحات 38 تا 43. [4] ریوندی بتول، نجفی مهدی، موسوی حرمی سید رضا ، محبوبی اسدالله، وحیدی نیا محمد 1389. رخساره های رسوبی و چینه نگاری سکانسی سازند تیرگان در شرق حوضه کپه داغ ( دره خور، شمال شرق مشهد). مجله رخساره های رسوبی، تابستان 1389. 3 (1) : 23-34. [5] ریوندی بتول، نجفی مهدی، موسوی حرمی سید رضا، محبوبی اسدالله، وحیدی نیا محمد 1389. چینه نگاری زیستی سازند تیرگان در ناحیه جوزک و چمن بید واقع در غرب حوضه رسوبی کپه داغ. مجله پژوهش های چینه نگاری و رسوب شناسی دانشگاه اصفهان. 4 (2) 33-50.[6] جوانبخت محمد، موسوی حرمی سید رضا، محبوبی اسدالله 1392. تاریخچه رسوب گذاری و چینه نگاری سکانسی سازند تیرگان ( بارمین- آپسین) در نواحی غربی و مرکزی کپه داغ، شمال شرق ایران. نشریه علمی پژوهشی رخساره های رسوبی. پاییز و زمستان 1392، 6 (2) : 162- 185.[7] جمالی محمد، 1390. بایواستراتیگرافی و لیتواستراتیگرافی نهشته های کرتاسه زیرین در شرق کپه داغ، پایان نامه دکتری، دانشگاه شهید بهشتی، 446 ص. [8] چنارانی، عاطفه 1390. بایواستراتیگرافی سازند تیرگان در برش روستای سررود، شرق حوضه رسوبی کپه داغ. پایان نامه کارشناسی ارشد. 131 صفحه.[9] خاکستری معصومه، محمودی قرایی محمد حسین، موسوی حرمی سید رضا 1392. بررسی تنوع فابریک اائید ها سازند تیرگان و ارتباط آنها با تغییرات سطح آب دریا در برش روستای باغک واقع در شرق حوضه کپه داغ. هفدهمین همایش انجمن زمین شناسی ایران ( 7 تا 9 آبان ماه 1392). [10] مرادیان الهه، آریایی علی اصغر، ترشیزیان حبیب الله 1392. رخساره ها و محیط رسوبی سازند تیرگان در برش امام قلی ( شمال قوچان). سی و دومین گرد همایی و نخستین کنگره بین المللی تخصصی علوم زمین 27 تا 30 بهمن ماه 1392( زمین شناسی بنیادی- مشهد). [11] مرتضوی مهریزی 1386. چینه نگاری سکانسی سازند های شوریجه و تیرگان ( کرتاسه زیرین) در ناحیه سفید سنگ ( شمال شرق فریمان). پایان نامه کارشناسی ارشد. دانشگاه فردوسی مشهد، 180 صفحه. [12] منصوری حسن، وحیدی نیا محمد، نجفی مهدی 1393. بایو استراتیگرافی و میکروفاسیس بخش بالایی سازند تیرگان و بخش قاعده ای سازند سرچشمه در برش چینه شناسی پیغو غرب حوضه رسوبی کپه داغ. پایان نامه کارشناسی ارشد. دانشگاه فردوسی مشهد. 106 صفحه. [13] محمدی مریم، خانه باد محمد، محبوبی اسدالله، موسوی حرمی سید رضا 1392. بررسی و طبقه بندی انواع اائید های سازند تیرگان در شرق حوضه کپه داغ ( برش آرتنج و قرقره در ناحیه بزنگان، شمال شرق مشهد. هفدهمین همایش انجمن زمین شناسی ایران( 7- 9 آبان ماه 1392). [14] موسویان، س. .، صادقی، ع.، آدابی، .ح.، 1393 . چینه نگاری سنگی، زیستی و رخسارههای رسوبی سازند شاه کوه در برشکوه تنگل بالا، جنوب غرب خور )ایران مرکزی(، پووهشهای چینه نگاری و رسوب شناسی، 54 ( 1 :) 79 - 95[15] موسوی زاده ع، محبوبی اسدالله، موسوی حرمی سید رضا، نجفی مهدی 1386. تاریخچه رسوب گذاری چینه نگاری سکانسی سازند تیرگان در جنوب غرب روستای جوزک و چمن بید در غرب حوضه رسوبی کپه داغ. مجموعه مقالات یازدهمین انجمن زمین شناسی ایران، صفحه 60. [16] مهرنوش، م و پرتو آذر، ح 1977. اطلس میکروفسیل های برگزیده ایران، سازمان تحقیقات زمین شناسی و معدنی کشور، گزارش 33-2536، 396 صفحه.[17] هاشمی کاخکی ن 1385. تحول زمین شناسی و بررسی چینه شناسی و میکروفاسیس اورگونین سازند تیرگان در حوضه کپه داغ. پایان نامه کارشناسی ارشد. دانشگاه آزاد اسلامی، 110 صفحه. [18] قربان پور اول فاطمه، آریایی علی اصغر، عاشوری علیرضا 1392. بررسی میکروفاسیس سازند تیرگان در برش تیوان. سی و دومین گردهمایی و نخستین کنگره بین المللی تخصصی علوم زمین. 27 تا 30 بهمن ماه ( زمین شناسی بنیادی- مشهد). [19] طاهرپور خلیل آباد، م. 1392 . چینه نگاری سنگی و ریز چینه نگاری زیستی (روزن داران و جلبک های آهکی) سازند تیرگان در حوضه رسوبی کپه داق، شمال شرق ایران. پایان نامه دکتری دانشگاه آزاد اسلامی. [20] طاهر پور خلیل آباد مرتضی، وزیری سید حمید، آریایی علی اصغر، عاشوری علیرضا، مجتهدین الهام 1392. تعیین مرز زیست چینه ای بارمین پسین-آپتین پیشین در توالی های کرتاسه زیرین برای اولین بار در غرب حوضه رسوبی کپه داغ. سی و دومین گرد همایی و نخستین کنگره بین المللی تخصصی علوم زمین ( 27 تا 30 بهمن ماه 1392). زمین شناسی بنیادی- مشهد. [21] طاهر پور خلیل آباد مرتضی، وزیری سید حمید، آریایی علی اصغر، عاشوری علیرضا. 1393. کاربرد روزن داران کف زی و جلبک های آهکی در تعیین مرز بارمین-آپتین: مطالعه موردی سازند تیرگان در غرب حوضه رسوبی کپه داغ. نشریه علمی-پژوهشی دیرینه شناسی. پاییز و زمستان 1393. 2: 180-197. [22] ARNAUD- VANNEU, A 1980. Micropaleontologie , paleoecologie et sedimentologied une platforme carbonate de la marge passive de la Tethys, Geology alpine, V 11 , P. 867-874.[23] ARNAUD, H., ARNAUD-VANNEAU, A., (1991). Les Calcaires urgoniens des Massifs subalpinsseptentrionaux et du Jura (France): âge et discussion des données stratigraphiques. Géologie Alpine 67, 63-79.[24] BACHMANN, M, HIRSCH, F 2006. Lower Cretaceous Platform of the eastern Levant ( Galilee and Golan Heights): Stratigraphy and second-order sea level change, Cretaceous Research, V.27, P. 487-512.[25] BASSOULLET , J P, BERNIER P , CONRAD , M.A, DELOFFRE , R and JAFFREZO M, 1978. Les Algues Dasycladales du Jurassique et du Cretace. Geobios, Mem. Sp, v.2, p.1-33.[26] BUCUR, I.I., MAJIDIFARD, M.R., and SENOWBARI-DARYAN, B., 2013. Early Cretaceous calcareous benthic microfossils from the eastern Alborz and western Kopet Dagh (northern Iran) and their stratigraphic significance. Acta Palaeontologica Romaniae, 9 (1): 23-37.[27] CARRAS, N , CONRAD M.A and RADOICIC , R, (2006). Salpingoporella, a common genus of Mesozoic Dasycladales ( Calcareous green algae) Revue de paleobiologie, v.25. ( 2), P.457-517. [28] CAREVIĆ, I., and ET AL., (2013). Comparisons between the Urgonian platform carbonates from eastern Serbia (Carpatho-Balkanides) and northeast Iran (Kopet-Dagh Basin): Depositional facies, microfacies, biostratigraphy, palaeoenvironments and palaeoecology. Cretaceous Research 40:110-130.[29] CONRAD M.A., and PEYBERNÈS, B., 1976. Hauterivian-Albian Dasycladaceae from Urgonian limestones in the French and Spanish eastern Pyrenees. Geologica romana, XV: 175–197.[30] ELLIS, B., and MESSINA, A., 1941- 2009. Catalogue of Foraminifera, Museum Natural History, Special publication.Javanbakht M , Ghazi S , Moussavi-Harami R, Mahboubi, A. 2013. Depositional history and sequence stratigraphy of Tirgan Formation ( Barremian-Aptian) in Central Kopet Dagh, NE, Iran. Journal of the Geological society of India. V32, I 6, pp 701-711. [31] GRADSTEIN, F., M., OGG, J., G., SMITH, A., G., 2004. A geologic time scale 2004. Cambridge University Press, 589 p .[32] GRANIER, B., 2013- Dissocladella hauteriviana MASSE in MASSE et al., 1999 (non MASSE, 1976), another lower Urgonian Dasycladalean algarevisited. Carnets de Geologie, Letter 2013/07 (CG2013-L07): 1-9.[33] GOVINDAN A 2008. Paleobiogeography of cretaceous and tertiary larger foraminifera and paleo-seas: proceeding of the international symposia on geoscience resources and environments of asia terranes, November 24-26,2008, Bangkok, Thailand.[34] HENSON, F.R.S., (1948). Larger imperforate Foraminifera of southwestern Asia. Families Lituolidae, Orbitolinidae and Meandropsinidae. British Museum (Nat Hist), London, 126 p.[35] HUSINEC, A., VELIC, I., FUCEK, L., VLAHOVIĆ, I., MATICEC, D., OSTRIC, N.,AND KORBAR, T., 2000. Mid CretaceousOrbitolininid( Foraminiferida) record from the islands of Cres and Losing (Croalia). Cretaceous Research ,v. 21 , p.155-171 .