The Geoscience Frontier of Gulong Shale Oil: Revealing the Role of Continental Shale from Oil Generation to Production

Wenyuan He; Rukai Zhu; Baowen Cui; Shuichang Zhang; Qian Meng; Bin Bai; Zihui Feng; Zhengdong Lei; Songtao Wu; Kun He; He Liu; Longde Sun

doi:10.1016/j.eng.2022.08.018

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Engineering ›› 2023, Vol. 28 ›› Issue (9) : 79-92. DOI: 10.1016/j.eng.2022.08.018

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Article

The Geoscience Frontier of Gulong Shale Oil: Revealing the Role of Continental Shale from Oil Generation to Production

Wenyuan He^a^,^c^,^# ,
Rukai Zhu^b^,^# ,
Baowen Cui^c^,^d ,
Shuichang Zhang^b ,
Qian Meng^c^,^d ,
Bin Bai^b ,
Zihui Feng^c^,^d ,
Zhengdong Lei^b ,
Songtao Wu^b ,
Kun He^b ,
He Liu^b^,^c ,
Longde Sun^c^,^e^,^*

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Abstract

The clay mineral content of Daqing Gulong shale is in the range of about 35%-45%, with particle sizes less than 0.0039 mm. The horizontal fluidity of oil in Gulong shale is poor, with near-zero vertical flowability. As a result, Gulong shale has been considered to lack commercial value. In recent years, however, interdisciplinary research in geoscience, percolation mechanics, thermodynamics, and surface mechanics has demonstrated that Gulong shale oil has a high degree of maturity and a high residual hydrocarbon content. The expulsion efficiency of Gulong shale in the high mature stage is 32%-48%. Favorable storage spaces in Gulong shale include connecting pores and lamellar fractures developed between and within organic matter and clay mineral complexes. The shale oil mainly occurs in micro- and nano-pores, bedding fractures, and lamellar fractures, with a high gas-oil ratio and medium-high movable oil saturation. Gulong shale has the characteristics of high hardness, a high elastic modulus, and high fracture toughness. This study achieves breakthroughs in the exploration and development of Gulong shale, including the theories of hydrocarbon generation and accumulation, the technologies of mobility and fracturing, and recoverability. It confirms the major transition of Gulong shale from oil generation to oil production, which has extremely significant scientific value and application potential for China’s petroleum industry.

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Keywords

Gulong shale / Gulong shale oil / Micro-nano pores / Lamellar fracture / Continental oil production

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Wenyuan He, Rukai Zhu, Baowen Cui, Shuichang Zhang, Qian Meng, Bin Bai, Zihui Feng, Zhengdong Lei, Songtao Wu, Kun He, He Liu, Longde Sun. The Geoscience Frontier of Gulong Shale Oil: Revealing the Role of Continental Shale from Oil Generation to Production. Engineering, 2023, 28(9): 79‒92 https://doi.org/10.1016/j.eng.2022.08.018

References

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[1]	C.H. Pan. Geological notes: non-marine origin of petroleum in north Shensi, and the Cretaceous of Szechuan, China. China AAPG Bull, 25 (1941), pp. 2058-2068

[2]	L.D. Sun. Gulong shale oil (preface). Pet Geol Oilfield Dev Daqing, 39 (3) (2020), pp. 1-7 [Chinese].

[3]	L.D. Sun, H. Liu, W.Y. He, G.X. Li, S.C. Zhang, R.K. Zhu, et al. An analysis of major scientific problems and research paths of Gulong shale oil in Daqing Oilfield, NE China. Pet Explor Dev, 48 (3) (2021), pp. 527-540

[4]	G.Y. Wang, F.L. Wang, B. Zhao, G.X. Sun, Q.A. Meng, Y.Z. Wang, et al. Exploration and development situation and development strategy of Daqing Oilfield Company. China Pet Explor, 26 (2021), pp. 45-63

[5]	Y.H. Wang, J.P. Liang, J.Y. Zhang, B. Zhao, Y. Zhao, X. Liu, et al. Resource potential and exploration direction of Gulong shale oil in Songliao Basin. Pet Geol Oilfield Dev Daqing, 39 (2020), pp. 20-34 [Chinese].

[6]	J.R. Xie. Petroleum. The Commercial Press, Shanghai (1929) [Chinese].

[7]	Z.J. Jin, R.Z. Bai, B. Gao, M.W. Li. Has China ushered in the shale oil and gas revolution?. Oil Gas Geol, 40 (2019), pp. 451-458 [Chinese].

