Sedimentary facies of marine shale gas formations in Southern China: The Lower Silurian Longmaxi Formation in the southern Sichuan Basin

Yizhen Li , Xingzhi Wang , Bin Wu , Guoqin Li , Dule Wang

Journal of Earth Science ›› 2016, Vol. 27 ›› Issue (5) : 807 -822.

PDF
Journal of Earth Science ›› 2016, Vol. 27 ›› Issue (5) : 807 -822. DOI: 10.1007/s12583-015-0592-1
Article

Sedimentary facies of marine shale gas formations in Southern China: The Lower Silurian Longmaxi Formation in the southern Sichuan Basin

Author information +
History +
PDF

Abstract

Sedimentary facies is an important factor influencing shale gas accumulation. It not only controlls hydrocarbon generation, but also affects reservoir characteristics and distribution. This paper discusses the Lower Silurian Longmaxi Formation in the south of the Sichuan Basin. Outcrop, core, drilling and logging data identify the sedimentary facies of the formation as continental shelf facies, which is divided into two subfacies: an inner shelf and an outer shelf subfacies. These two subfacies can be further divided into seven microfacies: muddy silty shallow shelf, calcareous silty shallow shelf, muddy limy shallow shelf, storm flow, muddy deep shelf, silty muddy deep shelf and contour current microfacies. Vertical and horizontal distribution of microfacies establishes a sedimentation model of the continental shelf facies. Combined with analization or calculation of geochemical, mineralogical, physical and gas-bearing properties of samples, sedimentary microfacies is evaluated using nine parameters: total organic carbon content, effective shale continuous thickness, vitrinite reflectance, kerogen type, mineral components, porosity, permeability, water saturation and gas content. The evaluation revealed that the most favorable facies for shale gas exploration and development are the muddy deep shelf and part of the silty muddy deep shelf microfacies, with TOC more than 2%, siliceous component over 50%, clay less than 30%, porosity more than 3%, water saturation lower than 40%, gas content greater than 2 m3/t. These results provide a theoretical basis for deciston-making on the most promising areas for shale gas exploration in the Sichuan Basin and for marine shale gas exploration and development in South China.

Keywords

Sichuan Basin / shale gas / Longmaxi Formation / sedimentary facies / continental shelf

Cite this article

Download citation ▾
Yizhen Li, Xingzhi Wang, Bin Wu, Guoqin Li, Dule Wang. Sedimentary facies of marine shale gas formations in Southern China: The Lower Silurian Longmaxi Formation in the southern Sichuan Basin. Journal of Earth Science, 2016, 27(5): 807-822 DOI:10.1007/s12583-015-0592-1

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Abouelresh M. O., Slatt R. M. Lithofacies and Sequence Stratigraphy of the Barnett Shale in East-Central Fort Worth Basin, Texas. AAPG Bulletin, 2012, 96(1): 1-22.

[2]

Aplin A. C., Macquaker J. H. S. Mudstone Diversity: Origin and Implications for Source, Seal, and Reservoir Properties in Petroleum Systems. AAPG Bulletin, 2011, 95(12): 2031-2059.

[3]

Bjørlykke K. Relationships between Depositional Environments, Burial History and Rock Properties, Some Principal Aspects of Diagenetic Process in Sedimentary Basins. Sedimentary Geology, 2014, 301: 1-14.

[4]

Bowker K. A. Recent Development of the Barnett Shale Play, FortWorth Basin, West Texas. Geological Society Bulletin, 2003, 42(6): 4-11.
[5]

Bowker K. A. Barnett Shale Gas Production, Fort Worth Basin: Issues and Discussion. AAPG Bulletin, 2007, 91(4): 523-533.

[6]

Boyer C. M., Kieschinick J., Suarez-Rivera R., . Producing Gas from Its Source, 2006, 37-49.
[7]

Bureau of GeologyMineral Resources of Sichuan Province Regional Geology of Sichuan Province, 1991 Beijing: Geology Press
[8]

Bureau of GeologyMineral Resources of Sichuan Province Multiple Classification and Correlation of the Stratigraphy of China (51)—Stratigraphy (Lithostratic) of Sichuan Province, 1997 Wuhan: China Uninversity of Geoscineces Press
[9]

Chen X., Rong J., Li Y., . Facies Patterns and Geography of the Yangtze Region, South China, through the Ordovician and Silurian Transition. Palaeogeography, Palaeoclimatology, Palaeoecology, 2004, 204: 353-372.

