Astronomical forcing of sedimentary cycles of Late Eocene Liushagang Formation in the Bailian Sag, Fushan Depression, Beibuwan Basin, South China Sea

Hai-yang Cao; Si-ding Jin; Ming Sun; Hua Wang

doi:10.1007/s11771-016-3195-9

Journal of Central South University ›› 2016, Vol. 23 ›› Issue (6) : 1427 -1438. DOI: 10.1007/s11771-016-3195-9

Geological, Civil, Energy and Traffic Engineering

Astronomical forcing of sedimentary cycles of Late Eocene Liushagang Formation in the Bailian Sag, Fushan Depression, Beibuwan Basin, South China Sea

Hai-yang Cao ¹^,²
, Si-ding Jin ¹^,²
, Ming Sun ³
, Hua Wang ¹^,^d

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Abstract

Sediments in the Liushagang Formation of Late Eocene form a group of key hydrocarbon play fairways in the Beibuwan Basin, South China Sea. As an important reservoir-forming combination, the Liushagang Formation consists of deltaic siliciclastic and show clear sedimentary cyclicity. According to paleontology research and stratigraphic correlation, the boundary between Liushagang Formation (Els) and Weizhou Formation (Ewz) is regarded as the Eocene-Oligocene boundary. The oxygen isotope dating for well cores from the top of the first Member of Liushagang Formation (Els1) and the bottom of the third Member of Weizhou Formation (Ewz3) give an isochron age of 35.2 Ma. Here, we use GR logging data as a paleoenvironmental proxy to conduct a detailed cyclostratigraphic study of the Els1 in the Bailian Sag, Fushan Depression. Power spectra, evolutionary fast Fourier transformation and wavelet analysis all reveal significant sedimentary cycles in Els1. The ratios of cycle wavelengths in these stratigraphic units are 21:5:2.8:1.2:1, and are interpreted as Milankovitch cycles of 400 ka and 96 ka eccentricity, 52 ka obliquity, 22 ka and 19 ka precession cycles, respectively. An astronomical time scale is established by tuning filtered 96 ka eccentricity cycles to a target curve of Well L2 in the Bailian Sag. Based on regional stratigraphic framework, combined with seismic, cores and logging data, the HST of the first member of the Liushagang Formation (Els1) delta in Well L2 was divided into six parasequence sets named Ps1-Ps6. According to the spectrum analysis by Simple Lomb periodogram from PAST program packages, the sediment accumulation rate of each parasequence sets first increased and then decreased as time went by. The sediment accumulation rate of Ps4 reached the maximum (0.127 m/ka) during the most prosperous period of delta prograding. Finally, the duration of each period of parasequence sets and more accurate geological age were calculated on the basis of sediment accumulation rate. The ages of each depth are precisely estimated and provide new constraints on the Late Eocene.

Keywords

Fushan Depression / Liushagang Formation / Milankovitch cycles / astronomical tuning

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Hai-yang Cao, Si-ding Jin, Ming Sun, Hua Wang. Astronomical forcing of sedimentary cycles of Late Eocene Liushagang Formation in the Bailian Sag, Fushan Depression, Beibuwan Basin, South China Sea. Journal of Central South University, 2016, 23(6): 1427-1438 DOI:10.1007/s11771-016-3195-9

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	ZhuW-l, HuangB-j, MiL-j, WilkinsR W T, FuN, XiaoX-ming. Geochemistry, origin, and deep-water exploration potential of natural gases in the Pearl River Mouth and Qiongdongnan basins, South China Sea [J]. AAPG Bulletin, 2009, 93(6): 741-761

[2]	JinS-d, WangH, CaoH-y, ChenS, LinZ-l, YuJ-h, PanS-qi. Sedimentation of the Paleogene Liushagang Formation and the response to regional tectonics in the Fushan Sag, Beibuwan Basin, South China Sea [J]. Austrian Journal of Earth Sciences, 2014, 107(2): 112-130

[3]	LiuE-t, WangH, LiY, ZhouW, LeonardN D, LinZ-liang. Sedimentary characteristic and tectonic setting of sublacustrine fans in a half-graben rift depression, Beibuwan Basin, South China Sea [J]. Marine and Petroleum Geology, 2014, 52: 9-21