[36] HUSINEC, A. and SOKAC, B., 2006- Early Cretaceous benthic associations (foraminifera and calcareous algae) of a shallow troPlcal-water Piatform environment (Mljet Island, southern Croatia), Cretaceous Research, 27:418–441.[37] KALANTARI, A., (1969). Foraminifera from the Middle Jurassic-Cretaceoussuccessions of the Koppet-Dagh region (N.E. Iran). Nat Iran OilCompany Geol Lab Publ 3:1–298.[38] LOEBLICH, A. R., and TAPPAN, H., 1988. Foraminiferal Genera and their Classification, Van Nostrand Reinhold Co.,New York .970 p.[39] MOLAEI M , VAZIRI H , TAHERPOUR KHALIL ABAD M, TAHERI J, 2017. Early cretaceous Neotrocholina Reichel , 1956 from the Tirgan Formation, Kopet Dagh sedimentary basin, NE Iran. Systematic and biometric interpretation. Arabian Journal of Geosciences.[40] SAINT-MARC, P., 1970. Contribution à la connaissance du Crétacé basal au Liban. Revue de Micropaléontologie, 12 (4): 224-233.[41] SCHLAGINTWEIT, F., BUCUR, I.I., RASHIDI, K., and SABERZADEH, B., 2013. Praeorbitolina claveli n.sp. (benthic Foraminifera) from the Lower Aptian sensu lato (Bedoulian) of Central Iran. Carnets de Géologie [Notebooks on Geology], Brest, 2013/04 (CG2013-L04): 255-272.[42] SCHROEDER, R .,1963. Palorbitolina, einneues subgenus der gattung orbitolina (Foram). Neues . Jahrbuch Fur. Geologie und paläontologie. Monatsh.,v.117, p. 346-359.[43] SCHROEDER, R., CHERCHI, A., GUELLAL, S., and VILA, J.M., 1978. Biozonation par les grands foraminifères du Jurassique supérieur et du Crétacé inférieur et moyen des séries néritiques en Algérie du Nord-Est.- Considérations paléobiogéographiques. Annales des Mines et de la Géologie [Actes du VIe Colloque Africain de Micropaléontologie - Tunis 1974], 28 (2): 243-253.[44] SCHROEDER, R., VAN BUCHEM, F.S.P,, CHERCHI, A., BAGHBANI, D.,VINCENT, B.,IMMENHAUSER. A., and GRANIER, B.,2010. Revised orbitolinid biostratigraphic zonation for The Barremian- Aptian of the eastern Arabian plate and implications for regional stratigraphic correlations Geoarbia special publications, v. 4 (1),p. 49-96.[45] SIMMONS, M.D., 1994. Micropalaeontological biozonation of the Kahmah Group (Early Cretaceous), Central Oman Mountains. In: Simmons, M.D., (ed.), Micropalaeontology and Hydrocarbon Exploration in the Middle East. Chapman & Hall, London, 177-219.[46] TAHERPOUR KHALI ABAD, M., SCHLAGINTWEIT, F., ASHOURI, A.R., and ARYAEI, A.A., 2009. Juraella bifurcata BERNIER, 1984 (Calcareous alga Gymnocodiaceae?) from the Lower Cretaceous (Barremian) Tirgan Formation of the Kopet Dagh basin, north-east Iran, Journal Of Alpine Geology, 51: 79-86.[47] TAHERPOUR KHALILABAD M, ARYAEI A , ASHOURI A, GHADERI A 2011. Introducting some echinoderms from the Tirgan Formation Kopeh- Dagh basin, Ne of Iran. Jgeope 1 (1), 2011, p 83-94.[48] TAHERPOUR KHALIL ABAD, M., SCHLAGINTWEIT, F., VAZIRI, S.H., ARYAEI, A.A., and ASHOURI, A.R., 2013. Balkhania balkhanica Mamontova, 1966 (benthic foraminifera) and Kopetdagaria sphaerica Maslov, 1960 (dasycladale alga) from the Lower Cretaceous Tirgan Formation of the Kopet Dagh mountain range (NE-Iran) and their palaeobiogeographic significance. Facies, 59: 267-285. [49] VELIC, I., 2007. Stratigraphy and Palaeobiogeraphy of Mesozoic Benthic Foraminifera of the Karst Dinarides (SE Europa) Geologia Croatica, v. 60 (1), p. 1-113 .[50] YAVARMANESH H, VAZIRI1 S.H , ARYAEI A , JAHANI D, POURKERMANI1 M, KHADEMI BOURIABADI E. 2017. Benthic Foraminiferal and Calcareous Algae Assemblages in the Tirgan Formation (Urgonien Facies Type) in South Flank ofGhorogh Syncline (North of Chenaran), NE Iran. Open Journal of Geology, 2017, 7, 796-805MahdiKheirollahiGolnaz JozanikohanRezaMohebianAliMoradzadeh1225202211510.52547/ispg.38414.11.21.1http://journal.ispg.ir/fa/Article/38414http://journal.ispg.ir/fa/Article/Download/38414http://journal.ispg.ir/fa/Article/Download/38414http://journal.ispg.ir/fa/Article/Download/38414http://journal.ispg.ir/fa/Article/Download/38414http://journal.ispg.ir/fa/Article/Download/38414http://journal.ispg.ir/fa/Article/Download/38414http://journal.ispg.ir/fa/Article/Download/38414 A. Kadkhodaie and R. Kadkhodaie, “A Review of Reservoir Rock Typing Methods in Carbonate Reservoirs: Relation between Geological, Seismic, and Reservoir Rock Types,” Pet. Eng. Iran. J. Oil Gas Sci. Technol., vol. 7, no. 4, pp. 13–35, 2018, [Online]. Available: http://ijogst.put.ac.ir. N. Bize-forest, V. Baines, A. Boyd, A. Moss, and R. Oliveira, “Carbonate Reservoir Rock Typing and the Link Between Routine Core Analysis and Special Core Analysis,” Sca, pp. 1–6, 2014. J. S. Gomes, M. T. Ribeiro, C. J. Strohmenger, S. Negahban, and M. Z. Kalam, “Carbonate reservoir rock typing - The link between geology and SCAL,” Soc. Pet. Eng. - 13th Abu Dhabi Int. Pet. Exhib. Conf. ADIPEC 2008, vol. 3, pp. 1643–1656, 2008, doi: 10.2118/118284-ms. E. A. Clerke, D. Ph, and S. Aramco, “SPE 126086 Electrofacies and Geological Facies for Petrophysical Rock Typing : Khuff C,” no. May, pp. 9–11, 2009. T. O. Services, T. O. Services, T. O. Services, and T. O. Services, “SPE 163294 Rock Typing and Characterization of Carbonate Reservoirs : A Case Study from South East Kuwait,” no. December, pp. 10–12, 2012. P. Mukherjee, D. Singharay, S. Matar, and D. M. A. Meshari, “Rock-Typing : An Integrated Reservoir Characterization Tool for Tight Jurassic Carbonates , West Kuwait *,” vol. 70372, 2018, doi: 10.1306/70372Mukherjee2018. Y. Liu et al., “Petrophysical static rock typing for carbonate reservoirs based on mercury injection capillary pressure curves using principal component analysis,” J. Pet. Sci. Eng., vol. 181, no. January, p. 106175, 2019, doi: 10.1016/j.petrol.2019.06.039. S. N. A. Al-Jawad, M. A. Ahmed, and A. H. Saleh, “Integrated reservoir characterization and quality analysis of the carbonate rock types, case study, southern Iraq,” J. Pet. Explor. Prod. Technol., vol. 10, no. 8, pp. 3157–3177, 2020, doi: 10.1007/s13202-020-00982-6. M. Skalinski, J. A. M. Kenter, M. Skalinski, and J. A. M. Kenter, “Geological Society , London , Special Publications Online First Carbonate petrophysical rock typing : integrating geological attributes and petrophysical properties while linking with dynamic behaviour Carbonate petrophysical rock typing : integrating geo,” 2014, doi: 10.1144/SP406.6. L. Saputelli, R. Celma, D. Boyd, H. Shebl, J. Gomes, and F. Bahrini, “SPE-196704-MS Deriving Permeability and Reservoir Rock Typing Supported with Self-Organized Maps SOM and Artificial Neural Networks ANN - Optimal Workflow for Enabling Core-Log Integration Predictive Data Analytics ( PDA ) and Machine Learning ( ML ),” 2019. M. Shabaninejad, M. Bagheripour, S. Z. Oil, and P. Company, “SPE 150819 Rock Typing and Generalization of Permeability- Porosity Relationship for an Iranian Carbonate Gas Reservoir,” 2011. E. Aliakbardoust, “Integration of rock typing methods for carbonate reservoir characterization,” vol. 055004, doi: 10.1088/1742-2132/10/5/055004. Z. Riazi, “Journal of Petroleum Science and Engineering Application of integrated