Sedimentary characteristics and model of gravity flow depositional system for the first member of upper Miocene Huangliu Formation in Dongfang area, Yinggehai basin, northwestern South China Sea

Ming Sun; Hua Wang; Jihua Liao; Huajun Gan; Jun Xiao; Jinfeng Ren; Shu’e Zhao

doi:10.1007/s12583-014-0451-5

Journal of Earth Science ›› 2014, Vol. 25 ›› Issue (3) : 506 -518. DOI: 10.1007/s12583-014-0451-5

Article

Sedimentary characteristics and model of gravity flow depositional system for the first member of upper Miocene Huangliu Formation in Dongfang area, Yinggehai basin, northwestern South China Sea

Ming Sun ¹^,²
, Hua Wang ¹^,³^,^b
, Jihua Liao ⁴
, Huajun Gan ¹^,³
, Jun Xiao ¹^,³
, Jinfeng Ren ¹^,³
, Shu’e Zhao ¹^,³

Author information +

History +

PDF

Abstract

The gravity flow deposit were mainly developed in the lowstand systems tract (LST) of the first member of Upper Miocene Huangliu Formation (Ehl ¹) in Dongfang area, Yinggehai Basin, has become a valuable target for gas exploration and production. The gravity flow sedimentary characteristics of lithofacies associations, sedimentary texture, seismic facies and logging facies were described in detail on the basis of integrated analysis of cores, logging and seismic data. The sedimentary microfacies types composed of neritic sandbar, continental shelf mud, main channel, bifurcated or cross-cutting distributary channel, overspill, and natural levee are revealed under the constraint of high resolution sequence stratigraphic framework in the Ehl ¹. The gravity flow deposit system in the LST is divided into three evolution stages corresponding to periods of three parasequence sets. The gravity flow deposit was induced in the early LST, expanded rapidly in the middle LST and decreased slightly in the late LST. But its developing scale decreased sharply in the transgression systems tract (TST) and finally vanished in the highstand systems tract (HST). This spatial evolution rule is constrained by the integrated function of sediments supply of the Vietnam Blue River in the LST, the development of local gradient change in sea floor (micro-topography, i.e., flexure slope break), and the fall in relative sea level. On the basics of the deep study of the coupling relationship among the three main control factors, the sedimentary model is established as an optimal component of “source-channel-sink” for shallow marine turbidite submarine fan.

Keywords

Yinggehai Basin / Dongfang area / the first member of Upper Miocene Huangliu Formation (Ehl ¹) / sedimentation characteristics / gravity flow / sedimentary model

Cite this article

Download citation ▾

Ming Sun, Hua Wang, Jihua Liao, Huajun Gan, Jun Xiao, Jinfeng Ren, Shu’e Zhao. Sedimentary characteristics and model of gravity flow depositional system for the first member of upper Miocene Huangliu Formation in Dongfang area, Yinggehai basin, northwestern South China Sea. Journal of Earth Science, 2014, 25(3): 506-518 DOI:10.1007/s12583-014-0451-5

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]	Deng H W, Wang H L, Wang J F, . Self-Similarity of Constitution of Sequence Stratigraphy and Distribution of Sandbodies and Lithologic Reservoirs: Taking Delta-Turbidite Fan System as an Example. Oil & Gas Geology, 2004, 25(5): 16-20.

[2]	Hao F, Li S T, Gong Z S. The Machanics of the Diaper and the Fluid Episodic Infilling of Yinggehai Basin. Science in China Series D: Earth Science, 2001, 31(6): 471-476.

[3]	He J X, Xia B, Zhang S L, . Origin and Distribution of Mud Diapirs in the Yinggehai Basin and Their Relation to the Migration and Accumulation of Natural Gas. Geology in China, 2006, 33(6): 1336-1344.

[4]	He L J, Xiong L P, Wang J Y. Simulation Studies on the Tectonic Thermal Evolution in Yinggehai Basin. Science in China Series D: Earth Science, 2000, 30(4): 415-419.

[5]	He W J, Xie J Y, Liu X Y, . Foraminiferal Biostratigraphy and Sedimentary Environment Reconstruction Based on Paleontological Data from Bore Hole DF1-1-11, Yinggehai Basin. Journal of Stratigraphy, 2011, 25(1): 81-87.

[6]	Jin B, Liu Z, Li X S. The Dominant Principle on Natural Gas Accumulation of Mud-Fluid Diapers and Significance an Exploration in Yinggehai Basin. Journal of Jilin University (Earth Science Edition), 2009, 39(2): 196-204.

