Petroleum system modeling in the central part of the Fars platform (Zagros Basin)

Ali Soleimani , Mohammad Hassan Jazayeri , Mehdi Kobraei , Mehrab Rashidi , Xiyuan Liu , Mehdi Ostadhassan

Petroleum ›› 2026, Vol. 12 ›› Issue (2) : 197 -215.

PDF (15575KB)
Petroleum ›› 2026, Vol. 12 ›› Issue (2) :197 -215. DOI: 10.1016/j.petlm.2026.03.007
Full Length Article
research-article
Petroleum system modeling in the central part of the Fars platform (Zagros Basin)
Author information +
History +
PDF (15575KB)

Abstract

The Fars Platform is a geological region with significant untapped potential for petroleum resources. Its unique structural and stratigraphic features, combined with favorable reservoir conditions, make it a key area for hydrocarbon exploration and production. To better delineate the Paleozoic petroleum system and mitigate future charge-related risks in the region, one- and two-dimensional petroleum system modeling was carried out. The primary objective of this study is to analyze the burial, thermal, maturation, and generation histories of the source rock(s), as well as the migration pathways, hydrocarbon charging history, and accumulation within reservoirs in the central part of the Fars Platform based on a comprehensive integration of geological, geophysical, and geochemical data. Geochemical investigation on potential source rocks showed that the Silurian hot shale of the Sarchahan Formation is the only effective source rock charging the Permian reservoir rocks. By conducting 1-D models in 6 wells, the maturation and hydrocarbon generation histories and also the heat flow for each well were obtained after calibrating the models with the measured temperature and vitrinite reflectance data. The resulting heat flows were consequently used in 2-D petroleum system modeling based on the interpretation of seismic data. The simulation results show that the occurrence of overpressure in the Dashtak Formation has caused the pressure to be different in the upper and lower layers, making this formation a suitable cap rock in the area. The hydrocarbons generated from the Sarchahan source rock started to expel in the eastern parts of the study area since the late Cretaceous, and expulsion occurred almost along the entire area during the Eocene. Before the Zagros orogeny happened in the Neogene, the hydrocarbon migration was mostly vertical while, after the orogeny, the lateral migration also occurred, mainly towards the regional high, and charged most of the traps. The large amounts of hydrocarbon, mostly in gaseous form, was expelled after the formation of structural traps. The results from this study can become the guideline for future exploration endeavors in the region to reduce risks and operational costs.

Keywords

Petroleum system modeling / Migration / Sarchahan formation / Zagros Basin / Dashtak formation

Cite this article

Download citation ▾
Ali Soleimani, Mohammad Hassan Jazayeri, Mehdi Kobraei, Mehrab Rashidi, Xiyuan Liu, Mehdi Ostadhassan. Petroleum system modeling in the central part of the Fars platform (Zagros Basin). Petroleum, 2026, 12 (2) : 197-215 DOI:10.1016/j.petlm.2026.03.007

登录浏览全文

4963

注册一个新账户 忘记密码

CRediT authorship contribution statement

Ali Soleimani: Writing – original draft, Visualization, Investigation, Formal analysis, Data curation, Conceptualization. Mohammad Hassan Jazayeri: Visualization, Validation, Investigation, Formal analysis. Mehdi Kobraei: Writing – review & editing, Investigation, Formal analysis, Data curation, Conceptualization. Mehrab Rashidi: Writing – review & editing, Validation. Xiyuan Liu: Writing – review & editing, Validation, Data curation. Mehdi Ostadhassan: Writing – review & editing, Supervision, Resources, Project administration, Methodology, Investigation, Funding acquisition.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgment

The authors would like to extend their heartfelt gratitude to the Exploration Directorate of the National Iranian Oil Company, especially to the technical staff of the Geochemistry Department, for their invaluable data, insightful discussions, and steadfast support throughout this research.

References

[1]

L.B. Magoon, W.G. Dow, The Petroleum System, 1994 (chapter 1): Part I. Introduction.

[2]

K.E. Peters , C.C. Walters , J.M. Moldowan , The Biomarker Guide, Cambridge university press, 2005.

[3]

L.B. Magoon, Identified petroleum systems within the United States-1990, Petrol. Syst.-Stat. Res. Method. (1990) 2-9.

[4]

J. Hunt, Petroleum geochemistry and geology (textbook). Petroleum Geochemistry and Geology (Textbook), second ed., WH Freeman Company, 1995.

