Reservoir Diagenesis

Chapter
Part of the Advances in Oil and Gas Exploration & Production book series (AOGEP)

Abstract

Diagenetic evolution in petroliferous basins is usually one of the main research focus areas in oil and gas exploration. However, clastic reservoir diagenesis is influenced by numerous factors, including mainly basin tectonic evolution, depositional system distribution, burial history, thermal evolution history, and underground water solution activity. As a result, petroleum geologists should consider the structure, deposition, and diagenesis of a basin and take them as an organic whole for the analysis and research of porosity evolution in a certain period or at a certain position. In addition, multi-disciplinary theories and methods should be applied to discuss the law that the hole varies with the evolution of time, space, and position. Similar to the factors influencing reservoir heterogeneity, as mentioned in Chap.  6, the macro factors determining the reservoir pore development law are ① tectonic evolution stage, ② sedimentary pattern complexity, and ③ diagenesis diversity.

References

  1. Boles, J.R., and S.G. Franks. 1979. Clay diagenesis in Wilcox Sandstones of SW Texas: Implications of smectite diagenesis on sandstone cementation. Journal of Sedimentary Petrology 49 (1): 55–70.Google Scholar
  2. Chilingarian, G.V., R.W. Mannon and H. Rieke. 1972. Oil and gas production from carbonate rocks. Amsterdam: Elsevier Publishing Company, 408 p.Google Scholar
  3. Chen, Lihua,and Jiang Zaixing. 1993. Reservoir experimental testing techniques, 220–232. Beijing: Petroleum Industry Press.Google Scholar
  4. Coustau, H. 1977. Formation waters and hydrodynamics. Journal of Geochemical Exploration 7: 213–241.CrossRefGoogle Scholar
  5. Crossey L.J., Frost B.R. and Surdam R.C. 1984. Secondary porosity in laumontite bearing sandstones, clastic diagenesis. AAPG Mem2 oir 37: 225–238.Google Scholar
  6. Demaison, G., and B.J. Huizinga, 1989. Genetic classification of petroleum basins: AAPG Bulletin (United States), 73: 3.Google Scholar
  7. Foster, J.E. 2004. Observation of quartz cathode-luminescence in a low pressure plasma discharge.Google Scholar
  8. Gengsheng, He. 1994. Oil reservoir physics. Beijing: Petroleum Industry Press.Google Scholar
  9. Giles, M.R., and R.B.D. Boer, 1990. Origin and significance of redistributional secondary porosity: Marine & Petroleum Geology, 7: 378–397.Google Scholar
  10. Guohua, Zhu. 1985a. Formation of lomonitic sand bodies with secondary porosity and their relationship with hydrocarbons. Acta Sedimentologica Sinica 6 (1): 1–8. Google Scholar
  11. Guohua, Zhu. 1985b. Formation of low permeability sandbodies and secondary pore sandbodies in the upper permian Yanchang series of South-western Shan-Gan-Ning Basin. Acta Sedimentologica Sinica 3(2). Google Scholar
  12. Guohua, Zhu. 1992. Origin and evolution and prediction of porosity in clastic reservoir rocks. Acta Sedimentologica Sinica 10 (3): 114–132.Google Scholar
  13. Hayes J B. 1979. Sandstone diagenesis; the hole truth (in aspects of diagenesis). Special Publication—Society of Economic Paleontologists and Mineralogists (26): 127–139.Google Scholar
  14. He, J.Y. and Meng, X.H. 1987. Sediments and Sedimentary Facies Model and Construction. Beijing: Geological Publishing House.Google Scholar
  15. Hoffman, J., and J. Hower. 1979. Clay mineral assemblages as low grade metamorphic indicators: Application to the trust-faulted disturbed belt of Montana U. S. A. SEPM. Special Publication No 26, 55–80.Google Scholar
  16. Houseknecht, D.W. 1987. Assessing the relative importance of compaction processes and cementation to reduction of porosity in sandstones. AAPG Bulletin 71: 633–642.Google Scholar
  17. Hunt, J.M. 1977. Distribution of carbons as hydrocarbons and asphalic compounds in sedimentary rocks. AAPG 61(1).Google Scholar