[7]	Khain V E, Polyakova I D. Oil and Gas Potential of Deep- and Ultradeep-Water Zones of Continental Margins. Lithology and Mineral Resources, 2004, 39(6): 530-540.

[8]	Li X B, Chen Q L, Liu H Q, . Three Types of Sediment Gravity Flows and Their Petrolferous Features of Yanchang Formation in Ordos Basin. Lithologic Reservoirs, 2010, 22(3): 16-21.

[9]	Li X B, Fu J H, Chen Q L, . The Concept of Sandy Debris Flow and Its Application in the Yanchang Formation Deep Water Sedimentation of the Ordos Basin. Advances in Earth Science, 2011, 26(3): 286-294.

[10]	Li X B, Liu H Q, Chen Q L. The Characteristics of the Sandy Debris Flow of the Triassic Yanchang Formation and Its Exploration Significance in the Ordos Basin, China. Acta Geologica Sinica (English Edition), 2011, 85(5): 1187-1202.

[11]	Lowe D R. Sediment Gravity Flows: Their Classification and Some Problems of Application to Natural Flows and Deposits. Geology of Continental Slopes, 1979, 27: 75-82.

[12]	Lowe D R. Sediment Gravity Flows II: Depositional Models with Special Reference to the Deposits of High Density Turbidity Currents. Journal of Sedimentary Petrology, 1982, 52(1): 279-297.

[13]	Middleton G V, Hampton M A. Middleton G V, Bouma A H. Sediment Gravity Flows: Mechanics of Flow and Deposition. Turbidites and Deepwater Sedimentation, 1973 Los Angeles: Society of Economic Paleontologists and Mineralogists, 1-38.

[14]	Middleton G V, Hampton M A. Stanley D J, Swift D J P. Subaqueous Sediment Transport and Deposition by Sediment Gravity Flows. Marine Sediment Transport and Environmental Management, 1976 New York: John Wiley, 197-218.

[15]	Okay S, Jupinet B, Lericolais G, . Morphological and Stratigraphic Investigation of a Holocene Subaqueous Shelf Fan, North of the Istanbul Strait in the Black Sea. Turkish Journal of Earth Sciences, 2011, 20: 287-305.

[16]	Paul M M, Richard N H. Shallow-Water Gravity-Flow Deposits, Chapel Island Formation, Southeast New-Foundland, Canada. Sedimentology, 1991, 38: 935-959.

[17]	Pei J X, Yu Z F, Wang L F, . Key Challenges and Strategies for the Success of Natural Gas Exploration in Mid-Deep Strata of the Yinggehai Basin. Acta Petrolei Sinica, 2011, 32(4): 573-579.

[18]	Pigott J D, Ru K. Basin Superposition on the Northern Margin of the South China Sea. Tectonophysics, 1994, 235: 27-50.

[19]	Qiao B, Zhang C M, Du J Y, . Contrast of Gravity Flows between Shallow Water and Deep Water in Pearl River Mouth Basin. Lithologic Reservoirs, 2011, 23(2): 59-63.

[20]	Reading H G, Richards M T. Turbidite Systems in Deep Water Basin Margins Classified by Grain-Size and Feeder System. AAPG Bulletin, 1994, 78: 792-822.

[21]	Richards M T, Bowman M B J, Reading H G. Submarine Fan Systems I: Characterisation and Stratrigraphic Prediction. Marine and Petroleum Geology, 1998, 15: 689-717.

[22]	Richards M T, Bowman M B J. Submarine Fan Systems II: Variability in Reservoir Architecture. Marine and Petroleum Geology, 1998, 15: 821-839.

[23]	Ru K, Pigott J D. Episodic Rifting and Subsidence in the South China Sea. AAPG Bulletin, 1986, 70: 1136-1156.

[24]	Shanmugam G. High-Density Turbidity Currents: Are They Sandy Debris Flows?. Journal of Sedimentary Research, 1996, 66: 2-10.

[25]	Shanmugam G. 50 Years of the Turbidite Paradigm (1950s–1990s): Deep-Water Processes and Facies Models-A Critical Perspective. Marine and Petroleum Geology, 2000, 17: 285-342.

[26]	Shanmugam G. Ten Turbidite Myths. Earth Science Reviews, 2002, 58: 311-341.