[10]

Cluff R. M., Dickerson D. R. Natural Gas Potential of the New Albany Shale Group (Devonian–Mississippian) in Southeastern Illinois, 1982, 21-28.
[11]

Curtis J. B. Fractured Shale-Gas System. AAPG Bulletin, 2002, 86(11): 1921-1938.
[12]

Dai J., Zou C., Liao S., . Geochemistry of the Extremely High Thermal Maturity Longmaxi Shale Gas, Southern Sichuan Basin. Organic Geochemistry, 2014, 74: 3-12.

[13]

Editorial Board of Shale Gas Geology, ExplorationDevelopment Practice Collection Progress of Shale Gas Exploration and Development in China, 2011 Beijing: Petroleum Industry Press
[14]

Fang J., Chen Q., Melchin M. J., . Quantitative Stratigraphy of the Wufeng and Lungmachi Black Shales and Graptolite Evolution during and after the Late Ordovician Mass Extinction. Palaeogeography, Palaeoclimatology, Palaeoecology, 2013, 389: 96-114.

[15]

Feng G., Chen S. Relationship between the Reflectance of Bitumen and Vitrinite in Rock. Gas Industry, 1988, 8(3): 20-26.
[16]

Friedman G. M., Sanders J. E. Principles of Sedimentology, 1978 New York: John Wiley and Sons
[17]

Gareth R. L., Marc B. R. Lower Cretaceous Gas Shales in Northeastern British Columbia, Part I: Geological Controls on Methane Sorption Capacity. Bulletin of Canadian Petroleum Geology, 2008, 56(1): 1-21.

[18]

Gentzis T., Goodarzi F. A Review of the Use of Bitumen Reflectance in Hydrocarbon Exploration with Examples from Melville Island, Arctic Canada. Rocky Mountain Section (SEPM), 1990, 23-26.
[19]

Guo L., Jiang Z., Jiang W. Formation Condition of Gas-Bearing Shale Reservoir and Its Geological Research Target. Geological Bulletin of China, 2011, 30(2–3): 385-392.
[20]

Guo Y., Li Z., Li D., . Lithofacies Palaeogeography of the Early Silurian in Sichuan Area. Journal of Palaeogeography, 2004, 6(1): 20-29.
[21]

Harris L. D., DeWitt W., Colton G. W. What Are Possible Stratigraphic Controls for Gas Fields in Eastern Black Shale?. Oil and Gas Journal, 1978, 76(14): 162-165.
[22]

Hickey J. J., Henk B. Lithofacies Summary of the Mississippian Barnett Shale, Mitchell 2 T.P. Sims well, Wise County, Texas. AAPG Bulletin, 2007, 91(4): 437-443.
[23]

Hill D. G., Lombardi T. E., Martin J. P. Fractured Shale Gas Potential in New York. Northeastern Geology and Environmental Sciences, 2004, 26(1/2): 57-78.
[24]

Jarvie D. M., Hill R. J., Porllstro R. M., . Evaluation of Hydrocarbon Generation and Storage in the Barnett Shale. Fort Worth Basin, Texas. Ellison Miles Memorial Symposium, 2004, 22-23.
[25]

Jarvie D. M., Hill R. J., Ruble T. E., . Unconventional Shale Gas Systems: the Mississippian Barnett Shale of North Central Texas as One Model for Thermogenic Shale Gas Assessment. AAPG Bulletin, 2007, 91(4): 475-499.

[26]

Jenkins C. D., Boyer C. M. Coalbed- and Shale-Gas Reservoirs. JPT, 2008, 60(1): 92-99.

[27]

Jia C., Zheng M., Zhang Y. Unconventional Hydrocarbon Resources in China and the Prospect of Exploration and Development. Petroleum Exploration and Development, 2012, 39(2): 139-146.