[5]

K.E. Peters , D.J. Curry , M. Kacewicz , An Overview of Basin and Petroleum System Modeling: Definitions and Concepts, 2012.

[6]

S.E. Beglinger , H. Doust , S. Cloetingh , Relating petroleum system and play development to basin evolution: west African South Atlantic basins, Mar. Petrol. Geol. 30 (2012) 1-25.

[7]

A. Escalona, P. Mann, An overview of the petroleum system of Maracaibo Basin, AAPG Bull. 90 (2006) 657-678.

[8]

Jr, H. Dembicki, Practical Petroleum geochemistry for exploration and production, Reprod. Dev. Toxicol. (2016) 1-331.

[9]

D.H. Welte , B. Horsfield , D.R. Baker , Petroleum and Basin Evolution: Insights from Petroleum Geochemistry, Geology and Basin Modeling, Springer Science & Business Media, 2012.

[10]

A.I. Levorsen , Geology of Petroleum, American Association of Petroleum Geologists, 2001.

[11]

T. Hantschel, A.I. Kauerauf, Fundamentals of Basin and Petroleum Systems Modeling, Springer Science & Business Media, 2009.

[12]

K.E. Peters , M.G. Fowler , Applications of petroleum geochemistry to exploration and reservoir management, Org. Geochem. 33 (2002) 5-36.

[13]

M. Gutierrez, R. Lewis, I. Masters, Petroleum reservoir simulation coupling fluid flow and geomechanics, SPE Reservoir Eval. Eng. 4 (2001) 164-172.

[14]

A.C. Aplin , J.H. Macquaker , Mudstone diversity: origin and implications for source, seal, and reservoir properties in petroleum systems, AAPG Bull. 95 (2011) 2031-2059.

[15]

L.B. Magoon, Petroleum system: nature’s distribution system for oil and gas, Encyclop. Energy 4 (2004) 823-836.

[16]

K. McCarthy, K. Rojas, M. Niemann, D. Palmowski, K. Peters, A. Stankiewicz, Basic petroleum geochemistry for source rock evaluation, Oilfield Rev. 23 (2011) 32-43.

[17]

M.T. Gibbs , L.R. Kump , Global chemical erosion during the last glacial maximum and the present: sensitivity to changes in lithology and hydrology, Paleoceanography 9 (1994) 529-543.

[18]

A.D. Miall , The geology of fluvial deposits: sedimentary facies, basin analysis. And Petroleum Geology, Springer, 2013.

[19]

H.G. Reading , Sedimentary Environments: Processes, Facies and Stratigraphy, John Wiley & Sons, 2009.

[20]

W. Wang, X. Pang, Z. Chen, et al., Quantitative prediction of oil and gas prospects of the Sinian-Lower Paleozoic in the Sichuan Basin in central China, Energy 174 (2019) 861-872.

[21]

F. Ghazban, Petroleum Geology of the Persian Gulf, Tehran University Press, 2009.

[22]

M. Bordenave, The origin of the Permo-Triassic gas accumulations in the Iranian Zagros foldbelt and contiguous offshore areas: a review of the Palaeozoic petroleum system, J. Petrol. Geol. 31 (2008) 3.

[23]

P.A. Allen , J.R. Allen , Basin Analysis: Principles and Application to Petroleum Play Assessment, John Wiley & Sons, 2013.

[24]

T. Alves, M. Fetter, C. Busby, R. Gontijo, T.A. Cunha, N.H. Mattos, A tectono-stratigraphic review of continental breakup on intraplate continental margins and its impact on resultant hydrocarbon systems, Mar. Petrol. Geol. 117 (2020) 104341.

[25]

A.S. Pepper , Estimating the petroleum expulsion behaviour of source rocks: a novel quantitative approach, Geol. Soc. London, Spec. Publ. 59 (1991) 9-31.

[26]

L. Vernik, Hydrocarbon-generation-induced microcracking of source rocks, Geophysics 59 (1994) 555-563.

[27]

D. Welte, M. Yukler, Petroleum origin and accumulation in basin evolution-a quantitative model, AAPG (Am. Assoc. Pet. Geol.) Bull. 65 (1981) 1387-1396.