  18. Hutcheon I., Abercrombie H. 1990. Carbon dioxide in clastic rocks and silicate hydrolysis. Geology 18: 541–544.Google Scholar
  19. Junmao, Zheng, and Pang Ming. 1989. Research on diagenesis of clastic reservoirs. Wuhan: China University of Geosciences Press.Google Scholar
  20. Kharaka, Y.K., D.J. Specht, and W.W. Carothers, 1985. Low to intermediate subsurface temperatures calculated by chemical geothermometers: AAPG Bulletin (United States), 69: 2.Google Scholar
  21. Krynine P.D. 1949. Mineralogical research on oil reservoirs. Mineral Industries (University Park) 18(4): 1–3.Google Scholar
  22. Liangtian, Sun, et al. 1992. Reservoir physics experiment. Beijing: Petroleum Industry Press.Google Scholar
  23. MacGowan D., Surdam R.C. 1988. Difuetional carboxylic acid anions in oil-field water. Organic Geochemistry 12: 245–259.Google Scholar
  24. Schmidt V., McDonald D.A. 1979. Texture and recognition of secondary porosty in sandstones. SEPM.SPEC.Pub.No26, 209–225.Google Scholar
  25. Schmidt V., McDonald D.A. 1979. The role of secondary porosity in the course of sandstone diagenesis (in Aspects of diagenesis). Special Publication - Society of Economic Paleontologists and Mineralogists (March 1979), 26: 175–207Google Scholar
  26. Surdam, R.C., S.W. Boese, and L.J. Crossey. 1984. The chemistry of secondary porosity (in Clastic diagenesis). AAPG Memoir 37: 127–149.Google Scholar
  27. Surdam R.C., Crossey L.J., et al. 1989. Organic-inorganic and sandstone diagenesis. AAPG Bulletin 73: 1–23.Google Scholar
  28. Surdam R.C., Wolfbauer C.A. 1975. Green River Formation, Wyoming; a playa-lake complex, Bulletin of the Geological Society of America 86(3): 335–345.Google Scholar
  29. Wilson, M.D., and E.D. Pittman. 1977. Authigenic clays in sandstones: Recognition and influence on reservoir properties and paleo environmental analysis: Journal of Sedimentary Research, 47, 3–31.Google Scholar
  30. Wu, S.H. and Xiong, Q.H. 1998. Oil and gas reservoir geology. Beijing: Petroleum Industry Press.Google Scholar
  31. Wu, Y.Y. et al. 1996. Hydrocarbon Reservoir Geology. Beijing: Petroleum Industry Press.Google Scholar
  32. Ying, F.X. and Wang, Y.Q. 1990. Elemental composition of minerals and cathodoluminescence. Journal of Chinese Electron Microscopy Society.(3): 244–244.Google Scholar
  33. Yongshang, Kang, and Wang Jie. 1999. Fluid dynamic systems and the formation of oil and gas pools. Acta Petrolei Sinica 20 (1): 30–33.Google Scholar
  34. Yu, X.H. 2002. Clastic Hydrocarbon Reservoir Sedimentology. Beijing: Petroleum Industry Press.Google Scholar
  35. Yu Xinghe, Junmao Zheng et al. 1997. The establishment of integrated model on structure, deposition and diagenesis. Acta Sedimentologica Sinica 15(3).Google Scholar
  36. Yu Xinghe, Junmao Zheng, Liheng Song et al. 1997. Faulted basin delta sandbody sedimentation and reservoir intrastratal heterogeneity. Earth Sciences 22(1).Google Scholar
  37. Yu, Xinghe, Daojian Zhang et al. 1999. Depositional facies model of deep shahejie formation in eastern and western depressions in Liaohe Oilfield. Journal of Palaeogeography 1(3).Google Scholar
  38. Zhao, C.L. et al. 1992. Sedimentary System and Diagenesis of Paleogene Clastic Rocks in Dongpu Depression. Beijing: Petroleum Industry Press.Google Scholar
  39. Zheng, J.M. and Pang, M. 1989. Study on diagenesis of clastic reservoir rocks. Wuhan: China University of Geosciences Press.Google Scholar
  40. Zimkernagel, M.U. 1978. Cathodoluminescence of quartz and its application to sandstone. Petrology, Stuttgart.Google Scholar

Copyright information

© Springer International Publishing AG, part of Springer Nature 2018

Authors and Affiliations

  1. 1.China University of GeosciencesBeijingChina
  2. 2.China University of GeosciencesBeijingChina

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