[8]	Z.J. Jin, R.K. Zhu, X.P. Liang, Y.Q. Shen. Several issues worthy of attention in current lacustrine shale oil exploration and development. Pet Explor Dev, 48 (6) (2021), pp. 1471-1484

[9]	W.Z. Zhao, S.Y. Hu, L.H. Hou, T. Yang, X. Li, B.C. Guo, et al. Types and resource potential of continental shale oil in China and its boundary with tight oil. Pet Explor Dev, 47 (1) (2020), pp. 1-11

[10]	W.Z. Zhao, R.K. Zhu, S.Y. Hu, L.H. Hou, S.T. Wu. Accumulation contribution differences between lacustrine organic-rich shales and mudstones and their significance in shale oil evaluation. Pet Explor Dev, 47 (6) (2020), pp. 1160-1171

[11]	Y.S. Ma, X.Y. Cai, P.R. Zhao, Z.Q. Hu, H.M. Liu, B. Gao, et al. Geological characteristics and exploration practices of continental shale oil in China. Acta Geol Sin, 96 (1) (2022), pp. 155-171 [Chinese].

[12]	R.Q. Gao. Characteristics of petroleum generation and expulsion in abnormal pressure shale zones and the formation of fracture shale reservoirs. Pet Geol Oilfield Dev Daqing, 3 (1984), pp. 160-167 [Chinese].

[13]	S. Jiang, X.L. Tang, O. Steve, A. Thomas. Enrichment factors and current misunderstanding of shale oil and gas: case study of shales in US, Argentina and China. Earth Sci, 42 (7) (2017), pp. 1083-1091 [Chinese].

[14]	M.W. Li, X.X. Ma, Q.G. Jiang, Z.M. Li, X.Q. Pang, C.C. Zhang. Enlightenment from formation conditions and enrichment characteristics of marine shale oil in North America. Pet Geol Recovery Effic, 26 (1) (2019), pp. 13-28 [Chinese]. DOI: 10.3847/1538-4365/ab2465

[15]	G.P. Bai, H.H. Qiu, Z.Z. Deng, W.Y. Wang, J. Chen. Distribution and main controls for shale oil resources in USA. Pet Geol Exp, 42 (4) (2020), pp. 524-532 [Chinese]. DOI: 10.1080/10916466.2020.1772819

[16]	J.H. Fu, S.X. Li, X.B. Niu, X.Q. Deng, X.P. Zhou. Geological characteristics and exploration of shale oil in Chang 7 Member of Triassic Yanchang Formation, Ordos Basin. NW China. Pet Explor Dev, 47 (5) (2020), pp. 931-945

[17]	S.T. Fu, Z.J. Jin, J.H. Fu, S.X. Li, W.W. Yang. Transformation of understanding from tight oil to shale oil in the Member 7 of Yanchang Formation in Ordos Basin and its significance of exploration and development. Acta Petrol Sin, 42 (2021), pp. 561-569 [Chinese].

[18]	D.M. Zhi, Y. Tang, Z.F. Yang, X.G. Guo, M.L. Zheng, M. Wan, et al. Geological characteristics and accumulation mechanism of continental shale oil in Jimusaer Sag, Junggar Basin. Oil Gas Geol, 40 (2019), pp. 524-536 [Chinese].

[19]

X.Z.

Zhao

, L.H.

Zhou

, X.G.

, F.M.

Jin

, W.Z.

Han

, D.Q.

Xiao

, et al. Geological characteristics of shale rock system and shale oil exploration breakthrough in a lacustrine basin: a case study from the Paleogene 1st sub-member of Kong 2 Member in Cangdong Sag, Bohai Bay Basin, China. Pet Explor Dev, 45 (3) (2018), pp. 377-388. DOI: 10.3724/sp.j.1249.2018.04377

[20]	X.Z. Zhao, L.H. Zhou, X.G. Pu, F.M. Jin, Z.N. Shi, W.Z. Han, et al. Formation conditions and enrichment model of retained petroleum in lacustrine shale: a case study of the Paleogene in Huanghua depression, Bohai Bay Basin, China. Pet Explor Dev, 47 (5) (2020), pp. 916-930

[21]	M.Y. Li, S.T. Wu, S.Y. Hu, R.K. Zhu, S.W. Meng, J.R. Yang. Lamination texture and its effects on reservoir and geochemical properties of the Paleogene Kongdian Formation in the Cangdong Sag, Bohai Bay Basin, China. Minerals, 11 (12) (2021), p. 1360. DOI: 10.3390/min11121360

[22]	G.Q. Song, X.Y. Xu, Z. Li, X.H. Wang. Factors controlling oil production from Paleogene shale in Jiyang depression. Oil Gas Geol, 36 (2015), pp. 463-471 [Chinese].