rock typing and fl ow units identi fi cation methods for an Iranian carbonate reservoir,” J. Pet. Sci. Eng., vol. 160, no. October 2017, pp. 483–497, 2018, doi: 10.1016/j.petrol.2017.10.025. S. Hosseinzadeh, A. Kadkhodaie, and S. Yarmohammadi, “NMR derived capillary pressure and relative permeability curves as an aid in rock typing of carbonate reservoirs,” J. Pet. Sci. Eng., vol. 184, p. 106593, 2020, doi: 10.1016/j.petrol.2019.106593. R. Mohebian, M. A. Riahi, and A. Kadkhodaie, “Characterization of hydraulic flow units from seismic attributes and well data based on a new fuzzy procedure using ANFIS and FCM algorithms, example from an Iranian carbonate reservoir,” Carbonates and Evaporites, vol. 34, no. 2, pp. 349–358, 2019, doi: 10.1007/s13146-017-0393-y. M. Farshi, R. Moussavi-Harami, A. Mahboubi, M. Khanehbad, and T. Golafshani, “Reservoir rock typing using integrating geological and petrophysical properties for the Asmari Formation in the Gachsaran oil field, Zagros basin,” J. Pet. Sci. Eng., vol. 176, no. May 2018, pp. 161–171, 2019, doi: 10.1016/j.petrol.2018.12.068. A. Mirzaei-Paiaman, M. Ostadhassan, R. Rezaee, H. Saboorian-Jooybari, and Z. Chen, “A new approach in petrophysical rock typing,” J. Pet. Sci. Eng., vol. 166, pp. 445–464, 2018, doi: 10.1016/j.petrol.2018.03.075. A. Mirzaei-paiaman et al., “Journal of Petroleum Science and Engineering A further veri fi cation of FZI * and PSRTI : Newly developed petrophysical rock typing indices,” vol. 175, no. December 2018, pp. 693–705, 2019, doi: 10.1016/j.petrol.2019.01.014. H. Mehrabi, R. R. Karami, and M. R. Nejad, “Reservoir rock typing and zonation in sequence stratigraphic framework of the Cretaceous Dariyan Formation , Persian Gulf,” Carbonates and Evaporites, no. 0123456789, 2019, doi: 10.1007/s13146-019-00530-2. B. Khadem, M. R. Saberi, M. Eslahati, and B. Arbab, “Integration of rock physics and seismic inversion for rock typing and flow unit analysis: A case study,” Geophys. Prospect., vol. 68, no. 5, pp. 1613–1632, 2020, doi: 10.1111/1365-2478.12952. Seyedeh Akram JooybariPeymanRezaeiMajidMehdipour12252022163210.52547/ispg.39683.11.21.16http://journal.ispg.ir/fa/Article/39683http://journal.ispg.ir/fa/Article/Download/39683http://journal.ispg.ir/fa/Article/Download/39683http://journal.ispg.ir/fa/Article/Download/39683http://journal.ispg.ir/fa/Article/Download/39683http://journal.ispg.ir/fa/Article/Download/39683http://journal.ispg.ir/fa/Article/Download/39683http://journal.ispg.ir/fa/Article/Download/396831. جویباری، س ا.، رضائی، پ.، مهدی پور،م. 1401. بررسی توان مخزنی سازند سروک (سنومانین-تورونین) با تاکید بر واحدهای جریانی و تعیین ارتباط آن با ریزرخساره‌های رسوبی این مخزن در یکی از میادین نفتی استان خوزستان، زاگرس چین خورده. زمین شناسی کاربردی پیشرفته، دوره12، شماره4، آنلاین#2. حسنی گیو، م.، ابرقانی، آ. 1388. بررسی نقش ریزرخساره ها و نوع تخلخل در کیفیت مخزنی سازند ایلام در یکی از میادین نفتی ناحیه دزفول شمالی، دشت آبادان. مجله علوم دانشگاه تهران، جلد 35، شماره3، ص 53 تا 62#3. حسینی، ک.، رضائی، پ، کاظم شیرودی، س.، معینی،م.1398.بررسی ارتباط ریزریزریزرخساره‌ها، محیط رسوبی، دیاژنز و کیفیت مخزنی سازند میشریف (سنومانین آغازین- تورونین) در میدان نفتی اسفند، شمال خاوری خلیج فارس. نشریه پژوهش های چینه نگاری و رسوب شناسی، دوره 35، شماره2، ص 109 تا 134.#4. سلیمانی،ب. روانشاد، م.، لرکی، ا.1397. تأثیر تغییرات سنگ‌شناسی و پارامترهای پتروفیزیکی بر پتانسیل نفتی مخزن ایلام (کرتاسه بالایی)، در میدان نفتی اهواز، جنوب غرب ایران. فصلنامه علمی علوم زمین، دوره 28، شماره109، ص121 تا132.#5. عباسپور، ا.، مهرابی، ح.، رحیم پوربناب،ح.، زمان نژاد،ا. 1401.بازسازی محیط رسوبی، تاریخچه دیاژنزی و کیفیت مخزنی سازند ایلام در یکی از میادین نفتی ناحیه لرستان، غرب ایران، دوفصلنامه رسوب شناسی کاربردی، دوره 10، شماره19، ص 13 تا 34.#6. مهماندوستی، ا، عبدالملکی، س.، قلاوند، ه.1396. ریزرخساره ها، محیط رسوبی و دیاژنز سازند ایلام در یکی از میدان های نفتی دشت آبادان، دوفصلنامه رسوب شناسی کاربردی، دوره 5، شماره9، ص 21 تا 39.#7. Abedpour, M., Afghah, M., Ahmadi, V., & Dehghanian, M. S. (2018). Microfacies, Sequence stratigraphy, Facies analysis and Sedimentary environment of Neocomian in Kuh-e-Siah section (Arsenjan area, SW of Iran). Iranian Journal of Earth Sciences, 10(2), 142-157.‏#8. Ahr W.M., 2008. Geology of Carbonate Reservior. John Wiley and Sons. Inc, 277p#9. Alsharhan, A.S., Nairn, A.E.M. and Mohammed, A.A.,1993. Late Palaeozoic Glacial Sediments of the Southern Arabian Peninsula: Their Lithofacies and Hydrocarbon Potential. Marine and Petroleum Geology, 10, 71-78.#10. Basso, M., Belila, A. M. P., Chinelatto, G. F., Souza, J. P. D. P., & Vidal, A. C. (2021). Sedimentology and petrophysical analysis of pre-salt lacustrine carbonate reservoir from the Santos Basin, southeast Brazil. International Journal of Earth Sciences, 110(7), 2573-2595.‏.#11. Bathurst, R.G.C., 1975, Carbonate sediment and their diagenesis: Development in Sedimentology 12, Elsevier, Amsterdam, 658 p.#12. Bordenave, M. L., and Hegre, J. A., 2005. The influence of tectonics on the entrapment of oil in the Dezful Embayment, Zagros Foldbelt, Iran, Journal of PetroleumGeology, Vol. 28(4), pp 339 – 368.#13. Cantrell, D. L., Shah, R. A., Ou, J., Xu, C., Phillips, C., Li, X. L., & Hu, T. M. (2020). Depositional and diagenetic controls on reservoir quality: Example from the upper Cretaceous Mishrif Formation of Iraq. Marine and Petroleum Geology, 118, 104415.‏, D. L., Shah, R. A., Ou, J., Xu, C., Phillips, C., Li, X. L., & Hu, T. M. (2020). Depositional and diagenetic controls on reservoir quality: Example from the upper Cretaceous Mishrif Formation of Iraq. Marine and Petroleum Geology, 118, 104415.‏#14. Dunham, R.J., 1962. Classification of carbonate rocks according to depositional texture. In: Ham WE (ed) Classification of carbonate.#15. Flugel, E., 2010. Microfacies of carbonate rocks. Springer-Verlag, Berlin, 976 p.#16. Geel, T., 2000. Recognition of stratigraphic sequences in carbonat platform and slope deposits: empirical models based on microfacies analysis of Palaeogene deposits in southeastern Spain. Palaeogeography, Palaeoclimatology, Palaeoecology, 155,211–238.#17. Ghabeishavi, A., H. Vaziri-Moghaddam, A. Taheri,and F. Taati, 2010. Microfacies anddepositional environment of the Cenomanian of the Bangestananticline, SW Iran: Journal of Asian Earth Sciences, v.37, p. 275-285.#18. Ghabeishavi, A., Vaziri-Moghaddam, H., Taheri, A., Taati, F., 2010. Microfacies and depositional environment of the Cenomanian of the Bangestan anticline, SW Iran. J Asian Earth Sci 37,275–285#19. Hottinger, L., 1997. Shallow benthic foraminiferalassemblages as signal for depth of their deposition and their limitation: Society Geology FranceBulletin, v. 168, p. 491− 505.#20. Ibrahem, Y., Morozov, V. P., Sudakov, V., Idrisov, I., & Kolchugin, A. N. (2022). Sedimentary diagenesis and pore characteristics for the reservoir evaluation of Domanik formations (Semiluksk and Mendymsk) in the central part of Volga-Ural petroleum province. Petroleum Research, 7(1), 32-46#21. James, G.A., Wynd, J.G.,1965. Stratigraphic nomenclature of Iranian oil- Journal of Science, 307, 1064-1095.