Control of neotectonic movement on hydrocarbon accumulation in the Kuqa Foreland Basin, west China

详细信息    查看全文

• 作者：Zhenxue Jiang (1) (2)
  Lianxia Li (1) (2)
  Yan Song (3)
  Fenghua Tian (4)
  Mengjun Zhao (3)
  Haijiang Wang (5)
  Zhenxing Zhao (6)
  
• 关键词：Kuqa Foreland Basin ; neotectonic movement ; accumulation element ; accumulation process ; accumulation model
• 刊名：Petroleum Science
• 出版年：2010
• 出版时间：March 2010
• 年：2010
• 卷：7
• 期：1
• 页码：49-58
• 全文大小：4249KB
• 参考文献：1. Cheng D L, Jing C R and Zhong X B. On neotectonic movement and crust stability. Journal of Xianning College. 2007. 27(6): 111鈥?14 (in Chinese)
  2. Gao R Q and Zhao Z Z. China New Area Exploration (Vol. 1): Exploration of Large Gas Fields in the Kuqa Depression in Tarim Basin. Beijing: Petroleum Industry Press. 2001 (in Chinese)
  3. Glover C and Robertson A. Neotectonic intersection of the Aegean and Cyprus tectonic arcs: extensional and strike-slip faulting in the Isparta Angle, SW Turkey. Tectonophysics. 1998. 298(1鈥?): 103鈥?32 CrossRef
  4. Granja H M, Ribeiro I C, de Carvalho G S, et al. Some neotectonic indicators in Quaternary formations of the northwest coastal zone of Portugal. Physics and Chemistry of the Earth, Part A: Solid Earth and Geodesy. 1999. 24(4): 323鈥?36 CrossRef
  5. Guo Z Q and Shi J H. Characteristics of the hydrocarbon system in Qaidam Basin with an active new structural movement. Petroleum Geology & Oilfield Development in Daqing. 2001. 20(1): 9鈥?2 (in Chinese)
  6. Guo Z Q, Xu W F and Peng W. Continental crust and basic characteristics of petroleum systems in western China. Xinjiang Petroleum Geology. 1999. 20(5): 336鈥?43 (in Chinese)
  7. Hao F, Zou H Y, Gong Z S, et al. The material and energy effects of neotectonics/late-stage tectonics and petroleum accumulation. Acta Geological Sinica. 2006. 80(3): 424鈥?31 (in Chinese)
  8. Jia C Z, He D F and Shi X. Himalayan movement and late hydrocarbon accumulation. In: Symposium on Control of Himalayan Movement on Sedimentary Basins and Late Hydrocarbon Accumulation in China. 2004. 11鈥?8 (in Chinese)
  9. Jia C Z, He D F, Shi X, et al. Characteristics of late hydrocarbon accumulation in China. Science in China (Series D: Earth Sciences). 2006. 36(5): 412鈥?20 (in Chinese)
  10. Jia X L, Zhao H J, Zhang S Q, et al. New tectonic movement and its ecological environment influences in Yangtze River source area. Plateau Earthquake Research. 2008. 20(2): 34鈥?0 (in Chinese)
  11. Jiang F J, Jiang Z X, Pang X Q, et al. Hydrocarbon accumulation conditions and advantageous exploration targets in foreland basins of central-western China. Xinjiang Petroleum Geology. 2007. 28(1): 1鈥? (in Chinese)
  12. Jiang Z X, Pang X Q, Jin Z J, et al. Relationship between pore variation of reservoir and rebounding of sandstone during uplift and its application to the Daqing Oilfield. Earth Science鈥擩ournal of China University of Geosciences. 2004. 29(4): 420鈥?27 (in Chinese)
  13. Jiang Z X, Pang X Q, Tian F H, et al. Tectonic uplifting and pressure releasing and the effect of hydrocarbon accumulation. Journal of Jianghan Petroleum Institute. 2006. 28(3): 47鈥?0 (in Chinese)
  14. Jiang Z X, Pang X Q, Zeng J H, et al. Research on types of the dominant migration pathways and their physical simulation experiments. Earth Science Frontiers. 2005. 12(4): 507鈥?16 (in Chinese)
  15. Jin W Z, Tang L J, Wang Q H, et al. Cenozoic tectonic evolution of the eastern Qiulitage structural belt, Kuqa foreland basin in Xinjiang. Chinese Journal of Geology. 2007. 42(3): 444鈥?54 (in Chinese)
  16. Kirillova G L. Late Mesozoic-Cenozoic sedimentary basins of active continental margin of Southeast Russia: paleogeography, tectonics, and coal-oil-gas presence. Marine and Petroleum Geology. 2003. 20(3鈥?): 385鈥?97 CrossRef
  17. Kontorovich V A. The Meso-Cenozoic tectonics and petroleum potential of West Siberia. Russian Geology and Geophysics. 2009. 50(4): 346鈥?57 CrossRef
  18. Li D W. Neotectonics and Hydrocarbon Accumulation in the Huanghua Depression. Wuhan: China University of Geosciences Press. 2006 (in Chinese)
  19. Li H Y, Jiang Z X, Lin S G, et al. The distribution rules of oil and gas in the foreland basins of central-western China. West China Petroleum Geosciences. 2006. 2(4): 368鈥?73 (in Chinese)
  20. Liu Z H, Lu H F, Jia C Z, et al. Determination of orogency time in the Kuqa foreland thrust belt. Earth Science Frontiers. 1999. 6(4): 236鈥?41 (in Chinese)
  21. Liu Z H, Lu H F, Li X J, et al. Tectonic evolution of the Kuqa rejuvenated foreland basin. Chinese Journal of Geology. 2000. 35(4): 482鈥?92 (in Chinese)
  22. Lu H F, Jia D, Chen C M, et al. Nature and timing of the Kuqa Cenozoic structures. Earth Science Frontiers. 1999. 6(4): 215鈥?21 (in Chinese)
  23. Lykousis V, Anagnostou C, Pavlakis P, et al. Quaternary sedimentary history and neotectonic evolution of the eastern part of Central Aegean Sea, Greece. Marine Geology. 1995. 128(1): 59鈥?1 CrossRef
