Geobiological approach to evaluating marine carbonate source rocks of hydrocarbon

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• 作者：HongFu Yin (1)
  ShuCheng Xie (1)
  JiaXin Yan (1)
  ChaoYong Hu (1)
  JunHua Huang (2)
  Tenger (3)
  WenKun Qie (1)
  Xuan Qiu (1)
  
• 关键词：geobiological evaluation ; carbonate source rocks ; parameters ; proxies
• 刊名：Science China Earth Sciences
• 出版年：2011
• 出版时间：August 2011
• 年：2011
• 卷：54
• 期：8
• 页码：1121-1135
• 全文大小：1098KB
• 参考文献：1. Mu S L, ed. Explotation Theory, Technology and Practice for Oil and Gas in China鈥檚 Marine Strata (in Chinese). Beijing: Geological Publishing House, 2009. 752
  2. Jin Z J, Wang Q C. Prediction on the Petroleum Formation, Enrichment and Distribution of the Typical Congruent Basins in China (in Chinese). Beijing: Science Press, 2007. 381
  3. Qing J Z. The Petroleum Source Rocks of China (in Chinese). Beijing: Science Press, 2005. 614
  4. Francois R, Honojo S, Manganini S J. Biogenic barium fluxes to the deep sea: Implications for palaeoproductivity reconstruction. Global Biogeochem Cycles, 1995, 5: 289鈥?03 CrossRef
  5. Hayes J M, Strauss H, Kaufman A J. The abundance of 未¹³C in marine organic matter and isotopic fractionation in the global biogeochemical cycle of carbon during the past 800 Ma. Chem Geol, 1999, 161: 103鈥?25 CrossRef
  6. McManus J, William M B, Silke S. Molybdenum and uranium geochemistry in continental margin sediments: Paleoproxy potential. Geochim Cosmochim Acta, 2006, 70: 4643鈥?662 CrossRef
  7. Meyers S R, Sageman B B, Lyons T W. Organic carbon burial rate and the molybdenum proxy: Theoretical framework and application to Cenomanian-Turonian oceanic anoxic event 2. Paleoceanography, 2005, 20: 2002鈥?020 CrossRef
  8. Rimmer S M. Geochemical paleoredox indicators in Devonian-Mississippian black shales, Central Appalachian Basin (USA). Chem Geol, 2004, 206: 373鈥?91 CrossRef
  9. Siebert C, McManus J, Bice A, et al. Molybdenum isotope signatures in continental margin marine sediments. Earth Planet Sci Lett, 2006, 241: 723鈥?33 CrossRef
  10. Tyson R V. The 鈥減roductivity versus preservation鈥?controversy: cause, flaws, and resolution. In: Harris N B, ed. The Deposition of Organic-carbon-rich Sediments: Models, Mechanisms, and Consequences. Oklahoma: Soc Sediment Geol, 2005. 17鈥?3
  11. Vet艖 I, P茅ter O, Istv谩n F, et al. Extension of carbon flux estimation to oxic sediments based on sulphur geochemistry and analysis of benthic foraminiferal assemblages: A case history from the Eocene of Hungary. Palaeogeogr Palaeoclimat Palaeoecol, 2007, 248: 119鈥?44 CrossRef
  12. Xie S C, Yin H F, Xie X N, et al. On the geobiological evaluation of hydrocarbon source rocks. Front Earth Sci China, 2007, 1: 389鈥?98 CrossRef
  13. Yin H F, Xie S C, Qing J Z, et al. Discussion on geobiology, biogeology, and geobiofacies. Sci China Ser D-Earth Sci, 2008, 51: 1516鈥?524 CrossRef
  14. Ziegler A M. Silurian marine communities and their environmental significance. Nature, 1965, 207: 270鈥?72 CrossRef
  15. Boucot A J. Principles of Benthic Marine Paleoecology. New York: Academic Press, 1981. 463
  16. Yin H F, Ding M H, Zhang K X, et al. Dongwuan-Indosinian (Late Permian-Middle Triassic) Ecotratigraphy of the Yangtze Region and its Margins (in Chinese). Beijing: Science Press, 1995. 338
  17. Cisne J L, Rabe B D. Coenocorrelation: Gradient analysis of fossil communities and its application in stratigraphy. Lethaia, 1978, 11: 341鈥?64 CrossRef
  18. Dodd J R, Stanton R J. Paleoecology, Concepts and Applications. New York: John Wiley and Sons, 1981. 559
  19. Grice K, Cao C Q, Love G D, et al. Photic zone euxinia during the Permian-Triassic superanoxic event. Science, 2005, 307: 706鈥?09 CrossRef
  20. Summons R E, Jahnke J J, Hope J M, et al. 2-Methylhopanoids as biomarkers for cyanobacterial oxygenic photosynthesis. Nature, 1999, 400: 554鈥?57 CrossRef
  21. Xie S C, Lai X L, Huang X Y, et al. Principles, methodology and application of molecular stratigraphy. J Stratigr, 2007, 31: 209鈥?21
  22. Mucci A, Sundby B, Gehlen M, et al. The fate of carbon in continental shelf sediments of Eastern Canada: A case study. Deep-Sea Res, 2000, 47: 733鈥?60 CrossRef
  23. Ibach L E J. Relationship between sedimentation rate and total organic carbon content in ancient marine sediments. AAPG Bull, 1982, 66: 170鈥?88
  24. Tyson R V, Pearson T H. Modern and ancient continental shelf anoxia: An overview. In: Tyson R V, Pearson T H, eds. Modern and Ancient Continental Shelf Anoxia. Geol Soc Spec Publ, 1991, 58: 1鈥?4
  25. Huang J H, Luo G M, Bai X, et al. Organic fraction of the total carbon burial flux deduced from carbon isotopes across the Permo-Triassic boundary at Meishan, Zhejiang Province, China. Front Earth Sci China, 2007, 1: 425鈥?30 CrossRef