[28]

A. Darvishzadeh, Geology of Iran, Neda Publication, 1991. Tehran 901.

[29]

H. Motiei, Petroleum Geology of Zagros, Geological Survey of Iran, 1995 (in Farsi) 589.

[30]

J. Stöcklin, Structural history and tectonics of Iran: a review, AAPG Bull. 52 (1968) 1229-1258.

[31]

M. Alavi, Sedimentary and structural characteristics of the Paleo-Tethys remnants in northeastern Iran, Geol. Soc. Am. Bull. 103 (1991) 983-992.

[32]

W. Gealey, Plate tectonic evolution of the Mediterranean-Middle East region, Tectonophysics 155 (1988) 285-306.

[33]

O. Wennberg, M. Azizzadeh, A. Aqrawi, E. Blanc, P. Brockbank, K. Lyslo, N. Pickard, L. Salem, T. Svånå, The Khaviz Anticline: an Outcrop Analogue to Giant Fractured Asmari Formation Reservoirs in SW Iran, Geological society, London, special publications 270, 2007, pp. 23-42.

[34]

G. Konert, A. Afifi, S. Al-Hajri, K. De Groot, A. Al Naim, H. Droste, Paleozoic stratigraphy and hydrocarbon habitat of the Arabian plate, AAPG (Am. Assoc. Pet. Geol.) Bull. 83 (1999) 1320-1336.

[35]

R. Davies, M. Simmons, Triassic Sequence Stratigraphy of the Arabian Plate, 2018.

[36]

L. Huang, X. Zhao, C. Liu, A. Wang, X. Li, Z. Zhang, Z. Zhang, X. Lv, J. Liu, Control of Hercynian Orogeny on basin evolution on the southern margin of the Tethyan region: a review and new insights, Geol. J. 58 (2023) 4453-4474.

[37]

M. Alipour, Petroleum systems of the Iranian Zagros Fold and Thrust Belt, Result. Earth Sci. (2024) 100027.

[38]

B. Guoping, Main controls on hydrocarbon accumulation in the paleozoic in central Saudi Arabia, Pet. Sci. 4 (2007) 10-17.

[39]

M. Faqira, A. Bakhiet, D. Tang, W. Tan, A. Ahmed, A Review of the Permo-Triassic Gas Play in the Arabian Gulf Region, 2013.

[40]

H. Wopfner, Late Palaeozoic-early triassic deposition and climates between Samfrau and Tethys: a review, Geol. Soc., London, Spec. Publ. 376 (2013) 5-32.

[41]

A. Ahanjan, A.R. Rabbani, S. Khajooie, Assessing vertical compartmentalization within the KHM field, southwest of Iran: an integrated approach, J. Nat. Gas Sci. Eng. 35 (2016) 1277-1283.

[42]

B. Esrafili-Dizaji, H. Rahimpour-Bonab, A review of permo-triassic reservoir rocks in the zagros area, sw Iran: influence of the qatar-fars arch, J. Petrol. Geol. 36 (2013) 257-279.

[43]

B. Esrafili-Dizaji, H. Rahimpour-Bonab, Carbonate reservoir rocks at giant oil and gas fields in SW Iran and the adjacent offshore: a review of stratigraphic occurrence and poro-perm characteristics, J. Petrol. Geol. 42 (2019) 343-370.

[44]

M. Alipour, B. Alizadeh, S. Mirzaie, Tectono-stratigraphic evolution of the Permo-Triassic succession in the fars platform of Iran: implications for future exploration of the Paleozoic petroleum system, J. Asian Earth Sci. 221 (2021) 104945.

[45]

C. Perotti, S. Carruba, M. Rinaldi, G. Bertozzi, L. Feltre, M. Rahimi, The Qatar-South Fars arch development (Arabian Platform, Persian Gulf): insights from seismic interpretation and analogue modelling, New Front. Tecton. Res. Midst Plate Converg. (2011) 325-352.

[46]

J. Stocklin, Structural history and tectonics of Iran: a review, AAPG Bull. 52 (1968) 1229-1258.

[47]

M. Bordenave, J. Hegre, Current distribution of oil and gas fields in the Zagros Fold Belt of Iran and contiguous offshore as the result of the petroleum systems, Geol. Soc. London, Spec. Publ. 330 (2010) 291-353.

[48]

E. Mohsenian, A. Fathi-Mobarakabad, R. Sachsenhofer, A. Asadi-Eskandar, 3D basin modelling in the Central Persian Gulf, offshore Iran, J. Petrol. Geol. 37 (2014) 55-70.