  24. Pang X Q. Accumulation mechanism and distribution rule of hydrocarbon in typical superimposed basins in western China. Oil & Gas Geology. 2008. 29(2): 157鈥?58 (in Chinese)
  25. Pang X Q, Gao J B, L眉 X X, et al. Reservoir accumulation pattern of multifactor recombination and procession superimposition and its application in the Tarim Basin. Acta Petrolei Sinica. 2008. 29(2): 159鈥?72 (in Chinese)
  26. Qi J F, Lei G L, Li M G, et al. A model of contractional structure for transition belt between the Kuche Depression and the Southern Tianshan Uplift. Earth Science Frontiers. 2009. 16(3): 120鈥?28 (in Chinese) CrossRef
  27. Qiang Z J and Wang H T. Study of Active Structure. Beijing: Earthquake Press. 1992 (in Chinese)
  28. Qin S F, Dai J X, Zhao J Z, et al. Control of the neotectonics in China on natural gas accumulation. Geological Review. 2006. 52(1): 94鈥?9 (in Chinese)
  29. Redfield T F, Torsvik T H, Andriessen P A M, et al. Mesozoic and Cenozoic tectonics of the M酶re Tr酶ndelag Fault Complex, central Norway: constraints from new apatite fission track data. Physics and Chemistry of the Earth, Parts A/B/C. 2004. 29(10): 673鈥?82 CrossRef
  30. Shi W Z, Chen H H and He S. Quantitative evaluation on contribution of structural compression to overpressure and analysis of origin of overpressure in the Kuqa Depression. Acta Petrolei Sinica. 2007. 28(6): 60鈥?5 (in Chinese)
  31. Song Y and Wang X S. The controlling action of modern structural movement on the late accumulation of natural gas. Natural Gas Geoscience. 2003. 14(2): 103鈥?06 (in Chinese)
  32. Song Y, Fang D Q and Xia X Y. The formation of abnormal pressure and its relationship with natural gas accumulation. Achievements of the program 鈥淓xploration & Development Study of Large and Middle Gas Fields in China鈥? 2000 (in Chinese)
  33. Song Y, Hong F, Xia X Y, et al. Syngenesis relationship between abnormal overpressure and gas pool formation鈥攚ith the Kuqa Depression as an example. Petroleum Exploration and Development. 2006. 33(3): 303鈥?08 (in Chinese)
  34. Sun J Z, Li L B, Zhou X Y, et al. Analysis on the typical structural styles and deformation mechanism of the Kelasu tectonic zone in the Kuqa Depression of the Tarim Basin. Petroleum Geology & Experiment. 2003. 25(3): 247鈥?50 (in Chinese)
  35. Tang L J, Jia C Z, Pi X J, et al. Salt-related structural styles of fold belts in the Kuqa foreland basin. Science in China, Series D. 2003. 33(1): 38鈥?6 (in Chinese)
  36. Tang L J, Wan G M, Wang Q H, et al. Tectonic evolution of the western Qiulitage tectonic belt in the Mesozoic and Cenozoic, Kuqa Depression. Journal of Southwest Petroleum University (Science & Technology Edition). 2008. 30(2): 167鈥?71 (in Chinese)
  37. Wang X S, Li J C, Wang S M, et al. Oil and gas accumulation and structural stress field in the Tarim Basin. Acta Petrolei Sinica. 1997. 18(1): 23鈥?7 (in Chinese)
  38. Xu Z P, Wu C, Ma L K, et al. Salt-related structure styles and their genetic mechanisms in the middle of the Kuqa Depression. Natural Gas Geoscience. 2009. 20(3): 356鈥?61 (in Chinese)
  39. Yu Y X, Tang L J, Wang Q H, et al. Salt structures and forming models of hydrocarbon pools in the Kuqa Depression. Coal Geology & Exploration. 2005. 33(6): 5鈥? (in Chinese)
  40. Zhang J R, Chen P and Zhong J W. Neotectonics characteristics of the Yanshan water reservoir and their relationship with engineering construction. Henan Water Resources & South-to-North Water Diversion. 2007. (2): 33鈥?4 (in Chinese)
  41. Zhang Z P, Lin W and Wang Q C. Progressive structural evolution of the Kelasu-Yiqikelike structural belt in the Kuqa Depression. Geotectonica et Metallogenia. 2003. 27(4): 327鈥?36 (in Chinese)
  42. Zhao M J, Song Y, Qin S F, et al. The multi-stage formation of oil-gas pools and late-stage accumulation of gas in the foreland basins in central and western China. Earth Science Frontiers. 2005. 12(4): 525鈥?32 (in Chinese)
  43. Zheng M, Meng Z F, Li X B, et al. Characteristics of the hydrocarbon system in the Kuqa Basin with an active new structural movement. Acta Scientiarum Naturalium Universitatis Sunyatseni. 2005. 44(z1): 305鈥?10 (in Chinese)
  44. Zheng M, Peng G X, Lei G L, et al. Structural pattern and its control on hydrocarbon accumulations in the Wushi Sag, Kuche Depression, Tarim Basin. Petroleum Exploration and Development. 2008. 35(4): 444鈥?51 (in Chinese) CrossRef
  45. Zhou X X. Oil and gas pool forming process and tectonic evolution of Cenozoic in the Kuqa petroleum system of the Tarim Basin. Journal of Palaeogeography. 2002. 4(1): 75鈥?2 (in Chinese)
  46. Zhu R, Lou Z H and Jin A M. A study of dynamic process of gas reservoiring in the Mesozoic and Cenozoic in the Kuqa Depression. Natural Gas Industry. 2006. 26(5): 5鈥? (in Chinese)
  