  26. Tait V. Elements of Marine Ecology. 3rd ed. London: Butterworths Scientific, 1981. 345
  27. Takeda S, Ramaiaha N, Mikia M, et al. Biological and chemical characteristics of high-chlorophyll, low-temperature water observed near the Sulu Archipelago. Deep-Sea Res, 2007, 54: 81鈥?02 CrossRef
  28. Paytan A, Kastner M, Chavez F P. Glacial to interglacial fluctuations in productivity in the equatorial Pacific as indicated by marine barite. Science, 1996, 274: 1355鈥?357 CrossRef
  29. McManus J, Berelson W M, Klinkhammer G P. Geochemistry of barium in marine sediments: Implications for its use as a paleoproxy. Geochim Cosmochim Acta, 1998, 62: 3458鈥?473 CrossRef
  30. Murray R W, Leinen M. Scavenged excess aluminum and its relationship to bulk titanium in biogenic sediment from the central equatorial Pacific Ocean. Geochim Cosmochim Acta, 1996, 60: 3869鈥?878 CrossRef
  31. Tonger, Liu W H, Xu Y C. The discussion on anoxic environments and its geochemical identifying indices. Acta Sediment Sin, 2004, 22: 365鈥?72
  32. Watanabe S, Tada R, Ikehara K, et al. Sediment fabrics, oxygenation history, and circulation modes of Japan Sea during the Late Quaternary. Palaeogeogr Palaeoclimat Palaeoecol, 2007, 247: 50鈥?4 CrossRef
  33. Raiswell R, Buckley F, Berber R A, et al. Degree of pyritization of iron as a paleoenvironmental indicator of bottom-water oxygenation. J Sediment Petrol, 1988, 58: 812鈥?19
  34. Hatch J R, Leventhal J S. Relationship between inferred redox potential of the depositional environment and geochemistry of the Upper Pennsylvanian (Missourian) stark shale member of the Dennis Limestone, Wabaunsee County, Kansas, USA. Chem Geol, 1992, 99: 65鈥?2 CrossRef
  35. Jones B, Manning D A C. Comparison of geochemical indices used for the interpretation of palaeoredox conditions in ancient mudstones. Chem Geol, 1994, 111: 111鈥?29 CrossRef
  36. Berner R A. The long-term carbon cycle, fossil fuels and atmospheric composition. Nature, 2003, 426: 323鈥?26 CrossRef
  37. Kump L R, Arthur M A. Interpreting carbon isotope excursions: Carbonates and organic matter. Chem Geol, 1999, 161: 181鈥?98 CrossRef
  38. Zheng Y F, Chen J F. The Geochemistry of Stable Isotopes (in Chinese). Beijing: Science Press, 2000. 231
  39. Zhou L, Huang J H, Archer C, et al. Molybdenum isotope composition from Yangtze block continental margin and its indication to organic burial rate. Front Earth Sci China, 2007, 1: 417鈥?24 CrossRef
  40. Raiswell R, Berner R A. Pyrite formation in euxinic and semi-euxinic sediments. Am J Sci, 1985, 285: 710鈥?24 CrossRef
  41. Mozley P S, Burns S J. Oxygen and carbon isotopic composition of marine carbonate concretions: An overview. J Sediment Petrol, 1993, 61: 73鈥?3
  42. Huggett J M, Gale A S, Evans S. Carbonate concretions from the London Clay (Ypresian, Eocene) of Southern England and the exceptional preservation of wood-boring communities. J Geol Soc, 2000, 157: 187鈥?00 CrossRef
  43. Woo K S, Khim B K. Stable oxygen and carbon isotopes of carbonate concretions of the Miocene Yeonil Group in the Pohang Basin, Korea: Types of concretions and formation condition. Sedimen Geol, 2006, 183: 15鈥?0 CrossRef
  44. Dymond J, Suess E, Lyle M. Barium in the deep-sea sediment: A geochemical proxy for paleoproductivity. Paleoceanography, 1992, 7: 163鈥?81 CrossRef
  45. Deuser W G, Brewer P G, Jickells T D, et al. Biological control of the removal of abiogenic particles from the surface ocean. Science, 1983, 219: 388鈥?90 CrossRef
  46. Raiswell R A. Geochemical framework for the application of stable sulfur isotopes to fossil pyritization. J Geol Soc, 1997, 154: 343鈥?56 CrossRef
  47. Zhou L, Zhang H Q, Wang J, et al. Assessment on redox conditions and organic burial of siliciferous sediments at the latest Permian Dalong Formation in Shangsi, Sichuan, South China. J China Univ Geosci, 2008, 19: 496鈥?06 CrossRef
  48. Yang H, Wang Y B, Chen L, et al. Calci-microbialite as a potential source rock and its geomicrobiological processes. Front Earth Sci China, 2007, 1: 438鈥?43 CrossRef
  49. Gehman H M Jr. Organic matter in limestones. Geochim Cosmochim Acta, 1962, 26: 885鈥?97 CrossRef
  50. Yan J X. Origin of Permian Chihsian carbonates from South China and its geological implications (in Chinese with English abstract). Acta Sediment Sin, 2004, 22: 579鈥?87
  51. Yan J X, Liu X Y. Geobiological interpretation of the oxygen-deficient deposits of the middle Permian marine source rocks in South China: A working hypothesis (in Chinese with English abstract). Earth Sci鈥擩 China Univ Geosci, 2007, 32: 789鈥?96
  