[23]	H.M. Liu, B.S. Yu, Z.H. Xie, S.Y. Han, Z.H. Shen, C.Y. Bai. Characteristics and implications of micro-lithofacies in lacustrine basin organic-rich shale: a case study of Jiyang depression, Bohai Bay Basin. Acta Petrol Sin, 39 (2018), pp. 1328-1343 [Chinese].

[24]	G.X. Li, R.K. Zhu, Y.S. Zhang, Y. Chen, J.W. Cui, Y.H. Jiang, et al. Geological characteristics, evaluation criteria and discovery significance of Paleogene Yingxiongling shale oil in Qaidam Basin, NW China. Pet Explor Dev, 49 (1) (2022), pp. 21-36

[25]	C.N. Zou, Z. Yang, H.Y. Wang, D.Z. Dong, H.L. Liu, Z.S. Shi, et al. “Exploring petroleum inside source kitchen”: Jurassic unconventional giant shale oil & gas field in Sichuan Basin, China. Acta Geol Sin, 93 (2019), pp. 1551-1562 [Chinese].

[26]	W.Y. He, H.Q. He, Y.H. Wang, B.W. Cui, Q.A. Meng, X.J. Guo, et al. Major breakthrough and significance of shale oil of the Jurassic Lianggaoshan Formation in Well Ping’an 1 in northeastern Sichuan Basin, China. Pet Explor, 27 (2022), pp. 40-49

[27]	W.Y. He, Q.A. Meng, J.Y. Zhang. Controlling factors and their classification-evaluation of Gulong shale oil enrichment in Songliao Basin. Pet Geol Oilfield Dev Daqing, 40 (2021), pp. 1-12 [Chinese]. DOI: 10.1504/ijepee.2021.10043255

[28]	W.Y. He, Q.A. Meng, Z.H. Feng, J.Y. Zhang, R. Wang. In-situ accumulation theory and exploration & development practice of Gulong shale oil in Songliao Basin. Acta Petrol Sin, 43 (2022), pp. 1-14 [Chinese].

[29]	W.Y. He, B.W. Cui, F.L. Wang, Y.Z. Wang, Q.A. Meng, J.Y. Zhang, et al. Study on reservoir spaces and oil states of the Cretaceous Qingshankou Formation in Gulong Sag, Songliao Basin. Geol Rev, 68 (2022), pp. 693-741 [Chinese].

[30]	G.L. Hua, S.T. Wu, J.Y. Zhang, X.H. Yu, M.D. Guan, Y. Zhao, et al. Laminar structure differences and heterogeneities in reservoirs in continental organic-rich shales: the Cretaceous Nenjiang Formation in the Songliao Basin. Interpretation, 10 (3) (2022), pp. SD89-106. DOI: 10.1190/int-2021-0156.1

[31]	Y. Cai, R.K. Zhu, Z. Luo, S.T. Wu, T.S. Zhang, C. Liu, et al. Lithofacies and source rock quality of organic-rich shales in the Cretaceous Qingshankou Formation, Songliao Basin, NE China. Minerals, 12 (4) (2022), p. 465

[32]	Z.H. Feng, W. Fang, X. Wang, C.Y. Huang, Q.L. Huo, J.H. Zhang, et al. Microfossils and molecular records in oil shales of the Songliao Basin and implications for paleo-depositional environment. Sci China Ser D Earth Sci, 52 (2009), p. 1559. DOI: 10.1007/s11430-009-0121-0

[33]	Z.H. Feng, W. Fang, Z.G. Li, X. Wang, Q.L. Huo, C.Y. Huang, et al. Depositional environment of terrestrial petroleum source rocks and geochemical indicators in the Songliao Basin. Sci China Earth Sci, 54 (9) (2011), pp. 1304-1317. DOI: 10.1007/s11430-011-4268-0

[34]	Z.H. Feng, Q.L. Huo, H.S. Zeng, Y.Z. Wang, Y.S. Jia. Organic matter compositions and organic pore evolution in Gulong shale of Songliao Basin. Pet Geol Oilfield Dev Daqing, 40 (2021), pp. 40-55 [Chinese].

[35]	H. Cao, W. He, F. Chen, X. Shan, D. Kong, Q. Hou, et al. Integrated chemostratigraphy (δ ¹³C-δ ³⁴S-δ ¹⁵N) constrains Cretaceous lacustrine anoxic events triggered by marine sulfate input. Chem Geol, 559 (2021), Article 119912

[36]	G.D. Zheng, Q.T. Meng, Z.J. Liu. Paleolimnological information of oil shale in 1st member of Qingshankou Formation in northern Songliao Basin. J Jilin Univ, 50 (2) (2020), pp. 392-404 [Chinese].

