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Meso-Cenozoic negative inversion model for the Linhe Depression of Hetao Basin, China

Published online by Cambridge University Press:  01 December 2021

Fusheng Yu*
Affiliation:
State Key Laboratory of Petroleum Resources and Prospecting, China University of Petroleum (Beijing), Beijing, China Department of Earth Sciences, China University of Petroleum (Beijing), Beijing, China
Ruifeng Zhang
Affiliation:
Exploration Department of Huabei Oilfield Company, PetroChina, Renqiu, China
Jiafu Yu
Affiliation:
Department of Earth Sciences, China University of Petroleum (Beijing), Beijing, China
Yidan Wang
Affiliation:
Department of Earth Sciences, China University of Petroleum (Beijing), Beijing, China
Shuguang Chen
Affiliation:
Exploration Department of Huabei Oilfield Company, PetroChina, Renqiu, China
Jing Liu
Affiliation:
Exploration Department of Huabei Oilfield Company, PetroChina, Renqiu, China
Chenlin Wu
Affiliation:
Exploration Department of Huabei Oilfield Company, PetroChina, Renqiu, China
Yiqun Wang
Affiliation:
Exploration Department of Huabei Oilfield Company, PetroChina, Renqiu, China
Shaochun Wang
Affiliation:
Exploration Department of Huabei Oilfield Company, PetroChina, Renqiu, China
Yuheng Wang
Affiliation:
Department of Earth Sciences, China University of Petroleum (Beijing), Beijing, China
Yilun Liu
Affiliation:
Department of Earth Sciences, China University of Petroleum (Beijing), Beijing, China
*
Author for correspondence: Fusheng Yu, Email: [email protected]

Abstract

The Linhe Depression is the largest tectonic unit in the Hetao Basin. The recently discovered commercial oil flow in the structural trap of wells JH2X and S5 has proved that the Meso-Cenozoic strata in the Linhe Depression have great exploration potential. Research on the kinematic model for the Mesozoic–Cenozoic Linhe Depression is important for analysing the geological conditions of hydrocarbon accumulation. In this study, field observations, seismic interpretation and scaled analogue modelling are performed. The results prove that the Linhe Depression experienced different stages of tectonic evolution, such as compressional depression (K1l), conversion from contraction to uniform subsidence (K1g), extensional rifting (E2–N2) and strike-slip deformation (Q), during the Mesozoic–Cenozoic eras. The kinematic model of negative inverted basins was first established with the early differential compression superimposed by the late extension. The seismic interpretation and analogue modelling results show that Jilantai Sag in the southern part of the Linhe Depression was subjected to compression from the Bayanwulashan fold–thrust belt on the NW side and the Helanshan fold–thrust belt on the SE side during Early Cretaceous time. Meanwhile, the Hanghou Sag in the northern part of the Linhe Depression was only compressed by the Langshan fold–thrust belt from the NW direction. The rifted structure generated by the extension from the SE direction during the Cenozoic Era resulted in the negative inversion of the pre-existing thrusts in different patterns. The intensity of negative inversion is controlled by several key factors, such as dip angle and the patterns of thrust faults, along with different basement textures. The morphological changes in the forebulge zone developed during Early Cretaceous time are responsible for the development of the segmented Central fault zones in the Hanghou Sag.

Type
Original Article
Copyright
© The Author(s), 2021. Published by Cambridge University Press