#22. Jooybari, A., Rezaie, P.,2017. Petrophysical evaluation of the Sarvak formation based on well logs in Dezful Embayment, Zagros Fold Zone, south west of Iran. Engineering, Technology & Applied Science Research, 7(1), 1358-1362#23. Khodaei, N., Rezaee, P., Honarmand, J., & Abdollahi-Fard, I. (2021). Controls of depositional facies and diagenetic processes on reservoir quality of the Santonian carbonate sequences (Ilam Formation) in the Abadan Plain, Iran. Carbonates and Evaporites, 36(2), 1-24.‏#24. Khodaei, N., Rezaee, P., Honarmand, J., Abdollahi-Fard, I., 2021. Controls of depositional facies and diagenetic processes on reservoir quality of the Santonian carbonate sequences (Ilam Formation) in the Abadan Plain, Iran. Carbonates and Evaporites, 36(2), 1-24. ‏#25. Lapponi, F., Casini, G., Sharp, I., Blendinger, W, Fernández, N., Romaire, I., Hunt D., 2011. From outcrop to 3D modelling: a case study of a dolomitized carbonate reservoir, Zagros Mountains, Iran. Petroleum Geoscience 17,145-158.#26. Lucia, F.J., 2007. Carbonate reservoir characterization: An integrated approach. Springer Berlin, 366 p.#27. Mehrabi, H., Bagherpour, B., & Honarmand, J. (2020). Reservoir quality and micrite textures of microporous intervals in the Upper Cretaceous successions in the Zagros area, SW Iran. Journal of Petroleum Science and Engineering, 192, 107292.‏#28. Messadi, A. M., Mardassi, B., Ouali, J. A., & Touir, J. (2019). Diagenetic process as tool to diagnose paleo-environment conditions, bathymetry and oxygenation during Late Paleocene-Early Eocene in the Gafsa Basin. Carbonates and Evaporites, 34(3), 893-908.‏#29. Mohajer, M. D., Afghah, M., Dehghanian, M., & Zakariaii, S. J. S. (2022). Biozonation, microfacies analysis and depositional environment of the Cenomanian sediments (Sarvak Formation) in South Zagros Basin (SW Iran). Carbonates and Evaporites, 37(3), 1-21.‏#30. Nazemi, M., Tavakoli, V., Rahimpour-Bonab, H., & Sharifi-Yazdi, M. (2021). Integrating petrophysical attributes with saturation data in a geological framework, Permian–Triassic reservoirs of the central Persian Gulf. Journal of African Earth Sciences, 179, 104203.‏#31. Omidpour, A., Mahboubi, A., Moussavi-Harami, R., & Rahimpour-Bonab, H. (2022). Effects of dolomitization on porosity–Permeability distribution in depositional sequences and its effects on reservoir quality, a case from Asmari Formation, SW Iran. Journal of Petroleum Science and Engineering, 208, 109348.‏#32. Pomar, L., 2001. Types of carbonate platforms: a genetic approach. Basin research, 13(3), 313-334.#33. Pomar, L.,1991. Reef geometries, erosion surfaces and high‐frequency sea‐level changes, upper Miocene Reef Complex, Mallorca, Spain. Sedimentology, 38(2), 243-269.‏#34. Qi, M., Han, C., Ma, C., Liu, G., He, X., Li, G., ... & Cheng, X. (2022). Identification of Diagenetic Facies Logging of Tight Oil Reservoirs Based on Deep Learning—A Case Study in the Permian Lucaogou Formation of the Jimsar Sag, Junggar Basin. Minerals, 12(7), 913.#35. Ravanshad, M. S., Soleimani, B., Larkee, E., & Soleimani, M. (2017). petrophysical evaluation and reservoir quality of ilam formation (late cretaceous), ahvaz oil field, dezful embayment, sw iran. Petroleum & Coal, 59(2).‏#36. Read, J.F., 1985. Carbonate platform facies models. Am Assoc Pet Geol Bull, 69,1-21. #37. Rebelle, M., Umbhauer, F., Poli, E., 2009. Pore to Grid Carbonate Rock-Typing. International Petroleum Technology Conference, International Petroleum Technology Conference.#38. Rezaie, P., Jooybari, A., Pour, M. M., Gorbani, M., 2016. Factor Controlling Reservoir Properties and Flow Unit Determination in the Ilam Formation of Dezfol Embayment at Zagros Fold-Thrust Belt, Southwest of Iran. Open Journal of Geology, 6(07), 660. ‏#39. Salifou, I. A. M., Zhang, H., Boukari, I. O., Harouna, M., & Cai, Z. (2021). New vuggy porosity models-based interpretation methodology for reliable pore system characterization, Ordovician carbonate reservoirs in Tahe Oilfield, North Tarim Basin. Journal of Petroleum Science and Engineering, 196, 107700.‏#40. Sharland, P. R., Archer, R., Casey, D. M., Davies, R. B., Hall, S. H., Heward, A. P., Horbury A. D., Simmons, M. D., 2001. Arabian plate sequence stratigraphy. Geo-Arabia Special Publication, 2, 371.#41. Soleimani, B., Ahmadi Nabi, M., & Jahani, D. (2022). Microfacies, Sedimentary Environment and Diagenetic Processes Analysis of Ilam Formation in Gachsaran Oil Field, Zagross Basin. Journal of Petroleum Research.‏#42. Wang, L. (2022). Three Dimensional Geological Modeling for Mixed Reservoir of F Oilfield in Middle East. In International Field Exploration and Development Conference (pp. 1659-1671). Springer, Singapore.‏#43. Wilson, J., 1975. Carbonate Facies in Geological History. Springer, Berlin, 471 p.#44. Yadav, P. K., Das, M., & Ray, S. (2022). Geology, petrology, and geochemistry of the Mesoproterozoic Kaimur Group of rocks of the Vindhyan Supergroup, Eastern India: implications for depositional environment and sequence stratigraphy. Journal of Sedimentary Environments, 1-27.‏#45. Yang, J., Wang, E., Ji, Y., Wu, H., He, Z., Zhang, J., ... & Feng, Y. (2021). Diagenetic facies and reservoir porosity evaluation of deep high-quality clastic reservoirs: A case study of the Paleogene Shahejie Formation, Nanpu Sag, Bohai Bay Basin, China. Energy Exploration & Exploitation, 39(4), 1097-1122.‏#Behrad Zebhi Kamandمحمد علی صالحی Ezat HeydariAliBahrami12252022547710.52547/ispg.39691.11.21.54http://journal.ispg.ir/fa/Article/39691http://journal.ispg.ir/fa/Article/Download/39691http://journal.ispg.ir/fa/Article/Download/39691http://journal.ispg.ir/fa/Article/Download/39691http://journal.ispg.ir/fa/Article/Download/39691http://journal.ispg.ir/fa/Article/Download/39691http://journal.ispg.ir/fa/Article/Download/39691http://journal.ispg.ir/fa/Article/Download/39691آدابی، م. ح.، 1392، ژئوشیمی رسوبی، انتشارات آرین زمین، تهران، 503 ص. باقری، ن.، 1381، بیواستراتیگرافی نهشته‌های پرمین در شمال شرق اصفهان (جنوب چاه‌ریسه، شمال دیزلو) براساس مطالعه کنودونت و ماکروفسیل¬ها: پایان نامه کارشناسی ارشد، دانشگاه اصفهان، 111 ص. ذبحی کمند، ب.