[28]

Li T. The Principal Geological Feature of Oil-Forming Formation in Sichuan Basin. Mineralogy and Petrology, 1991, 11(3): 80-87.
[29]

Li Y., Fan T., Gao Z., . Sequence Stratigraphy of Silurian Black Shale and Its Distribution in the Southeast Area of Chongqing. Natural Gas Geoscience, 2012, 23(2): 299-306.
[30]

Liang C., Jiang Z., Yang Y., . Characteristics of Shale lithofacies and Reservoir Space of the Wufeng-Longmaxi Formation, Sichuan Basin. Petroleum Exploration and Development, 2012, 39(6): 691-698.
[31]

Liang D., Guo T., Bian L., . Some Progresses on Studies of Hydrocarbon Generation and Accumulation in Marine Sedimentary Regions, Southern China (Part 1): Distribution of Four Suits of Regional Marine Source Rocks. Marine Oil and Gas Geology, 2008, 13(2): 1-16.
[32]

Liang D., Guo T., Bian L., . Some Progresses on Studies of Hydrocarbon Generation and Accumulation in Marine Sedimentary Regions, Southern China (Part 3): Controlling Factors on the Sedimentary Facies and Development of Palaeozoic Marine Source Rocks. Marine Oil and Gas Geology, 2009, 14(2): 1-19.
[33]

Lin B., Su Y., Zhu X., . Stratigraphy of China (Silurian), 1998 Beijing: Geology Press
[34]

Liu B., Xu X. Atlas of the Lithofacies and Palaeogeography of South China, 1994 Beijing: Science Press.
[35]

Liu S., Deng B., Li Z., . Architecture of Basin-Mountain Systems and Their Influences on Gas Distribution: A Case Study from the Sichuan Basin, South China. Journal of Asian Earth Sciences, 2012, 47: 204-215.

[36]

Loucks R. G., Ruppel S. C. Mississippian Barnett Shale: Lithofacies and Depositional Setting of a Deep-Water Shale-Gas Succession in the Fort Worth Basin, Texas. AAPG Bulletin, 2007, 91(4): 579-601.

[37]

Loydell D. K. Early Silurian Sea-Level Changes. Geological Magazine, 1998, 135(4): 447-471.

[38]

Ma, L., Chen, H., Gan, K., et al., 2004). Tectonics and Marine Oil and Gas Geology in South China. Geology Press, Beijing (in Chinese)
[39]

Ma Y., Chen H., Wang G., . Sequence Stratigraphy and Palaeogeography of South China, 2009 Beijing: Science Press.
[40]

Martineau D. F. History of the Newark East Field and the Barnett Shale as a Gas Reservoir. AAPG Bulletin, 2007, 91(4): 399-403.

[41]

Meyers P. A. Paleoceanographic and Paleoclimatic Similarities between Mediterranean Sapropels and Cretaceous Black Shales. Palaeogeography, Palaeoclimatology, Palaeoecology, 2006, 235: 305-320.

[42]

Montgomery S. L., Jarvie D. M., Bowker K. A., . Mississippian Barnett Shale, Fort Worth Basin, North-Central Texas: Gas Shale Play with Multi-Trillion Cubic Foot Potential. AAPG Bulletin, 2005, 89: 155-175.

[43]

Mu C., Zhou K., Liang W., . Early Paleozoic Sedimentary Environment of Hydrocarbon Source Rocks in the Middle–Upper Yangtze Region and Petroleum and Gas Exploration. Acta Geologica Sinica, 2011, 85(4): 526-532.
[44]

Mu E., Zhu Z., Chen J., . Silurian in Shuanghe Changning, Sichuan. Journal of Stratigraphy, 1983, 7(3): 208-215.
[45]

Mu E., Boucot A. J., Chen X., . Correlation of the Silurian Rocks of China. Special Paper of the Geological Society of America, 1986, 202: 1-80.