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References

Anderson, EM (1951) The Dynamics of Faulting. Edinburgh: Oliver and Boyd.Google Scholar
Brace, WF and Kohlstedt, DL (1980) Limits on lithospheric stress imposed by laboratory experiments. Journal of Geophysical Research 85, 6248–52.CrossRefGoogle Scholar
Buiter, SJH (2012) A review of brittle compressional wedge models. Tectonophysics 530–531, 117.CrossRefGoogle Scholar
Cai, MT, Ye, PS and Yang, XC (2018) Evolution of sedimentary environment in the north Hetao basin since 344ka. Journal of Geomechanics 24, 253–62 (in Chinese with English abstract).Google Scholar
Darby, BJ and Ritts, BD (2007) Mesozoic structural architecture of the Lang Shan, North-Central China: Intraplate contraction, extension, and synorogenic sedimentation. Journal of Structural Geology 29, 2006–16.CrossRefGoogle Scholar
DeCelles, PG and Giles, KA (1996) Foreland basin systems. Basin Research 8, 105–23.CrossRefGoogle Scholar
Del Ventisette, C, Bonini, M, Maestrelli, D, Sani, F, Iavarone, E and Montanari, D (2021) 3D-thrust fault pattern control on negative inversion: An analogue modelling perspective on central Italy. Journal of Structural Geology 143, 104254, doi: 10.1016/j.jsg.2020.104254.CrossRefGoogle Scholar
Del Ventisette, C, Montanari, D, Bonin, M and Sani, F (2006) Basin inversion and fault reactivation in laboratory experiments. Journal of Structural Geology 28, 2067–83.CrossRefGoogle Scholar
Deng, Q, Chen, S, Min, W, Yang, G and Ren, D (1999) Discussion on Cenozoic tectonics and dynamics of Ordos block (in Chinese with English abstract). Journal of Geomechanics 5, 1321.Google Scholar
Dong, SP, Zhang, PZ, Zheng, WJ, Yu, ZY, Lei, QY, Yang, HL, Liu, JF and Gong, HL (2018) Paleoseismic observations along the Langshan range-front fault, Hetao Basin, China: Tectonic and seismic implications. Tectonophysics 730, 6380.CrossRefGoogle Scholar
Du, XY, Ding, WL, Jiao, BC, Zhou, ZC and Xue, MW (2019) Fluid potential and hydrocarbon migration: Accumulation unit classification in Linhe Depression of Hetao Basin. Special Oil and Gas Reservoir 26, 915 (in Chinese with English abstract).Google Scholar
Faccenna, C, Nalpas, T, Brun, JP and Davy, P (1995) The influence of pre-existing thrust faults on normal fault geometry in nature and in experiments. Journal of Structure Geology 17, 1139–49.CrossRefGoogle Scholar
Fu, ST, Fu, JH, Yu, J, Yao, JL, Zhang, CL, Ma, ZR, Yang, YJ and Zhang, Y (2018) Petroleum geological features and exploration prospect of Linhe Depression in Hetao Basin, China. Petroleum Exploration and Development 45, 803–17.CrossRefGoogle Scholar
Guo, ZM and Yu, ZP (1990) Structural characteristics, mechanism of evolution and petroleum prospecting of Hetao Graben system. Petroleum Exploration and Development 17, 1120 (in Chinese with English abstract).Google Scholar
Hoshino, K, Koide, H, Lnami, K, Lwarmura, S and Mitsui, S (1972) Mechanical properties of Japanese Tertiary sedimentary rocks under high confined pressure. Geological Survey of Japan Report 244, 200.Google Scholar
Jagger, LJ and McClay, KR (2018) Analogue modelling of inverted domino-style basement fault systems. Basin Research 30 (Suppl.1), 363–81.CrossRefGoogle Scholar
Jolivet, L, Daniel, JM and Foumier, M (1991) Geometry and kinematics of the Alpine Corsica. Earth and Planetary Science Letters 104, 278–91.CrossRefGoogle Scholar
Koyi, H (1997) Analogue modelling: From a qualitative to a quantitative technique, a historical outline. Journal of Petroleum Geology 20, 223–38.CrossRefGoogle Scholar
Koyi, H and Peterson, K (1993) Influence of basement faults on the development of salt structures in the Danish Basin. Marine and Petroleum Geology 10, 8294.CrossRefGoogle Scholar
Koyi, H and Vendeville, BC (2003) The effect of decollement dip on geometry and kinematics of model accretionary wedges. Journal of Structural Geology 25, 1445–50.CrossRefGoogle Scholar
Liu, SF (1998) The coupling mechanism of basin and orogen in the western Ordos Basin and adjacent regions of China. Journal of Asian Earth Sciences 16, 369–83.CrossRefGoogle Scholar
Malavielle, J (1987) Kinematics of compressional and extensional ductile shearing deformation in a metamorphic core complex of the North-Eastern Basin and Range. Journal of Structure Geology 9, 541–54.CrossRefGoogle Scholar
McClay, KR (1990) Deformation mechanics in analogue models of extensional fault systems. In Deformation Mechanisms, Rheology and Tectonics (eds Knipe, RJ and Rutter, E.H.), pp. 445–53. Geological Society of London, Special Publication no. 54.Google Scholar
