Division and characteristics of shale parasequences in the upper fourth member of the Shahejie Formation, Dongying Depression, Bohai Bay Basin, China

Jing Wu; Zaixing Jiang

doi:10.1007/s12583-016-0943-6

Journal of Earth Science ›› 2017, Vol. 28 ›› Issue (6) : 1006 -1019. DOI: 10.1007/s12583-016-0943-6

Article

Division and characteristics of shale parasequences in the upper fourth member of the Shahejie Formation, Dongying Depression, Bohai Bay Basin, China

Jing Wu ¹^,²^,³^,^a
, Zaixing Jiang ⁴

Author information +

History +

PDF

Abstract

Shale parasequence analysis is an important part of sequence stratigraphy sudies. This paper proposed a systematic research method for analyzing shale parasequences including their delineation, division, characteristics and origins. The division method is established on the basis of lithofacies. Multi-method analysis and mutual verification were implemented by using auxiliary indicators (such as mineral compositions, geochemical indicators and wavelet values). A typical shale parasequence comprises a lower interval of deepening water-depth and an upper interval of shallowing water-depth (e.g., a shale parasequence including a high-total organic carbon (TOC) shale-low-TOC limy shale). Abrupt increases in pyrite content, TOC value, relative hydrocarbon generation potential ((S1+S2)/TOC), and wavelet values are indicative of parasequence boundaries. The proposed research method was applied to study the upper fourth member of the Shahejie Formation in the Dongying depression, Bohai Bay Basin. Results show that there were seven types of parasequences developed. A singular and a dual structured parasequences were identified. Three factors controlling the development of the shale parasequences were identified including relative lake level change, terrestrial input and transgression. The development of high-TOC (>2%) shale parasequences was mainly controlled by biological and chemical sedimentation. The low-TOC (<2%) shale parasequences were mainly deposited by chemical sedimentation. The diversities of shale parasequences were caused by four major controlling factors including climate, relative lake level change, terrestrial input and emergency (e.g., transgression).

Keywords

shale / parasequence / Dongying depression / Shahejie Formation

Cite this article

Download citation ▾

Jing Wu, Zaixing Jiang. Division and characteristics of shale parasequences in the upper fourth member of the Shahejie Formation, Dongying Depression, Bohai Bay Basin, China. Journal of Earth Science, 2017, 28(6): 1006-1019 DOI:10.1007/s12583-016-0943-6

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]	Angulo S., Buatois L. A. Integrating Depositional Models, Ichnology, and Sequence Stratigraphy in Reservoir Characterization: The Middle Member of the Devonian–Carboniferous Bakken Formation of Subsurface Southeastern Saskatchewan Revisited. AAPG Bulletin, 2012, 96(6): 1017-1043.

[2]	Arthur M. A., Sageman B. B. Sea-Level Control on Source-Rock Development: Perspectives from the Holocene Black Sea, the Mid-Cretaceous Western Interior Basin on North America, and the Late Devonian Appalachian Basin. SEPM Special Publication, 2004, 82: 35-59.

[3]	Berner R. A. Sedimentary Pyrite Formation: An Update. Geochimica et Cosmochimica Acta, 1984, 48(4): 605-615.

[4]	Catuneanu O. Principles of Sequence Stratigraphy, 2006.

[5]	Charles M. J., Simmons M. S. Methods for the Determination of Carbon in Soils and Sediments—A Review.. The Analyst, 1986, 111(4): 385-390.

[6]	Creaney S., Passey Q. R. Recurring Patterns of Total Organic Carbon and Source Rock Quality within a Sequence Stratigraphic Framework. AAPG Bulletin, 1993, 77(3): 386-401.

[7]	Davies S. J., Elliott T. Spectral Gamma Ray Characterization of High Resolution Sequence Stratigraphy: Examples from Upper Carboniferous Fluvio-Deltaic Systems, County Clare, Ireland. Geological Society, London, Special Publications, 1996, 104(1): 25-35.

[8]	Deng H. W., Qian K. The Genetic Types and Association Evolution of Deep Lacustrinefacies Mudstones. Acta Sedimentologica Sinica, 1990, 8(3): 1-20.

[9]	Jiang N. Y., Jia R. F., Wang Z. Y. Permian Paleogeography and Geochemical Environment in Lower Yangtze Region, China, 1994.

[10]	Li Y. Z., Wang X. Z., Wu B., . 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.

[11]	Liang C., Jiang Z. X., Cao Y. C., . Deep-Water Depositional Mechanisms and Significance for Unconventional Hydrocarbon Exploration. AAPG Bulletin, 2016, 100: 773-794.

[12]	Liang C., Jiang Z. X., Cao Y. C., . Sedimentary Characteristics and Origin of Lacustrine Organic-Rich Shales in the Salinized Eocene Dongying Depression. GSA Bulletin, 2017.

[13]	Liang C., Cao Y. C., Jiang Z. X., . Shale Oil Potential of Lacustrine Black Shale in the Eocene Dongying Depression: Implications for Geochemistry and Reservoir. AAPG Bulletin, 2017.

[14]	Liu Z. H. Orbital Cycles Analysis and Its Genesis Significance for the Sequence Hierarchy: A Case Study of Carboniferous Karashayi Formation, Central Tarim Basin. Journal of Earth Science, 2012, 23(4): 516-528.

[15]	Liu Z. J., Sun P. C., Jia J. L., . Distinguishing Features and Their Genetic Interpretation of Stratigraphic Sequence in Continental Deep Water Setting: A Case from Qingshankou Formation in Songliao Basin. Earth Science Frontiers, 2011, 18(4): 171-180.