[49]

H. Motiei, Stratigraphy of zagros, Treat. Geol. Iran 60 (1993) 237-245.

[50]

C. Authemayou, O. Bellier, D. Chardon, L. Benedetti, Z. Malekzade, C. Claude, B. Angeletti, E. Shabanian, M.R. Abbassi, Quaternary slip-rates of the Kazerun and the Main Recent Faults: active strike-slip partitioning in the Zagros fold-and-thrust belt, Geophys. J. Int. 178 (2009) 524-540.

[51]

M. Bordenave, J. Hegre, The influence of tectonics on the entrapment of oil in the Dezful Embayment, Zagros Foldbelt, Iran, J. Petrol. Geol. 28 (2005) 339-368.

[52]

M. Alipour, B. Alizadeh, S. Mirzaie, Petroleum system analysis of the Paleozoic series in the Fars Platform of Iran, J. Petrol. Sci. Eng. 208 (2022) 109557.

[53]

M. Bordenave, Petroleum Systems and Distribution of the Oil and Gas Fields in the Iranian Part of the Tethyan Region, 2014.

[54]

M.H. Saberi , A.R. Rabbani , M. Ghavidel-syooki , Hydrocarbon potential and palynological study of the Latest Ordovician-Earliest Silurian source rock (Sarchahan Formation) in the Zagros Mountains, southern Iran, Mar. Petrol. Geol. 71 (2016) 12-25.

[55]

M. Abu-Ali, U. Franz, J. Shen, F. Monnier, M. Mahmoud, T. Chambers, Hydrocarbon generation and migration in the Paleozoic sequence of Saudi Arabia, in: SPE Middle East Oil and Gas Show and Conference, SPE, 1991 pp. SPE-21376-MS.

[56]

M.A. Abu-Ali , Organic petrology, maturation, thermal and burial history analysis, and hydrocarbon generation and migration modeling of the Saudi Arabian paleozoic petroleum systems, in: Von Der Fakultät Für Georessourcen Und Materialtechnik Der Rheinisch-Westfälischen Technischen Hochschule Aachen, vol 209, 2005.

[57]

M.A. Abu-Ali , J.-L.L. Rudkiewicz , J.G. McGillivray , F. Behar , Paleozoic petroleum system of central Saudi Arabia, GeoArabia (Manama) 4 (1999) 321-336.

[58]

A. Al-Juboury, F. Qader, J. Howard, S. Vincent, A. Al-Hadidy, B. Thusu, M. Kaye, B. Vautravers, Organic and inorganic geochemical and mineralogical assessments of the Silurian Akkas Formation, western Iraq, J. Petrol. Geol. 44 (2021) 69-96.

[59]

M. Alipour, B. Alizadeh, A. Chehrazi, A thermal maturity analysis of the effective Cretaceous petroleum System in the Southern Persian Gulf Basin, Iran. J. Oil Gas Sci. Technol. 6 (2017) 1-17.

[60]

P. Agard, J. Omrani, L. Jolivet, F. Mouthereau, Convergence history across Zagros (Iran): constraints from collisional and earlier deformation, Int. J. Earth Sci. 94 (2005) 401-419.

[61]

J.-P. Callot , V. Trocmé , J. Letouzey , E. Albouy , S. Jahani , S. Sherkati , Pre-existing salt structures and the folding of the Zagros Mountains, Geol. Soc. London, Spec. Publ. 363 (2012) 545-561.

[62]

S.J. Haynes , H. McQuillan , Evolution of the Zagros suture zone, southern Iran, Geol. Soc. Am. Bull. 85 (1974) 739-744.

[63]

M. Takin, Iranian geology and continental drift in the Middle East, Nature 235 (1972) 147-150.

[64]

F. Mouthereau, O. Lacombe, J. Vergés, Building the Zagros collisional orogen: timing, strain distribution and the dynamics of Arabia/Eurasia plate convergence, Tectonophysics 532 (2012) 27-60.

[65]

N. Hajnorouzi, M. Pourkemani, Z. Maleki, Hydrocarbon trap and folding style of the pishvar anticline, sub-coastal Fars, zagros, Open J. Geol. 6 (2016) 376.