، 1399، بررسی رخساره¬ها، محیط رسوبی و چینه¬نگاری سکانسی سازند جمال (پرمین) در منطقه چاه¬ریسه، شمال شرق اصفهان: پایان نامه کارشناسی ارشد، دانشگاه اصفهان، 93 ص. ADABI, M.H., 2009, Multistage dolomitization of upper Jurassic Mozduran Formation, Kopeh-Dagh basin NE Iran. Carbonates and Evaporites, 24(1), 16-32. AMERI, H., YAZDI, M., and BAHRAMI, A., 2017, Pseudophillipsia (Carniphillipsia) (Trilobite) from the Permian Jamal Formation, Isfahan, Iran. Journal of Sciences, Islamic Republic of Iran, 28(4), 325–336. AMTHOR, J.E., and FRIEDMAN, G.M., 1992, Early to late diagenetic dolomitization of platform carbonates; Lower Ordovician Ellenburger Group, Permian Basin, West Texas. Journal of Sedimentary Petrology, 62(1), 131-144. AREFIFARD, S., and DAVYDOV, V.I., 2005, Petrography and geochemistry of Permian Strata in Tabas and Kalmard regions, Eastern-Central Iran. Geophysical Research Abstracts, v. 7, 7p. AREFIFARD, S., 2017, Sea level drop, paleoenvironmental change and related biotic responses across Guadalupian-Lopingian boundary in southwest, North and Central Iran. Geological Magazine, 155(4), 921-943. BRAND, U., and VEIZER, J., 1980, Chemical diagenesis of a multicomponent carbonate system-1: Trace elements. Journal of Sedimentary Petrology, 50(4), 1219-1236. FLUGEL, E., 2010, Microfacies of Carbonate Rocks Analysis, Interpretation and Application. Springer, Berlin, 1006 p. FRIEDMAN, G.M., 1965, Terminology of crystallization textures and fabrics in sedimentary rocks. Journal of Sedimentary Petrology, 35(3), 643-655. GREGG, J.M., and SIBLEY, D.F., 1984, Epigenetic dolomitization and the origin of xenotopic dolomite texture. Journal of Sedimentary Petrology, 54(3), 908-931. GREGG, J.M., 1988, Origins of dolomite in the offshore facies of the Bonneterre Formation (Cambrian), Missouri, in Shukla, V., and Baker, P.A., eds., Sedimentology and Geochemistry of Dolostones: SEPM Special publication, 43, 67-83. GREGG, J.M., and SHELTON, K.L., 1990, Dolomitization and dolomite neomorphism in the back reef facies of the Bonneterre and Davis formations (Cambrian), southeast Missouri. Journal of Sedimentary Petrology, 60(4), 549-562. JAMES, N.P., and JONES, B., 2016, Origin of Carbonate Sedimentary Rocks. John Wiley and Sons, Alberta, 467p. LAND, L.S., 1985, The origin of massive dolomite. Journal of Geological Education, 33(2), 112-125. LEE, Y.I., and FRIEDMAN, G.M., 1987, Deep burial dolomitization in the Ordovician Ellenburger group carbonates, West Texas and southeastern New Mexico. Journal of Sedimentary Petrology, 57(3), 544-557. MAZZULLO, S.J., 1992, Geochemical and neomorphic alteration of dolomite: a review. Carbonates and Evaporites, 7(I), 21-37. MITCHELL, J.T., LAND, L.S., and MISER, D.E., 1987, Modern marine dolomite cement in a north Jamaican fringing reef. Geology, 15(6), 557-560. MILLIMAN, J.D., 1974, Marine Carbonates. Recent Sedimentary Carbonates, Part 1. Springer, New York, Xv, 375p. MORROW, D.W., 1982a, Diagenesis 1. Dolomite- Part 1: The chemistry of dolomitization and dolomite precipitation. Geoscience Canada, 9(1), 5-13. MORROW, D.W, 1982b, Diagenesis 2. Dolomite- Part 2: Dolomitization models and ancient dolostones. Geoscience Canada, 9(2), 95-107. PERMOPHILES, 2008, Newsletter of the subcommission on Permian Stratigraphy Number, 51, 1684-5927. QING, H., and Mountjoy, E.W., 1989, Multistage dolomitization in rainbow buildups, middle Devonian Keg River Formation, Alberta, Canada. Journal of Sedimentary Petrology, 59(1), 114-126. RAO, C.P., 1991, Geochemical differences between subtropical (Ordovician), cool temperate (Recent and Pleistocene) and subpolar (Permian) carbonates, Tasmania, Australia. Carbonates and Evaporites, 6(1), 83-106. RAO, C.P., and Adabi, M.H., 1991, Carbonate minerals, major and minor elements and oxygen and carbon isotopes and their variation with water depth in cool, temperate carbonates, western Tasmania, Australia. Marine Geology, 103, 249-272. RAO, C.P., 1996, Modern Carbonates, Tropical, Temperate, Polar: Introduction to Sedimentology and Geochemistry. Carbonates, Howrah, Tasmania, 206 p. SALLER, A.H., 1984, Petrologic and geochemical constraints on the origin of subsurface dolomite, Enewetak Atoll: An example of dolomitization by normal seawater. Geology, 12(4), 217-220. SHUKLA, V., and FRIEDMAN, G.M., 1983, Dolomitization and diagenesis in a shallowing upward sequence; the Lockport formation (middle Silurian), New York State. Journal of Sedimentary Petrology, 53(3), 703-717. SIBLEY, D.F., and GREGG, J.M., 1987, Classification of dolomite rock textures. Journal of Sedimentary Petrology, 57(6), 967-975. STÖCKLIN, J., EFTEKHAR-NEZHAD, J., and HUSHMAND-ZADEH, A., 1965, Geology of the Shotori Range (Tabas Area, East Iran). Geological Survey of Iran, Tehran, Report No. 3, 1-69. STÖCKLIN, J., and NABAVI, M.H., 1971, Explanatory text of the Boshruyeh Quadrangle Map. Geological Survey of Iran, Tehran, Quadrangle, No. v. J78, 50 p. YARAHMADZAHI, H. and LEVEN, E.J., 2021, Middle Permian (Late Murgabian) Fusulinids of the Jamal Formation, Tabas Area, Iran. Stratigraphy and Geological Correlation, 29(5), 495-503. YAZDI, M., 1999, Late Devonian-Carboniferous conodonts from Eastern Iran. Rivista Italiana di paleontologia e Stratigrafia, 105, I, 2, 167-200. YAZDI, M., and SHIRANI, M., 2002, first research on marine and nonmarine sedimentology sequences and micropaleontologic significance across Permian-Triassic boundary in Iran (Isfahan & Abadeh). Journal of China University of Geosciences, 13, 172-176. AbeerIssaAbbasGhaderiMohammadKhanehbadTea Kolar-Jurkovšek12252022335310.52547/ispg.39722.11.21.33http://journal.ispg.ir/fa/Article/39722http://journal.ispg.ir/fa/Article/Download/39722http://journal.ispg.ir/fa/Article/Download/39722http://journal.ispg.ir/fa/Article/Download/39722http://journal.ispg.ir/fa/Article/Download/39722http://journal.ispg.ir/fa/Article/Download/39722http://journal.ispg.ir/fa/Article/Download/39722http://journal.ispg.ir/fa/Article/Download/397221. آقانباتی، س.ع.، 1393. زمین‌شناسی ایران: سازمان زمین‌شناسی و اکتشافات معدنی کشور، 640 صفحه. 2. شیخ الاسلامی، م.ر. و زمانی، م.، 1378، نقشه زمین‌شناسی حلوان: سازمان زمین‌شناسی و اکتشافات معدنی کشور، شماره 7257، مقیاس 000/1:100. 3. قماشى، م. و لاسمى، ی.، 1383، محيط‌هاي رسوبي و چينه‌ نگاري سكانسي سازند سرخ ‌شيل (ترياس زيرين) در بلوك طبس، نشريه علوم دانشگاه تربيت معلم، جلد چهارم، شماره 2، صفحه 369-386. 4. یحیی شیبانی، و.، صباغ بجستانی، م. و خانه‌باد، م.، 1396، چينه سنگي و محيط رسوبي سازند سرخ شيل در بلوك طبس، شرق ايران مركزي: سومين همايش انجمن رسوب شناسي ايران، شماره سوم، صفحه 625-642. 5. ALGEO, T.J., 2011, The Early Triassic cesspool: marine conditions following the end-Permian mass extinction. In: HAKANSSON, E., TROTTER, J. (Eds.), Program and Abstracts, the XVII International Congress on the Carboniferous and Permian: Geological Survey of Western Australia, 35 (4), 6-38. 6. ALGEO, T.J., and TWITCHETT, R.J., 2010, Anomalous Early Triassic sediment fluxes due to elevated weathering rates and their biological consequences: Geology, 38, 1023–1026. 7. ALGEO, T.J., CHEN, Z.Q., FRAISER, M.L., and TWITCHETT, R.J., 2011, Terrestrial–marine teleconnections in the collapse and rebuilding of Early Triassic marine ecosystems: Palaeogeography, Palaeoclimatology, Palaeoecology, 308 (1–2), 1–11. 8. ALGEO, T.J., HENDERSON, C.M., TONG, J., FENG, Q., YIN, H., and TYSON, R.V., 2013, Plankton and productivity during the Permian-Triassic boundary crisis: an analysis of organic carbon fluxes: Global and Planetary Change, 105, 52–67. 9. ALJINOVIĆ, D., KOLAR-JURKOVŠEK, T., and JURKOVŠEK, B. 2006, The Lower Triassic shallow marine succession in Gorski Kotar region (External Dinarides, Croatia): Lithofacies and conodont dating: Rivista Italiana di Paleontologia e Stratigrafia, 112 (1), 35-53. 