[16]	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.

[17]	Miall A. D. Exxon Global Cycle Chart: An Event for Every Occasion?. Geology, 1992, 20(9): 787-790.

[18]	Passey Q. R., Creaney S., Kulla J. B., . A Practical Model for Organic Richness from Porosity and Resistivity Logs. AAPG Bulletin, 1990, 74(12): 1777-1794.

[19]	Prokoph A., Agterberg F. P. Wavelet Analysis of Well-Logging Data from Oil Source Rock, Egret Member, Offshore Eastern Canada. AAPG Bulletin, 2000, 84(10): 1617-1632.

[20]	Qian K., Wang S. M., Liu S. F., . Tertiary Reef Limestone Found in the Northern East China and Its Significance in Petroleum Geology. Science Bulletin, 1980, 25(12): 1025-1029.

[21]	Rioul O., Vetterli M. Wavelets and Signal Processing. IEEE Signal Processing Magazine, 1991, 8(4): 14-38.

[22]	Schutter, S. R., 1998. Characterization of Shale Deposition in Relation to Stratigraphic Sequence Systems Tracts. In: Schieber, J., Zimmerle, W., Sethi, P., eds., Shales and Mudstones I. E. Schweizerhbart’sche Verlagsbuchhandlung, Stuttgart, Germany

[23]	Singh P. Lithofacies and Sequences Stratigraphic Framework of the Barnett Shale: [Dissertation], 2008.

[24]	Slatt R. M., Abousleiman Y. Merging Sequence Stratigraphy and Geomechanics for Unconventional Gas Shales. The Leading Edge, 2011, 30(3): 274-282.

[25]	Slatt R. M., Philp P. R., Abousleiman Y., . Pore-to-Regional-Scale Integrated Characterization Workflow for Unconventional Gas Shales. AAPG Memoir, 2012, 97: 127-150.

[26]	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(8): 68-84.

[27]	Smith M. G., Bustin R. M. Late Devonian and Early Mississippian Bakken and Exshaw Black Shale Source Rocks, Western Canada Sedimentary Basin: A Sequence Stratigraphic Interpretation. AAPG Bulletin, 2000, 84(7): 940-960.

[28]	van Wagoner J. C., Mitchum R. M., Campion K. M., . Siliciclastic Sequence Stratigraphy in Well Logs, Core, and Outcrops: Concepts for High Resolution Correlation of Time and Facies, 1990, 43-62.

[29]	Wang B., Lin X., Bao Y., . SY/T 6210-1996 Quantitative Analysis of Total Contents of Clay Minerals and Common Non-Clay Minerals in Sedimentary Rocks by X-Ray Diffraction, 1996.

[30]	Wang J. F. Sedimentary Facies of the Shahejie Formation of Paleogene in Dongying Sag, Jiyang Depression. Journal of Paleogeography, 2005, 7(1): 45-58.

[31]	Wilkin R. T., Barnes H. L., Brantley S. L. The Size Distribution of Framboidal Pyrite in Modern Sediments: An Indicator of Redox Conditions. Geochimica et Cosmochimica Acta, 1996, 60(20): 3897-3912.

[32]	Wu J., Jiang Z. X., Pan Y. W., . Lacustrine Fine-Grained Depositional Model—A Case Study of the Upper Submember of the Fourth Member of Paleogene Shahejie Formation in Dongying Sag. Acta Petrolei Sinica, 2016, 37(9): 1080-1089.

[33]	Wu J., Jiang Z. X., Qian K., . Characteristics of Salinization Mechanism on the Upper Part of Fourth Member of Shahejie Formation in the Dongying Sag, Shandong Province. Acta Geoscientica Sinica, 2014, 35(6): 733-740.

[34]	Wu L., Zhang Z., Li B., . GB/T 18602-2001 Rock Pyrolysis Analysis, 2001.

[35]	Xu J. L., Pan Z. R., Yang Y. M., . Dinophyceae and Acritarchs on Early Tertiary in Shengli Oil Area, 1997.

[36]	Yan J. H., Chen S. Y., Jiang Z. X. Sedimentary Characteristics of Nearshore Subaqueous Fans in Steep Slope of Dongying Depression. Journal of the University of Petroleum, China, 2005, 29(1): 6-9.

[37]	Yan J. P., Sima L. Q., Li Y. Method of Wavelet Multiscale Analysis and Its Application in Division of Sedimentation Cycle of Lake Facies Mudstone, 2011

[38]	Yang Y. Q., Qiu L. W., Jiang Z. X., . A Depositional Pattern of Beach Bar in Continental Rift Lake Basins: A Case Study on the Upper Part of the Fourth Member of the Shahejie Formation in the Dongying Sag. Acta Petrolei Sinica, 2011, 32(3): 417-423.

[39]	Yuan W. F., Chen S. Y., Zeng C. M. Study on Marine Transgression of Paleogene Shahejie Formation in Jiyang Depression. Acta Petrolei Sinica, 2006, 27(4): 40-49.

[40]	Zhang M. M., Zhou J. J., Qin R. D. Tertiary Fish Fauna from Coastal Region of Bohai Sea. Memoirs of Institute of Vertebrate Paleontology and Paleoanthropology. Academia Sinica, 1985, 17: 55-60.

[41]	Zhang S. Q., Ren Y. G. The Study of Base Level Changes of the Songliao Basin in Mesozoic. Journal of Chang’an University (Earth Science Edition), 2003, 25(2): 1-7.