[66]

V. Atashbari, M. Tingay, K. Amrouch, Stratigraphy, tectonics and hydrocarbon habitat of the Abadan plain basin: a geological review of a prolific middle Eastern Hydrocarbon Province, Geosciences 8 (2018) 496.

[67]

A. Abarghani, M. Ostadhassan, T. Gentzis, H. Carvajal-Ortiz, B. Bubach, Organofacies study of the Bakken source rock in North Dakota, USA, based on organic petrology and geochemistry, Int. J. Coal Geol. 188 (2018) 79-93.

[68]

L.F. Camacho-Ortegón , L. Martínez , J.J. Enciso-Cardenas , A. Bueno-Tokunaga , J. Pironon , F. Núñez-Useche , Thermal history of the Sabinas-Piedras Negras Basin (Northeastern Mexico): insights from 1D modelling, J. South Am. Earth Sci. 115 (2022) 103756.

[69]

A.S. Pepper , P.J. Corvi , Simple kinetic models of petroleum formation. Part I: oil and gas generation from kerogen, Mar. Petrol. Geol. 12 (1995) 291-319.

[70]

Hongmei Luo , Changjiang Wang , Zhijing Zhang , et al. , New progress and future prospects of oil and gas reservoir modeling technology for exploration, Petrol. Geol. Recov. Eff. 31 (4) (2024) 135-153.

[71]

Youjuan He , M.A. Hongtao , D.E.N.G. Feng , Li Sun , Dan Yang , W.A.N.G. Yong , J.I.N. Yan , L.I.N. Ge , Application of seismic wavelet decomposition and reconstruction technology in thin reservoir prediction, Fault-Block Oil Gas Field 31 (2) (2024) 319-325.

[72]

W.Y. Wang , X.Q. Pang , Y.P. Wang , Z.X. Chen , C.R. Li , X.H. Ma , Hydrocarbon expulsion model and resource potential evaluation of high-maturity marine source rocks in deep basins: example from the Ediacaran microbial dolomite in the Sichuan Basin, China, Pet. Sci. 19 (6) (2022) 2618-2630.

[73]

Guanglei Ren , L.I. Xiaohui , Zhaozhou Wang , R.A.N. Hui , Xinyu Liu , Guosheng Liang , Guoping Chen , Application of waveform indication inversion based on compressive sensing in thin reservoir prediction, Fault-Block Oil Gas Field 31 (4) (2024) 637-644.

[74]

Qiang Zhang , L.Ü. Shichao , X.U. Yanqun , et al. , Current status and prospects of research on development seismic technologies for oil and gas fields: a case study of Jiyang Depression, Petrol. Geol. Recov. Eff. 31 (5) (2024) 130-141.

[75]

A. Bahroudi, C. Talbot, The configuration of the basement beneath the Zagros Basin, J. Petrol. Geol. 26 (2003) 257-282.

[76]

M.A. Abdelwahhab , N.A. Abdelhafez , A.M. Embabi , 3D-static reservoir and basin modeling of a lacustrine fan-deltaic system in the Gulf of Suez, Egypt, Petrol. Res. 8 (2023) 18-35.

[77]

M. Ghavidel-Syooki, Investigation on the upper paleozoic strata in Tang-e-Zakeen, and introducing Zakeen formation, Kuh-e Faraghan Zagros basin, South Iran, Geosciences 29 (1998) 54-73.

[78]

M. Ghavidel-Syooki, Palynostratigraphy of Devonian sediments in the Zagros Basin, southern Iran, Rev. Palaeobot. Palynol. 127 (2003) 241-268.

[79]

B. Khani, M. Mirshahani, A. Khajehzadeh, Maturity Evaluation of Seyaho an D Sarchahan Formations Based on Zooclast Reflectance and its Correlation with Vro, 34th International Geosciences Congress, Geological Survey of Iran, Tehran, Iran, 2016.

[80]

A. Soleimani, E. Dehyadegari, M. Hosseini-Barzi, M. Rashidi, M.H. Jazayeri, One and two-dimensional modeling of petroleum systems in the internal Fars region, J. Stratigr. Sedimentol. Res. 39 (2023) 61-78.

[81]

A. Soleimani, E. Dehyadegari, M. Hosseini-Barzi, M. Rashidi, M.H. Jazayeri, Burial History Reconstruction and Hydrocarbon Generation modeling of Probable Source rocks in two Gas Fields, South of Iran, Appl. Sedimentol. 11 (2023) 127-143.