[27]	Shultz A W. Subaerial Debris-Flow Deposition in the Upper Paleozoic Cutler Formation, Western Colorado. Journal of Sedimentary Research, 1984, 54: 759-772.

[28]	Su M, Xie X N, Li J L, . Gravity Flow on Slope and Abyssal Systems in the Qiongdongnan Basin, Northern South China Sea. Acta Geologica Sinica (English Edition), 2011, 85(1): 243-253.

[29]	Wan Z F, Xia B, Xu L F, . Study on the Dynamic Mechanism of Tectonic Evolution in Yinggehi Basin. Marine Science Bulletin, 2010, 29(6): 654-657.

[30]	Wang H, Zhu W L, Wang Y. Characteristics of Medium-Deep Reservoir and Sedimentary History in Yinggehai Basin. Oil & Gas Geology, 1999, 20(1): 55-57.

[31]	Wang X L, Zhou J Y, Ma L, . Gravity Flow Sedimentary Characteristics and the Significance of Petroleum Exploration in the Chaluhe Fault Depression, the Yitong Basin. Petroleum Geology & Experiment, 2008, 30(1): 26-31.

[32]	Wang Y, Wang X Z, Wang Y M, . Determina tion of the Gravity Flow Critical Gradient Using Sedimentary Simulation Experiment. Journal of Chengdu University of Technology (Science & Technology Edition), 2010, 37(4): 463-468.

[33]	Wang Y M, Xu Q, Li D, . Late Miocene Red River Submarine Fan, Northwestern South China Sea. Chinese Science Bulletin, 2011, 56(1): 781-787.

[34]	Wang Z F, Pei J X. A New Accumulation Model of High Pressure Gas in Huangliu Formation of the Middle-Deep Interval in Yinggehai Basin: the Significance of Discovering a Good-Quality Gas Pay with Overpressure and High Production in Well DF14. China Offshore Oil and Gas, 2011, 23(4): 213-217.

[35]	Weimer P, Roger M S, Henry S P. Weimer P, Roger M S. Global Overview of Deepwater Exploration and Production. Petroleum Systems of Deepwater Settings, 2004, 21-39.

[36]	Xie X N, Li S T, Hu X Y. Genetic Mechanisms of the Diaper and the Fluid Guide Economy in Yinggehai Basin. Science in China Series D: Earth Science, 1999, 29(3): 247-256.

[37]	Xie Y H, Fan C W. Some New Knowledge about the Origin of Huangliu Formation Reservoirs in Dongfang Area, Yinggehai Basin. China Offshore Oil and Gas, 2010, 22(6): 354-359.

[38]	Xie Y H, Zhang Y Z, Li X S, . Main Controlling Factors and Formation Models of Natural Gas Reservoirs with High-Temperature and Overpressure in Yinggehai Basin. Acta Petrolei Sinica, 2012, 33(4): 601-609.

[39]	Zhang M Q, Zhong Z H, Xia B. Genetic Mechanisms of Mud-Fluid Diaper in Yinggehai Basin and Hydrocarbon Accumulation. Geotectonica et Metallogenia, 2004, 28(2): 118-125.

[40]	Zhu W L, Zhang G C, Yang S K, . Natural Gas Geology of Continental Margin Basins in the Northern South China Sea, 2007 Beijing: Petroleum Industry Press, 1-391.

[41]	Zhu W L, Zhang G C, Gao L. Geological Characteristics and Exploration Objectives of Hydrocarbons in Northern Continental Margin Basin of South China Sea. Acta Petrolei Sinica, 2008, 29(1): 1-9.

[42]	Zhu Y H. Composition and Reservoir Body Distribution of Continental Shelf-Continental Slope Sedimentary System in Earlf Eocene in Pearl Rixer Mouth Basin. Journal of Xi’an Shiyou University (Natural Science Edition), 2011, 26(6): 1-8.

[43]	Zhu Y H, Zhu W L, Xu Q, . Sedimentary Response to Shelf-Edge Eeila and Slope Deep-Water Fan in 13.8 Ma of Miocene Epoch in Pearl River Mouth Basin. Journal of Central South University (Science and Technology), 2011, 42(12): 3827-3834.

[44]	Zou C N, Zhao Z Z, Yang H, . Genetic Mechanism and Distribution of Sandy Debris Flows in Terrestrial Lacustrine Basin. Acta Sedimentologica Sinica, 2009, 27(6): 1065-1075.