[46]

Picard M. D. Classification of Fine-Grained Sedimentary Rocks. Journal of Sedimentary Research, 1971, 41(1): 179-195.
[47]

Pollastro R. M. Geological and Production Characteristics Utilized in Assessing the Barnett Shale Continuous (Unconventional) Gas Accumulation. Barnett–Paleozoic Total Petroleum System, Fort Worth Basin, Texas: Barnett Shale Symposium, 2003, 6.
[48]

Potter P. E., Maynard J. B., Depetris P. J. Mud and Mudstones, 2005 Berlin Heidelberg: Springer-Verlag
[49]

Slatt R. M., Philp P. R., Abousleiman Y., . Breyer J. A., . Pore-to-Regional-Scale Integrated Characterization Workflow for Unconventional Gas Shales. Shale Reservoirs—Giant Resources for the 21st Century, 2012, 127-150.
[50]

Slatt R. M., Rodriguez N. D. Comparative Sequence Stratigraphy and Organic Geochemistry of Gas Shales: Commonality or Coincidence?. Journal of Natural Gas Science and Engineering, 2012, 8: 68-84.

[51]

Sondergeld C. H., Newsham K. E., Comisky J. T., . Petrophysical Considerations in Evaluating and Producing Shale Gas Resources, 2010
[52]

Stevenson D. L., Dickerson D. R. Organic Geochemistry of the New Albany Shale in Illinois. Illinois State Geological Survey, Illinois Petroleum, 1969, 90: 1-11.
[53]

Committee of Petroleum Geology Exploration of Professional Standards, 2012). Determination of Vitrinite Reflectance in Sedimentary Rocks: SY/T 5124–2012.
[54]

Standards Press of China, Beijing Committee of Petroleum Geology Exploration of Professional Standards, 1996). Indentification of Maceral and Division of Kerogen Type by Transmitted and Fluorescent Light: SY/T 5125-1996.
[55]

Standards Press of China, Beijing Committee of Petroleum Geology Exploration of Professional Standards, 2010). Analysis Method for Clay Minerals and Ordinary Non-Clay Minerals in Sedimentary Rocks by X–ray Diffraction: SY/T 5163-2010.
[56]

Standards Press of China, Beijing Committee of Petroleum Geology Exploration of Professional Standards, 2013). Measurement Method of Shale Gas Content: SY/T 6940-2013.
[57]

Standards Press of China, Beijing Committee of Petroleum Geology Exploration of Professional Standards Determination of Total Organic Carbon in Sedimentary Rock: GB/T 19145-2003, 2003 Beijing: Standards Press of China
[58]

Wang H. Atlas of the Palaeogeography of China, 1985 Beijng: China Cartographic Press
[59]

Whelan J. K., Thompson-Rizer C. L. Michael H. E., Stephen A. M. Chemical Methods for Assessing Kerogen and Protokerogen Types and Maturity. Organic Geochemistry, 1993 New York: Plenum Press, 289-353.

[60]

Wignall P. B. Model for Transgressive Black Shales?. Geology, 1991, 19(2): 167-170.

[61]

Xiao X., Liu D., Fu J. The Significance of Bitumen Reflectance as a Mature Parameter of Source Rocks. Acta Sedimentologica Sinica, 1991, 9: 138-146.
[62]

Zhai G. M., Wang S. S. Petroleum Geology of China, Part 10: Sichuan Petroleum Region, 1989 Beijing: Petroleum Industry Press
[63]

Zheng H., Hu Z. Atlas of Tectonic and Lithofacies Palaeogeography in Pre-Mesozoic in China, 2010 Beijing: Geology Press, 1-194.
[64]

Zheng H., Gao B., Peng Y., . Sedimentary Evolution and Shale Gas Exploration Direction of the Lower Silurian in Middle–Upper Yangtze Area. Journal of Palaeogeography, 2013, 15(5): 645-656.
[65]

Zhou M., Wang R., Li Z., . Ordovician and Silurian Lithofacies Palaeogeography and Mineralization in South China, 1993 Beijng: Geology Press
[66]

Zou C., Dong D., Wang S., . Geological Characteristics and Resource Potential of Shale Gas in China. Petroleum Exploration and Development, 2010, 37(6): 641-653.

[67]

Zou C., Tao S., Hou L., . Unconventional Petroleum Geology, 2013 Beijing: Geology Press, 127-129.
AI Summary AI Mindmap
PDF

162

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/