[82]

S. Nielsen, O.R. Clausen, E. McGregor, Basin% ro: a vitrinite reflectance model derived from basin and laboratory data, Basin Res. 29 (2017) 515-536.

[83]

O. Schenk, K. Peters, A. Burnham, Evaluation of alternatives to Easy% Ro for calibration of basin and petroleum system models, in: 79th EAGE Conference and Exhibition 2017, European Association of Geoscientists & Engineers, 2017, pp. 1-5.

[84]

H. Motamedi, S. Sherkati, M. Sepehr, Structural style variation and its impact on hydrocarbon traps in central Fars, southern Zagros folded belt, Iran, J. Struct. Geol. 37 (2012) 124-133.

[85]

Zhenzhong Cai , Hui Zhang , X.U. Ke , Guoqing Yin , Zhimin Wang , Haiying Wang , Zhangyu Qianziwei , Geomechanics modeling of ultra-deep fault-controlled carbonate reservoirs and its application in development, Petrol. Geol. Exp. 46 (4) (2024) 868-879, https://doi.org/10.11781/sysydz202404868.

[86]

M. Makhous, Y. Galushkin, Basin Analysis and Modeling of the Burial, Thermal and Maturation Histories in Sedimentary Basins, 2004.

[87]

Wei Ju , Hui Zhang , Ke Xu , Weike Ning , Ru Xiang , Quantitative division method of geomechanical strata and its applications in exploration and development of oil and gas in ultra-deep layers, Petrol. Geol. Exp. 46 (4) (2024) 880-888, https://doi.org/10.11781/sysydz202404880.

[88]

M. Hosseinpour, M. Arian, Z. Maleki, M. Qorashi, Investigating for hydrocarbon potential in the Sarvak and Ilam Formations using Fuzzy logic in the Fars Region, Iran, Episod. J. Int. Geosci. 46 (2023) 361-374.

[89]

P. Ungerer, F. Behar, M. Villalba, O.R. Heum, A. Audibert, Kinetic modelling of oil cracking, Org. Geochem. 13 (1988) 857-868.

[90]

J. Aali, H. Rahimpour-Bonab, M.R. Kamali, Geochemistry and origin of the world’s largest gas field from Persian Gulf, Iran, J. Petrol. Sci. Eng. 50 (2006) 161-175.

[91]

A. Ahanjan, A.R. Rabbani, M.R. Kamali, An improved understanding of the origin and mechanism of Permian-Triassic natural gas-condensate accumulations in the Gavbendi High, Southwest Iran: an integrated approach, J. Nat. Gas Sci. Eng. 37 (2017) 217-233.

[92]

T. Ashrafi, M.H. Saberi, B. ZareNezhad, 1D and 2D basin modeling, in evaluating the hydrocarbon generation-migration-accumulation potential, at coastal Fars Area, Southern Iran, J. Petrol. Sci. Eng. 195 (2020) 107594.

[93]

Z. Jin, Hydrocarbon accumulation and resources evaluation: recent advances and current challenges, Adv. Geo-Energy Res. 8 (1) (2023) 1-4, 2023.

[94]

C. Baker, J. Jackson, K. Priestley, Earthquakes on the Kazerun Line in the Zagros Mountains of Iran: strike-slip faulting within a fold-and-thrust belt, Geophys. J. Int. 115 (1993) 41-61.

[95]

Grabowski Jr, G, Sequence Stratigraphy and Distribution of Silurian Organic-Rich “Hot Shales” of Arabia and North Africa, International Petroleum Technology Conference. IPTC, 2005. IPTC-10388-ABSTRACT.

[96]

O. Lacombe, N. Bellahsen, F. Mouthereau, Fracture patterns in the Zagros Simply Folded Belt (Fars, Iran): constraints on early collisional tectonic history and role of basement faults, Geol. Mag. 148 (2011) 940-963.

[97]

Li Hui , You Yuchun , Daqian Zeng , et al. , 3D geological modeling of strongly heterogeneous dual-medium deep carbonate reservoirs:a case study of Feixianguan-Changxing Formations in Puguang Gas Field, Petrol. Geol. Recov. Eff. 31 (1) (2024) 44-53.

PDF (15575KB)

0

Accesses

0

Citation

Detail

Sections
Recommended

/