• 作者单位：Zhenxue Jiang (1) (2)
  Lianxia Li (1) (2)
  Yan Song (3)
  Fenghua Tian (4)
  Mengjun Zhao (3)
  Haijiang Wang (5)
  Zhenxing Zhao (6)
  
  1. State Key Laboratory of Petroleum Resources and Prospecting, China University of Petroleum, Beijing, 102249, China
  2. Basin and Reservoir Research Center, China University of Petroleum, Beijing, 102249, China
  3. Exploration and Development Research Institute, PetroChina, Beijing, 100083, China
  4. Department of Exploration & Development, PetroChina CBM Limited Company, Beijing, 100013, China
  5. Exploration Department, Tarim Oilfield Company, PetroChina, Kuerle, Xinjiang, 841000, China
  6. No.8 Oil Production Plant, Changqing Oilfield Company, PetroChina, Xi鈥檃n, Shaanxi, 710018, China
  
• ISSN：1995-8226

文摘

Neotectonic movement refers to the tectonic movement that has happened since the Cenozoic, which is the latest movement. It has the most important influence on the basins in west China, especially on the hydrocarbon accumulation in the western foreland basins. We determined the time of neotectonic movement in the Kuqa Foreland Basin, which began from the Neogene, and analyzed the patterns of movement, which were continuous and fast subsidence in the vertical direction and intense lateral compression. The structure styles are that the faulting is weakened and the folding is strengthened gradually from north to south. We studied the control of neotectonic movement on the hydrocarbon accumulation process and model in the Kuqa Foreland Basin with basin simulation technique. The largest subsidence rate of the Kuqa Foreland Basin reached 1,200 m/Ma during the neotectonic movement, leading to rapid maturing of source rock within 5 Ma and a large quantity of hydrocarbon being generated and expelled. The thick neotectonic strata can form high quality reservoirs with the proved gas and oil reserves accounting for 5% and 27% of the total reserves, respectively. 86% of the structural traps were formed in the neotectonic movement period. The faults formed during the neotectonic movement serve as important migration pathways and they exist in the region where the hydrocarbon reservoirs are distributed. Abnormally high pressure caused by the intense lateral compression, thick neotectonic strata deposition and rapid hydrocarbon generation provide driving force for hydrocarbon migration. The accumulation elements match each other well over a short period, leading to many large gas fields formed later in the Kuqa Foreland Basin.