10. ALJINOVIĆ, D., KOLAR-JURKOVŠEK, T., JURKOVŠEK, B., and HRVATOVIĆ, H. 2011, Conodont dating of the Lower Triassic sedimentary rocks in the external Dinarides (Croatia and Bosnia and Herzegovina): Rivista Italiana di Paleontologia e Stratigrafia, 117 (1), 135–148. 11. BAUD, A., RICHOZ, S., and PRUSS, S.B., 2007, The Lower Triassic anachronistic carbonate facies in space and time: Global and Planetary Change, 55, 81–89. 12. BEYERS, J.M., and ORCHARD, M.J. 1991, Upper Permian and Triassic conodont faunas from the type area of Cache Creek complex, south-central British Columbia, Canada: Geological Survey of Canada Bulletin, 417, 269 –297. 13. BONDARENKO, L.G., ZAKHAROV, Yu.D., GURAVSKAYA, G.I., and SAFRONOV, P.P., 2015, Lower Triassic zonation of southern Primorye: Article 2. First conodont findings in Churkites cf. syaskoi Beds at the western coast of the Ussuri Gulf: Russian Journal of Pacific Geology, 9 (3), 203–214. 14. BRAYARD, A., ESCARGUEL, G., BUCHERB, H., MONNET, C., BRÜHWILER, T., GOUDEMAND, N., GALFETTI, T., and GUEX, J., 2009, Good genes and good luck: Ammonoid diversity and the end-Permian mass extinction: Science, 325, 1118–1121. 15. BRAYARD, A., VENNIN, E., OLIVIER, N., BYLUND, K.G., JENKS, J., STEPHEN, D.A., BUCHER, H., HOFMANN, R., GOUDEMAND, N., and ESCARGUEL, G., 2011, Transient metazoan reefs in the aftermath of the end-Permian mass extinction: Nature Geoscience, 4, 693–697. 16. BRONNIMANN, L., ZANINETTI, A., and MOSHTAGHIAN, A., HUBER, H., 1973, Foraminifera from the Sorkh Shale Formation of the Tabas area, east-central Iran. Riv: Italian Paleontologists, 79 (1): 1-32. 17. BUDUROV, K., and PANTIĆ, S., 1973, Conodonten aus den Campiler Schichten von Brassina (Westserbien): II. Systematischer Teil, Bulletin of the Geological Institute-Series Paleontology, 22, 49–64. 18. CHEN, Y.L., KOLAR-JURKOVŠEK, T., JURKOVŠEK, B., ALJINOVIĆ, D., and RICHOZ, S., 2016, Early Triassic conodonts and carbonate carbon isotope record of the Idrija–Žiri area, Slovenia: Palaeogeography, Palaeoclimatology, Palaeoecology, 444, 84–100. 19. CHEN, Z.Q., and BENTON, M.J., 2012. The timing and pattern of biotic recovery following the end-Permian mass extinction: Nature Geoscience, 5, 375–383. 20. CLARK, D.L. 1972. Early Permian crisis and its bearing on Permo-Triassic conodont taxonomy: Geologica et Palaeontologica, Sp., 1, 147-158. 21. CLARKSON, M.O., WOOD, R.A., POULTON, S.W., RICHOZ, S., NEWTON, R.J., KASEMANN, S.A., BOWYER, F., and KRYSTYN, L., 2016, Dynamic anoxic ferruginous conditions during the end Permian mass extinction and recovery: Nature Communication, 7, 12236, 1-9. 22. DOZET, S., and KOLAR-JURKOVŠEK, T., 2007, Spodnjetriasne plasti na južnovzhodnem obrobju Ljubljanske kotline, osrednja Slovenija = Lower Triassic beds in the southern borderland of the Ljubljana depression, central Slovenia: Materiali in Geookolje, 54 (3), 361–386. 23. EPSTEIN, A.G., EPSTEIN, J.B., and HARRIS, L.D., 1977, Conodont color alteration; an index to organic metamorphism: United States Geological Survey Professional Paper, 995, 1-27. 24. ERWIN, D.H., BOWRING, S.A., and JIN, Y.G., 2002, End-Permian mass extinctions: a review: Geological Society of America Special Papers, 356, 363–383. 25. FARABEGOLI, E., and PERRI, M.C., 1998, Permian-Triassic boundary and Early Triassic of the Bulla section (Southern Alps, Italy): lithostratigraphy, facies and conodont biostratigraphy. In: PERRI, M.C., and Spalletta, C., (Eds.): Southern Alps Fie1d Trip Guidebook, ECOS VII., Giornale di Geologia, Speciallssue, 60, 292-310. 26. FARABEGOLI, E., and PERRI, M.C., 2012, Millennial Physical Events and the End-Permian Mass Mortality in the Western Palaeothethys: Timing and Primary Causes: In: TALENT, J.A. (Eds.), Part of the book Earth and Life: International Year of Planet Earth (IYPE), Environmental Science, Geography, 719-758. 27. FERRETTI, A., BANCROFT, A.M., REPETSKI, J.R., 2020, GECkO: Global Events impacting Conodont evolution: Palaeogeography, Palaeoclimatology, Palaeoecology, 549, 109677, 1-8. 28. GANSSER, A., 1955, New aspects of geology in Central Iran, Proceedings of the fourth world petroleum congress, Rome, Section I/A/5, Geology, 279-300. 29. GHADERI, A., GARBELLI, C. ANGIOLINI, L. ASHOURI, A.R. KORN, D. RETTORI, R. and MAHMUDY GHARAIE, M.H., 2014a. Faunal changes near the End Permian Extinction: the brachiopods of the Ali Bashi Mountains, NW Iran: Rivista Italiana di Paleontologia e Stratigrafia, 120 (1), 27-59. 30. GHADERI, A., LEDA, L., SCHOBBEN, M., KORN, D., and ASHOURI, A.R., 2014b. High-resolution stratigraphy of the Changhsingian (Late Permian) successions of NW Iran and the Transcaucasus based on lithological features, conodonts and ammonoids: Fossil Record, 17, 41-57. 31. GLAUS, M., 1964, Trias und Oberperm in Zentralen Elburs (Persien): Eclogae Geologicae Helvetiae, 57, 497-508. 32. GOUDEMAND, N., 2014. Note on the Conodonts from the Induan/Olenekian Boundary: Albertiana, 42, 49–51. 33. HORACEK, M., RICHOZ, S., BRANDNER, R., KRYSTYN, L., and SPOTL, C., 2007, Evidence for recurrent changes in Lower Triassic oceanic circulation of the Tethys: The δ13C record from marine sections in Iran: Palaeogeography, Palaeoclimatology, Palaeoecology, 252, 355–369. 34. IGO, H., 1996, Silurian to Triassic conodont biostratigraphy in Japan, Acta Micropalaeontology Since, 13 (2), 143 –160. 35. JELASKA, V., KOLAR-JURKOVŠEK, T., JURKOVŠEK, B. and GUŠIĆ, L. 2003, Triassic beds in the basement of the Adriatic-Dinaric carbonate platform of Mt. Svilaja (Croatia) = Triasne plasti v podlagi Jadransko-dinarske karbonatne platforme na planini Svilaja (Hrvaška). Geologija, 46 (2), 225–230. 36. JURKOVŠEK, B., OGORELEC, B., and KOLAR-JURKOVŠEK, T., 1999, Lower Triassic beds from Tehovec = Polhov Gradec Hills, Slovenia. Geologija, 41, 29-40. 37. KOLAR-JURKOVŠEK, T., CHEN, Y. L., JURKOVŠEK, B., POLJAK, M., ALJINOVIĆ, M., and RICHOZ, S., 2017, Conodont Biostratig¬raphy of the Early Triassic in Eastern Slovenia: Palaeon¬tological Journal, 51, 687-703. 38. KOLAR-JURKOVŠEK, T., JURKOVŠEK, B., VUKS, V.J., HRVATOVIĆ, H., Aljinović, D., ŠARIĆ, Ć., and SKOPLJAK, F., 2014, The Lower Triassic platy limestone in the Jajce area (Bosnia and Herzegovina), Geologija, 57 (2), 105–118. 39. KOLAR-JURKOVŠEK, T., and JURKOVŠEK, B., 1995, Lower Triassic conodont fauna from Tržič (Karavanke Mts. Slovenia): Eclogae Geologicae Helvetiae, 88 (3), 789 – 801. 40. KOLAR-JURKOVŠEK, T., and JURKOVŠEK, B., 1996, Contribution to the knowledge of the Lower Triassic conodont fauna in Slovenia: Razprave 4. Razreda Sazu, 37 (1), 3–21. 41. KOLAR-JURKOVŠEK, T., and JURKOVŠEK, B., 2015, Conodont zonation of Lower Triassic strata in Slovenia, Geologija, 58 (2), 155–174. 42. KOLAR-JURKOVŠEK, T., and JURKOVŠEK, B., and ALJINOVIĆ, D., 2011, Conodont biostratigraphy and lithostratigraphy across the Permian–Triassic boundary at the Lukač section in western Slovenia: Rivista Italiana di Paleontologia e Stratigrafia, 117 (1), 115–133. 