• 作者单位：HongFu Yin (1)
  ShuCheng Xie (1)
  JiaXin Yan (1)
  ChaoYong Hu (1)
  JunHua Huang (2)
  Tenger (3)
  WenKun Qie (1)
  Xuan Qiu (1)
  
  1. State Key Laboratory of Biogeology and Environmental Geology, China University of Geosciences, Wuhan, 430074, China
  2. State Key Laboratory of Geological Process and Mineral Resources, China University of Geoscience, Wuhan, 430074, China
  3. Wuxi Institute of Petroleum Geology, SINOPEC, Wuxi, 214151, China
  
• ISSN：1869-1897

文摘

Evaluating the pre-Jurassic marine source rocks in China has been difficult because these rocks are generally too high- or over-maturated for most traditional methods to work. As to the remaining parameter TOC (%), its lower limit for recognizing the carbonate source rocks in China has been in dispute. Nineteen Phanerozoic sections in the Middle-Upper Yangtze Platform and the Guizhou-Hunan-Guangxi Basin have been studied in search for a different approach to complementing the traditional evaluation method for these source rocks. We have applied a geobiological approach to tracing the organic carbon (OC) output and accumulation from the living stage (primary productivity) to the post-mortem deposited remains, and finally to the preserved burial organics. Four biological and geological parameters are employed to represent the OC of the three stages. A series of proxies of these parameters are discussed and integrated to establish a geobiological evaluation system independent of TOC and other traditional methods. Here we use the Guangyuan section in Sichuan as an example for the geobiological evaluation. Our results indicate that in the argillaceous rocks, the geobiological parameters show the qualified source rocks in accordance with high TOC values; but in the carbonates, the good source rocks delineated by the geobiological parameters have a wide range of TOC, from 0.03% to 1.59%, mostly <0.3%. We suggest that it is still premature to set TOC=0.3% or 0.5% as the lower limit for the pre-Jurassic carbonate source rocks in South China.