[4]	LIN Zheng-liang. Research on the tectonic characteristics of Paleogene in Fushan Sag, Beibuwan Basin [D]. Wuhan: China University of Geosciences, 2011. (in Chinese)

[5]	XuW, XieX-nong. A new method to calculate sedimentary rates based on Milankovitch Cycles [J]. Petroleum geology & Experiment, 2012, 34(2): 207-214

[6]	YaoY-m, XuX-h, LiuC, TanC-p, LuoJ-q, ZhuJ-xiu. Calculation of denudation amount with Milankovitch cycle method: A case study in Biyang Sag [J]. Petroluem Geology & Experiment, 2011, 33(5): 460-467

[7]	YaoY-m, XuD-y, ZhangH-f, HanY-b, ZhangS-p, YinZ-q, HeQ-f, BianX-mei. The Pliocene-Holocene astrostratigraphic study of Well Dongxin 2-4 in the Dongying Depression [J]. Journal of Stratigraphy, 2007, 31(2): 458-469

[8]	TianJ, AngP-x, ChengX-r, LiQ-yu. Establishment of the Plio-Pleistocene astronomical timescale of ODP Site 1143, Southern South China Sea [J]. Earth Science-Journal of China University of Geosciences, 2005, 30(1): 31-39

[9]	BergerA, LoutreM F, LaskarJ. Stability of the astronomical frequencies over the earth’s history for paleoclimate studies [J]. Science New Series, 1992, 255(5044): 560-566

[10]	AbelsH A, AzizH A, KrijgsmanW, SmeetsS J B, HilgenF J. Long-period eccentricity control on sedimentary sequences in the continental Madrid Basin (middle Miocene, Spain) [J]. Earth and Planetary, Science Letters, 2010, 289(1/2): 220-231

[11]	HilgenF J. Extension of the astronomically calibrated (polarity) time scale to the MiocenePliocene boundary [J]. Earth and Planetary Science Letters, 1991, 107(2): 349-368

[12]	LaskarJ. The chaotic motion of the solar system: A numerical of the size of the chaotic zones [J]. Icarus, 1990, 88(2): 266-291

[13]	RioD, SilvaL P, CaprarpL. The geological time scale and the Italian stratigraphic record [J]. Episodes, 2003, 26(3): 259-263

[14]	GradsteinF M, OggJ G, SmithA GA geologic time scale 2004 [M], 2004CambridgeCambridge University Press440

[15]	LaurinJ, SagemanB. Cenomanian-Turonian coastal record in SW Utah, U.S.A: Orbital-scale transgressiveregressive events during Oceanic Anoxic Event II [J]. Journal of Sedimentary Research, 2007, 77(9): 731-756

[16]	LaskarJ, RobuletP, JoutelF, GastineauM, CorreiaA C M, LevrardB. A long-term numerical solution for the insolation quantities of the earth [J]. Astronomy and Astrophysics, 2004, 428(1): 261-285

[17]	KangX-d, ZhaoW-c, PanZ-g, ZhangQ-m, ChenZ-yong. Study on architecture of sequence stratigraphic framework of Beibuwan Basin [J]. Journal of Earth Science, 1994, 19(4): 493-502

[18]	DuZ-chuan. Structural features and the controlling function of sedimentary from Tertiary in Beibuwan Basin, the South China Sea [J]. Journal of Hebei Mining and Civil Engineering Institute, 1997, 1(1): 55-59

[19]	ZhuW-l, WuG, LiM-bi. Palaeolimology and hydrocarbon potential in Beibu Gulf Basin if South China Sea [J]. Oceanologia et Limnologia Sinica, 2004, 35(1): 8-14

[20]	ShiY-m, LiuJ, ZhangM-z, ChenD-x, MaQ-lin. Experience and understand in oil and gas exploration in Fushan Sag, Hainan Province [J]. South China Journal of Seismology, 2007, 27(3): 57-68

[21]	LiuE-t, WangH, LinZ-l, LiY, MaQ-lin. Characteristics and hydrocarbon enrichment rules of transfer zone in Fushan Sag, Beibuwan Basin [J]. Journal of Central South University: Science and Technology, 2012, 43(10): 3947-3965