Nei Mongol Bureau of Geology and Mineral Resources (NMBGMR) (1991) Regional Geology of Nei Mongol Autonomous Region. Beijing: Geological Publishing House.Google Scholar
Nei Mongol Bureau of Geology and Mineral Resources (NMBGMR) (1996) Multiple Classification and Correlation of the Stratigraphy of China (15): Stratigraphy (Lithostratic) of Nei Mongol Autonomous Region Bureau of Geology and Mineral Resources of Nei Mongol Autonomous Region. Wuhan: China University of Geosciences Press, 313 pp.Google Scholar
Ori, GG and Friend, PG (1984) Sedimentary basins, formed and carried piggyback on active thrust sheets. Geology 12, 475–78.2.0.CO;2>CrossRefGoogle Scholar
Ramberg, H (1981) Gravity, Deformation and Earth’s Crust. San Diego, CA: Academic, 452 pp.Google Scholar
Rao, G, Chen, P, Hu, JM, Yu, YL and Qiu, JH (2016) Timing of Holocene paleo-earthquakes along the Langshan Piedmont Fault in the western Hetao Graben, North China: Implications for seismic risk. Tectonophysics 677–678, 115–24.CrossRefGoogle Scholar
Shi, JM, Shi, SS, Wu, XW, Gao, T, Yang, HZ, Zhang, L, Song, WB and Chen, TY (2019) Spatial structure characteristics of gravity high anomaly combination in volcanic areas: A case study of northeast Inner Mongolia. Geology and Resources 28, 482–88.Google Scholar
Smith, RB and Bruhn, RL (1984) Intraplate extensional tectonics of the eastern Basin and Range: interferences of structural styles from seismic reflection data, regional tectonics, and thermal mechanical models of brittle-ductile deformation. Journal of Geophysical Research 89, 5733–62.CrossRefGoogle Scholar
Sun, LX, Zhang, Y, Hu, XJ, Ren, BF, Wang, SQ and Zhang, TF (2018) Geochemical characteristics and zircon U-Pb geochronology of Paleoproterozoic metamorphic granites from northern Langshan, Inner Mongolia: Magmatic response to the breakup of Columbia supercontinent. Acta Petrologica Sinica 34, 3116–36 (in Chinese with English abstract).Google Scholar
Weijermars, R and Schmeling, H (1986) Scaling of Newtonian and non-Newtonian fluid dynamics without inertia for quantitative modelling of rock flow due to gravity (including the concept of rheological similarity). Physics of the Earth and Planetary Interiors 43, 316–30.CrossRefGoogle Scholar
Williams, GD, Powell, CM and Cooper, MA (1989) Geometry and kinematics of inversion tectonics. In Inversion Tectonics (eds Cooper, MA and Williams, GD), pp. 315. Geological Society of London, Special Publication no. 44.Google Scholar
Yang, H, Li, MC and Cui, YP (2005) Accumulation condition and exploration prospects of biogenic gas in Hetao Basin. China Petroleum Exploration 3, 1621 (in Chinese with English abstract).Google Scholar
Yang, HF, Zhang, YL and Meng, RF (2017) Study on water controlling mechanism of structures and dividing result of groundwater system in Hetao Basin, Inner Mongolia. Journal of Arid Land Resources and Environment 31, 177–85 (in Chinese with English abstract).Google Scholar
Yang, XY and Dong, YP (2018) Mesozoic and Cenozoic multiple deformations in the Helanshan Tectonic Belt, Northern China. Gondwana Research 60, 3453.CrossRefGoogle Scholar
Yu, FS and Koyi, H (2016) Cenozoic tectonic model of the Bohai Bay Basin in China. Geological Magazine 153, 866–86.CrossRefGoogle Scholar
Yu, FS and Koyi, H (2017) Theoretical and experimental estimation of geometric relationship of non-parallel conjugate normal faults. Tectonophysics 703–704, 8597.CrossRefGoogle Scholar
Zhang, YM, Zhang, RF, Wang, SC, Liu, XH, Li, YJ, Liu, J, Wang, HL, Wang, J, Wu, CL and Dan, WN (2018) Practice and understanding of great discovery in oil and gas exploration in Linhe depression of Hetao Basin. China Petroleum Exploration 23, 111 (in Chinese with English abstract).Google Scholar
Zhao, CY, Guo, ZM and Hui, BY (1984) Hetao arcuate tectonic system and their mechanism of formation and evolution. Oil & Gas Geology 5, 349–61 (in Chinese with English abstract).Google Scholar
Zhao, MW (1988) Characteristics of the fault activity in Hetao Basin and its relation with oil and gas. Journal of Northwest University 18, 8594 (in Chinese with English abstract).Google Scholar
Zwaan, F, Schreurs, G and Buiter, SJH (2019) A systematic comparison of experimental set-ups for modelling extensional tectonics. Solid Earth 10, 1063–97.CrossRefGoogle Scholar
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