43. KORN, D., LEDA, L., HEUER, F., MORADI SALIMI, H., FARSHID, E., AKBARI, A., SCHOBBEN, M., GHADERI, A., STRUCK, U., GLIWA, J., WARE, D., and HAIRAPETIAN, V., 2021. Baghuk Mountain (Central Iran): high-resolution stratigraphy of a continuous Central Tethyan Permian–Triassic boundary section: Fossil Record, 24, 171-192. 44. KOZUR, H., 2003. Integrated ammonoid, conodont and radiolarian zonation of the Triassic and some remarks to stage/substage subdivision and the numeric age of the Triassic stages: Albertiana, 28, 57–74. 45. KOZUR, H.W., 2005, Pelagic uppermost Permian and the Permian-Triassic boundary conodonts of Iran, Part II: Investigated sections and evaluation of the conodont faunas: Hallesches Jahrbuch Fur Geowissenschaften, Reihe B: Geologie, Palaontologie, Mineralogie, 19, 49–86. 46. KOZUR, H.W., 2007, Biostratigraphy and event stratigraphy in Iran around the Permian-Triassic boundary (PTB); implications for the causes of the PTB biotic crisis; Environmental and biotic changes during the Paleozoic- Mesozoic transition: Global and Planetary Change, 55, 155–176. 47. KOZUR, H., and MOSTLER, H., 1970, Neue C¬¬onodonten aus der Trias: Berichte Naturwissenschaftlichen-medizinischen Verin Innsbruck, 58, 429–464. 48. KӦNIGSHOF, P., 2003, Conodont deformation patterns and textural alteration in Paleozoic conodonts: examples from Germany and France: Senckenbergian alethae, 83, 149-156. 49. LEGALL, F.D, BARNES, C.R., and MCQUEEN, R.W., 1982, Thermal maturation, burial history and hotspot development, Paleozoic strata of Southern Ontario-Quebec, from conodont and acritarch colour alternation studies: Bulletin Canadian Petroleum Geology, 29, 492-539. 50. LEVEN, E.YA., and GORGIJ, M.N., 2009, Section of Permian Deposits and Fusulinids in the Halvan Mountains, Yazd Province, Central Iran: Stratigraphy and Geological Correlation, 17 (2), 155–172. 51. LI, H., JIANG, H., CHEN, Y., WIGNALL, P. B., WU, B., ZHANG, Z., ZHANG, M., OUYANG, Z., and LAI, X. 2019, Smithian platform-bearing gondolellid conodonts from Yiwagou Section, northwestern China and implications for their geographic distribution in the Early Triassic: Journal of Paleontology, 93 (3), 496-511. 52. LINDSTROM, M., 1964. Conodonts. Elsevier Publishing Company, Amsterdam, London and New York, 58s, 1-196. 53. METCALF, I., and RILEY, N.J. 2010, Conodont Colour Alteration pattern in the Carboniferous of the Craven Basin and adjacent areas, northern England: Proceedings of The Yorkshire Geological Society, 58, 1-8. 54. METCALF, I., NICOLL, R.S., WILLINK, R., LADJAVADI, M., and GRICE, K., 2013, Early Triassic (Induan–Olenekian) conodont biostratigraphy, global anoxia, carbon isotope excursions and environmental perturbations: new data from Western Australian Gondwana: Gondwana Research, 23, 1136–1150. 55. MEYER, K.M., YU, M., JOST, A.B., KELLEY, B.M., and PAYNE, J.L., 2011, δ13C evidence that high primary productivity delayed recovery from end-Permian mass extinction: Earth and Planetary Science Letters, 302 (3–4), 378–384. 56. NICOLL, R.S., and CORTER, J.D., 1984, Conodont colour alternation, Thermal maturation and geothermal history of the Canning Basin, Western Australia: Australian Petroleum Exploration Association, 24, 243-258. 57. NOWLAN, G.S., & BARNES, C.R., 1987. Thermal maturation of Paleozoic strata in eastern Canada from conodont colour alteration index (CAI) data with implication for burial history, tectonic evolution, hotspot tracks and mineral and hydrocarbon exploration: Geological Survey of Canada Bulletin, 367, 1-47. 58. ORCHARD, M.J., 2005, Multielement conodont apparatuses of Triassic Gondolelloidea: Special Papers in Palaeontology, 73, 73–101. 59. ORCHARD, M.J., 2007, Conodont diversity and evolution through the latest Permian and Early Triassic upheavals: Palaeogeography, Palaeoclimatology, Palaeoecology, 252, 93–117. 60. ORCHARD, M.J., 2010, Triassic conodonts and their role in stage boundary definition. In: Lucas, S.G. (Ed.), The Triassic Timescale. Geological Society, London, Special Publications 334, 139–161. 61. PAYNE, J.L., and KUMP, L.R., 2007, Evidence for recurrent Early Triassic massive volcanism from quantitative interpretation of carbon isotope fluctuations: Earth and Planetary Science Letters, 256 (1–2), 264–277. 62. PAYNE, J.L., LEHRMANN, D.J., WIE, J.Y., ORCHARD, M.J., SCHRAGE, D.P., and KNOLL A.H., 2004, Large perturbations of the carbon cycle during recovery from the end-Permian extinction: Science, 305, 506–509. 63. PERRI, M.C., 1991, Conodont biostratigraphy of the Werfen Formation (Lower Triassic), Southern Alps, Italy: Bollettino della Società Paleontologica Italiana, 30 (1), 23–46. 64. PERRI, M.C., and ANDRAGHETTI, M., 1987, Permian–Triassic and Early Triassic conodonts from the Southern Alps, Italy: Rivista Italiana di Paleontologia e Stratigrafia, 93: 291-328. 65. POWELL, J.H., NICORA, A., PERRI, M.C., RETTORI, R., POSENATO, R., STEPHENSON, M.H., MASRI, A., BORLENGHI, L.M. and GENNARI, V., 2019, Lower Triassic (Induan to Olenekian) conodonts, foraminifera and bivalves from the Al Mamalih area, Dead Sea, Jordan: constraints on the P-T boundary: Rivista Italiana di Paleontologia e Stratigrafia, 125 (1), 147-181. 66. POWELL, J.H., STEPHENSON, M.H., NICORA, A., RETTORI, R., BORLENGHI, L.M. and PERRI, M.C., 2016, The Permian -Triassic boundary, Dead Sea, Jordan: transitional alluvial to marine depositional sequences and biostratigraphy: Rivista Italiana di Paleontologia e Stratigrafia, 122 (3), 23-40. 67. REJEBIAN, V. A., HARRIS, A. G., and HUEBNER, J. S. 1987, Conodont color and textural alteration: an index to regional metamorphism, contact metamorphism and hydrothermal alteration: Geological Society of America Bulletin, 99, 471–479. 68. RICHOZ, S., KRYSTYN, L., BAUD, A., BRANDNER, R., HORACEK, M., and MOHTAT-AGHAI, P., 2010, Permian–Triassic boundary interval in the Middle East (Iran and N. Oman): Progressive environmental change from detailed carbonate carbon isotope marine curve and sedimentary evolution: Journal of Asian Earth Science, 39 (4), 236–253. 69. RUBAN, D.A., AL-HUSSEINI, M.I., and IWASAKI, Y., 2007. Review of Middle East Paleozoic plate tectonics: GeoArabia, 12: 35–56. 70. SAMANKASSUO, E., 1995, Early Triassic (Scythian) conodonts from the Werfen Formation, Southern Alps, Italy: Neues Jahrbuch für Geologie und Paläontologie, 4, 248-256. 71. SCHOBBEN, M., STEBBINS, A., GHADERI, A., STRAUSS, U., KORN, D., and KORTE, CH., 2016, Eutrophication, microbial-sulfate reduction and mass extinctions: Communicative & Integrative Biology, 9 (1), 1–9. 72. SEPHTON, M.A., LOOY, C.V., BRINKHUIS, H., WIGNALL, P.B., DE LEEUW, J.W., and VISSCHER, H., 2005, Catastrophic soil erosion during the end-Permian biotic crisis: Geology, 33 (12), 941–944. 73. SEYED-EMAMI, K., 2003, Triassic in Iran: Facies, 48, 91-106. 74. SOLIEN, M.A., 1979, Conodont biostratigraphy of the Lower Triassic Thaynes Formation, Utah: Journal of Paleontology, 53 (2), 276–306. 