[37]	W.L. Yang, R.Q. Gao, Q.F. Guo, Y.G. Liu. Continental petroleum generation, migration and accumulation in the Songliao Basin. Heilongjiang Science & Technology Press, Harbin (1985) [Chinese].

[38]	R.Q. Gao, X.Y. Cai. Forming conditions and distribution of petroleum fields in the Songliao Basin. Petroleum Industry Press, Beijing (1997) [Chinese].

[39]	Q.J. Hou, Z.Q. Feng, Z.H. Feng. Continental petroleum geology in the Songliao Basin. Petroleum Industry Press, Beijing (2009) [Chinese].

[40]	B.P. Tissot, D.H. Welte.Petroleum formation and occurrence. ( 2nd ed.), Springer verlag, Berlin (1984)

[41]	J.P. Chen, Y.G. Sun, N.N. Zhong, Z.K. Huang, C.P. Deng, L.J. Xie, et al. The efficiency and model of petroleum expulsion from the lacustrine source rocks within geological frame. Acta Geol Sin, 88 (2014), pp. 2005-2032 [Chinese].

[42]	J.J. Sweeney, A.K. Burnham. Evaluation of a simple model of vitrinite reflectance based on chemical kinetics. AAPG Bull, 74 (10) (1990), pp. 1559-1570

[43]	M.J. Wilson, L. Wilson, M.V. Shaldybin. Clay mineralogy and unconventional hydrocarbon shale reservoirs in the USA. II. Implications of predominantly illitic clays on the physico-chemical properties of shales. Earth Sci Rev, 158 (2016), pp. 1-8. DOI: 10.1097/01.EEM.0000508429.81220.5b

[44]	K.L. Milliken, M. Rudnicki, D.N. Awwiller, T.W. Zhang. Organic matter-hosted pore system, Marcellus Formation (Devonian), Pennsylvania. AAPG Bull, 97 (2013), pp. 177-200. DOI: 10.1306/07231212048

[45]	S.T. Wu, Z. Yang, X.F. Zhai, J.W. Cui, L.S. Bai, S.Q. Pan, et al. An experimental study of organic matter, minerals and porosity evolution in shales within high-temperature and high-pressure constraints. Mar Pet Geol, 102 (2019), pp. 377-390

[46]	F.W.G. Julia, E.L. Stephen, E.O. Jon, E. Peter, F. András. Natural fractures in shale: a review and new observations. AAPG Bull, 98 (11) (2014), pp. 2165-2216

[47]	M. Pommer, K. Milliken. Pore types and pore-size distributions across thermal maturity, Eagle Ford Formation, southern Texas. AAPG Bull, 99 (9) (2015), pp. 1713-1744. DOI: 10.1306/03051514151

[48]	C.Z. Jia, X.Q. Pang, Y. Song. The mechanism of unconventional hydrocarbon formation: hydrocarbon self-sealing and intermolecular forces. Pet Explor Dev, 48 (3) (2021), pp. 507-526

[49]	T. Hu, X.Q. Pang, F.J. Jiang, Q.F. Wang, X.H. Liu, Z. Wang, et al. Movable oil content evaluation of lacustrine organic-rich shales: methods and a novel quantitative evaluation model. Earth Sci Rev, 214 (2021), Article 103545

[50]	Y.J. Han, B. Horsfield, R. Wirth, N. Mahlstedt, S. Bernard. Oil retention and porosity evolution in organic-rich shales. AAPG Bull, 101 (06) (2017), pp. 807-827. DOI: 10.1306/09221616069

[51]	Y.J. Han, B. Horsfield, N. Mahlstedt, R. Wirth, D.J. Curry, H. LaReau. Factors controlling source and reservoir characteristics in the Niobrara shale oil system, Denver Basin. AAPG Bull, 103 (9) (2019), pp. 2045-2072. DOI: 10.1306/0121191619717287

[52]

K.E.

Gorynski

, M.H.

Tobey

, D.A.

Enriquez

, T.M.

Smagala

, J.L.

Dreger

, R.E.

Newhart

. Quantification and characterization of hydrocarbon filled porosity in oil-rich shales using integrated thermal extraction, pyrolysis, and solvent extraction. AAPG Bull, 103 (3) (2019), pp. 723-744. DOI: 10.1306/08161817214

[53]	M.F. Romero-Sarmiento. A quick analytical approach to estimate both free versus sorbed hydrocarbon contents in liquid-rich source rocks. AAPG Bull, 103 (9) (2019), pp. 2031-2043. DOI: 10.1306/02151918152