[22]	LiuE-t, WangH, LiaoY-t, MaQ-l, LinZ-liang. Constraints by transfer zone on sequences and depositional system in Fushan Sag, Beibuwan Basin [J]. Journal of China University of Petroleum: Edition of Natural Science, 2013, 37(4): 17-22

[23]	HeY-b, GaoZ-zhong. Sedimentary facies of the Liushagang Fomation of Paleogene in Fushan Sag of Hainan Island [J]. Palaeogeography, 2006, 8(3): 365-376

[24]	ShiX-b, KohnB, SpencerS, GuoX-w, LiY-m, YangX-q, ShiH-c, GleadowA. Cenozoic denudation history of souther Hainan Island, South China Sea: Constaints from low temperature thermochronology [J]. Tectonophysics, 2011, 504(1/2/3/4): 100-115

[25]	HaqB U, HardenbolJ, VailP R. Mesozoic and Cenozoic chronostratigraphy and eustatic cycles [J]. Society of Economic Paleontologist and Special Publication U. S. A., 1988, 42: 71-108

[26]	XieJ-y, LiJ, MaiW, ZhangH-l, CaiK-l, LiuX-yu. Palynofloras and age of the Liushagnag and Weizhou Formation in the Beibuwan Basin, South China Sea [J]. Acta Palaeontologica Sinica, 2012, 51(3): 385-394

[27]	LuoW, XieJ-y, LiuX-y, HuW-y, ZhangJ-x, ZhouWei. The study of paleogene climate in the Haizhong Depression, Beibuwan Basin, Northern South China Sea [J]. Acta Micropalaeontologica Sinica, 2013, 30(3): 288-296

[28]	HinnovL A. New perspectives on orbitally forced stratigraphy [J]. Annual Review of Earth and Planetary Sciences, 2000, 28(1): 419-475

[29]	ProkophA, VilleneuveM, AgterbergF P. Geochronology and calibration of global Milankovitch cyclicity at the Cenomanian-Turonian boundary [J]. Geology, 2001, 29(6): 523-526

[30]	HinnovLGradsteinF M, OggJ G, SmithA G. Earth’s orbital parameters and cycle stratigraphy. A Geologic Time Scale 2004, 2004CambridgeCambridge University Press55-62

[31]	SchulzM, MudelseeM. REDFIT: estimatingred-noise spectra directly from unevenly spaced Paleoclimatic time series [J]. Computers & Geoseiences, 2002, 28(3): 421-426

[32]	TorrenceC, CompoP G. A practical guide to wavelet analysis [J]. Bulletin of the American Meteorological Society, 1998, 79(1): 61-78

[33]	PressW H, TeukolskyS A, VetterlingW T, FlanneryB PNumerical Recipes in C [M], 1992CambridgeCambridge Univ Press

[34]	LaskarJ, FiengaA, GatineauM, MancheH. La2010: A new orbital solution for the long-term motion of the Earth [J]. Astronomy and Astrophysics, 2011, 532: A89

[35]	WeedonG PTime-series analysis and cyclostratigraphy [M], 2003CambridgeCambridge University Press

[36]	HilgenF J, KrijgamanW, LangereisC G, LourensL J. Breakthrough made in dating of the geological records [J]. EOS, 1997, 78(28): 288-289

[37]	SheriffR E. Limitations on resolution of seismic reflections and geological detail derivable from them [J]. PAYTON C E. Seismic Stratigraphy-Applications to Hydrocarbon Exploration AAPG (Tulsa), Memoir, 1977, 26: 3-14

[38]	MitchumR M J, VanW J C. High-frequency sequences and their stacking patterns: Sequence-stratigraphic evidence of high frequency eustatic cycles [J]. Sedimentary Geology, 1991, 70(2/3/4): 131-160

[39]	VailP R, MitchumR M, SangreeJ B. Concepts of depositional sequences. Sequence Stratigraphic Models for Exploration and Production: Evolving Methodology, Emerging Models, and Application Histories: 22nd Annual, 2002Houston, USAGCSSEPM19-32