75. STAESCHE, U., 1964, Conodonten aus dem Skyth von Sudtirol: Neues Jahrbuch für Geologie und Paläontologie (Abh.), 119, 247–306. 76. STANLEY, S.M., 2009, Evidence from ammonoids and conodonts for multiple Early Triassic mass extinctions: Proceedings of the National Academy of Sciences (PNAS), 106 (36), 15264–15267. 77. STANLEY S.M., 2016, Estimates of the magnitudes of major marine mass extinctions in earth history: Proceedings of the National Academy of Sciences (PNAS), 113 (42), E6325–E6334. 78. STӦCKLIN, J., EFTEKHAR NAZHAD, J., and HUSHMAND ZADEH, A., 1965, Geology of the Shotori Range, Tabas area, East Iran: Geological Survey of Iran, 3, 1-69. 79. SUDAR, M.N., 1986, Triassic microfossils and biostratigraphy of the Inner Dinarides between Gučevo and Ljubišnja Mts., Yugoslavia: Geološki anali Balkanskog poluostrva, 50, 151–394 (in Serbian, English summary). 80. SUDAR, M.N., CHEN, Y.L., KOLAR-JURKOVŠEK, T., JURKOVŠEK, B., JOVANOVIĆ, D., and FOREL, M.B., 2014, Lower Triassic (Olenekian) microfauna from Jadar Block (Gučevo Mt., NW Serbia): Annales Géologiques de la Péninsule Balkanique, 75, 1–15. 81. SUN, Y.D., JOACHIMSKI, M.M., WIGNALL, P.B., YAN, C.B., CHEN, Y.L., JIANG, H.S., WANG, L.N., and LAI, X.L., 2012, Lethally hot temperatures during the Early Triassic greenhouse: Science, 338, 366–370. 82. SWEET, W.C., 1970, Uppermost Permian and Lower Triassic conodonts of the Salt Range and Trans-Indus ranges, West Pakistan. In: Kummel B., Teichert C. (Eds.), Stratigraphic Boundary Problems: Permian and Triassic of West Pakistan. Department of Geology, University of Kansas, Special Publication, 4, 207–275. 83. SWEET, W.C., 1988. A quantitative conodont biostratigraphy for the Lower Triassic: Senckenbergiana lethaeo, 69, 253 -273. 84. SWEET, W.C., MOSHER, L.C., CLARK, D.L., COIIINSON, J.W., and HASENMULLER, W.A., 1971, Conodont Biostratigraphy of the Triassic: In: Sweet, W.C., Bergström, S.M. (Eds.), Symposium on conodont Biostratigraphy. Geological Society of America Memoir, 127, 441–465. 85. TORSVIK, T.H. and COCKS, L.R.M., 2004, Earth geography from 400 to 250 Ma: a palaeomagnetic, faunal and facies review: Journal of the Geological Society, London, 161, 555–572. 86. TORSVIK, T.H. and COCKS, L.R.M., 2017, Earth History and Palaeogeography: Cambridge University Press, 1-317. 87. TWITCHETT, R.J., 1999, Palaeoenvironments and faunal recovery after the end-Permian mass extinction: Palaeogeography, Palaeoclimatology, Palaeoecology, 154, 27–37. 88. TWITCHETT, R.J., 2007, The Lilliput effect in the aftermath of the end-Permian extinction event: Palaeogeography, Palaeoclimatology, Palaeoecology, 252, 132–144. 89. VENNIN, E., OLIVIER, N., BRAYAD, A., BOUR, I., THOMAZO, C., ESCARGUEL, G., FARA, E., BYLUND, K.G., JENKS, J.F., STEPHEN, D.A., and HOFMANN, R., 2015, Microbial deposits in the aftermath of the end-Permian mass extinction: a diverging case from the Mineral Mountains (Utah, USA): Sedimentology, 62, 753–792. 90. WANG, H.M., WANG, X.L., LI, R.X., and WIE, J.Y., 2005, Triassic conodont succession and stage subdivision of the Guandao section, Bianyang, Luodian, Guizhou: Acta Palaeontologica Sinica, 44 (4), 611–626. 91. WANG, Z.H., and CAO, Y.Y., 1981, Early Triassic conodonts from Lichuan, Western Hubei. Acta Micropalaeontology Sinica, 20 (4), 363–375. 92. YAN, C.B., WANG, L.N., JIANG, H.S., WINGALL, P.B., SUN, Y.D., CHEN, Y.L., and ALI, X.L., 2013, Uppermost Permian to Lower Triassic conodont at Bianyang Section, Guizhou province, South China: Palaios, 28, 509–522. 93. ZHAO, L.S., ORCHARD, M.J., TONG, J.N., SUN, Z.M., ZUO, J.X., ZHANG, S.X., and YUN, A.L., 2007, Lower Triassic conodont sequence in Chaohu, Anhui Province, China and its global correlation: Palaeogeography, Palaeoclimatology, Palaeoecology, 252, 24–38. 94. ZHAO, L.S., TONG, J.N., SUN, Z.M., and ORCHARD, M.J., 2008, A detailed Lower Triassic conodont biostratigraphy and its implications for the GSSP candidate of the Induan–Olenekian boundary in Chaohu, Anhui Province: Progress in National Science, 18, 79–90. 95. ZHENG, Y., XU, R., WANG, C., MA, G., LAI, X., YE, D., CAO, L., and LIANG, J., 2007, Discovery of Early Triassic conodonts in western Gangdisê and the establishment of the Tangnale Formation: Science in China Series D- Earth Sciences, 50 (12), 1767-1772. AlirezaBashari122520229810810.52547/ispg.39981.11.21.98http://journal.ispg.ir/fa/Article/39981http://journal.ispg.ir/fa/Article/Download/39981http://journal.ispg.ir/fa/Article/Download/39981http://journal.ispg.ir/fa/Article/Download/39981http://journal.ispg.ir/fa/Article/Download/39981http://journal.ispg.ir/fa/Article/Download/39981http://journal.ispg.ir/fa/Article/Download/39981http://journal.ispg.ir/fa/Article/Download/39981منابع [1] بشری .، ع،. 1400 جریان هیدرو دینامیکی در مخزن میشریف با نگرشی بر سرشت نمایی سازند سروک در بخش شرقی خلیج فارس. نشریه علمی پژوهشی زمین شناسی نفت ایران.، سال دهم، شماره 19 ، بهار و تابستان 1399 ص 45-56.[2] زارع . ا.، 1381برسی خواص مخزنی میدان نفتی سیری دی (دنا) در خلیج فارس بر اساس مطالعات پتروفیزیکی. پایان نامه کارشناسی ارشد مهندسی اکتشاف نفت دپارتمان معدن، دانشکده فنی تهران.. [3] معمار ضیا ء . ع.، 1384. مد ل سازی چینه شناختی لرزه ای . شرکت نفت فلات قاره 160 ص. [4] مستقل. ب، . کاربرد اآنالیز و مدلسازی استو کاستیک (ناقاطع) در خلال مطالعات جامع ویژگیهای مخزن گازی گنبدلی ( مرز ایران و ترکمنستان) نشریه علمی پژوهشی علوم پایه، دانشگاه آزاد اسلامی .، سال پانزدهم، شماره 57 ، پائیز 1384 ص 327-340 [5] چهرازی ، ع و همکاران . دیاژنز و چینه نگاری سکانسی سازند ایلام در میدان نفتی سیری الوند. فضلنامه علمی پژهشی علوم زمین، سال بیست و چهارم شماره 95 بهار..1394 [6] MIRI. A., BASHARI. A. AFSHAR. A., Geological Reservoir of Ilam Formation in the Sirri D Field in the Persian Gulf, Based on deterministic and Stochastic Approaches ( 2nd National Iranian Petrleum Engineering Congress, 30-31 January 2008, Ahwaz, Iran "Extended Abstract". [7] MIRI, A., Integration of Petrophysical and Seismic Data to characterize and Geo-model Ilam reservoir in the Sirri D oil Field,. M.Sc. Thesis, Of Science in Petroleum exploration Engineering. , PUT & Ecole Du Petrole et des Moteurs ( IFP).[8] DUBRULE, O., Geostatic for Seismic Data Integration in Earth Models, EAGE, Distinguish instructor Series, No. 6 (2003). [9] BASHARI, A,. 2007, Integrated 3D Seismic and Petrophysical data of the Sarvak Formation, Sirri District in the Persian Gulf, (EAGE, First Break, v. 25 ,pp45-53, Regional focus, Middle East). [10] BASHARI, A., MOSTAGHEL, B., & KHAKZAD, A., 2004.Application of Stochastic Analysis & Modelling through Integrated Reservoir Characterization in Gonbadli Gas field, North Eastern of the Iran, (AAPG International Conference & Exhibition Oct 24-27 2004, Cancun, Mexico). [11]Ghazban, F. 2007. Petroleum Geology of the Persian Gulf. Natinal Iranian Oil Company. [12] MEMARZIA, A. H, 2005. Rule of Reflaction Seismic Data interpretation in Hydrocarbon Exploration, Iranian Offshore Oil Company 275.p.