济阳坳陷古近系孔店组高频韵律旋回沉积记录及成因

doi:10.11743/ogg20150108

Abstract

Abstract:

There is a set of high frequency cycles with lithological combination of purple red mudstone, grey siltstone and gypsiferous mudstone developing in the Kongdian Formation of Jiyang Depression.By using logging data, well logging, core observation and elemental geochemistry methods, this paper researched the deposition mechanism of high frequency cycles of the Kongdian Formation in Jiyang Depression.The research results show that the cyclic sedimentation record of Kongdian Formation in Jiyang Depression consist of color meter scale cycle, graded meter scale cycle, non-graded meter scale cycle and consist of 6 types of lithofacies assemblages which include 23 kinds of lithology combinations.The cyclic sedimentation record can be divided into 276 cycles, with the maximum thickness being 29.6m, the minimum thickness being 1.48m, and average thickness being 6.28m.Fisher diagrams and the spectrum analysis of logging curves reveal that the precession cycle is 19.2-23.4 ka, slope cycle is 39.1-51.4 ka, and eccentricity cycles is 95.3-403.1 ka.They are consistent with the period of ultra short term cycles, short-term cycle and medium-term cycles, respectively.So it is confirmed that the cyclic sedimentation record was controlled by the Milankovich cycle.In addition, it was also influenced by paleo-climate, sedimentary medium conjugate concussion and material supply.Finally, the cyclic-sedimentation dynamic model during low/high-stand period of Kongdian Formation in Jiyang Depression is established, and the original sedimentary dynamics and ancient environment of the cyclic sedimentation record under the control of Milankovich cycle are discussed.

Key words: high frequency cycle, deposition mechanism, Kongdian Formation, Palaeogene, Jiyang Depression

CLC Number:

TE121.3

Tan Xianfeng, Jiang Yanxia, Li Jie, Xue Weiwei, Li Zemin. Sedimentary record and origin of high frequency cycles in the Paleogene Kongdian Formation in the Jiyang Depression[J]. Oil & Gas Geology, 2015, 36(1): 61-72.

References

[1] Schwarzacher W.Cyclostragraphy and the milankovitch theory,Amsterdam,Landon,New York[M].Tokyo:Elsevier,1993.
[2] Doyle P,Bennett M R.Unlocking the stratigraphical record:advances in modern stratigraphy[J].Chichester,1998,2(3):1-5.
[3] Gong Y M,Li B H,W ang C Y,et al.Orbital cyclostratigraphy of the Devonian Frasnian-Famenian transition in South China[J].Palaeogeograph,Palaeoclirnatology,Palaeoecology,2001,168(3-4):237-248.
[4] Buonocunto F P,D Argenio B,Ferreri V,et al.Orbital ennsyl ratigraphy and sequence stratigraphy of Upper Cretaceous platform carbona-tes at Monte Sant' Erasmo,southern Apennines,Italy[J].Cretaceous Research,1999,20 (1) :81-95.
[5] Anderson R Y A long geoclimatic record from the Permian[J].Journal of Geophysical Research,1982,87:7285-7294.
[7] 梅冥相,徐德斌,周洪瑞.米级旋回层序的成因类型及其相序组构特征[J].沉积学报,2000,18(1):43-49. Mei Mingxiang,Xu Debin,Zhou Hongrui.Genetic types of meter-scale cyclic sequences and their fabric features of facies-succession[J].Acta Sedimentologica Sinica,2000,18(1):43-49.
[8] 郭刚,童金南,张世红,等.安徽巢湖早三叠世印度期旋回地层研究[J].中国科学,2007,37(12):1571-1578 Guo Gang,Tong Jinnan,Zhang Shihong,et al.Cyclos-tratigraphy of the Induan (Early T riassic) in WestPingdingshan Section,Chaohu,Anhui Province[J].Sciencein China,2007,37(12):1571-1578.
[9] 伊海生.测井曲线旋回分析在碳酸盐岩层序地层研究中的应用[J].古地理学报,2011,13(4):456-466. Yi Haisheng.Application of well log cycle analysis in studies of sequence stratigraphy of carbonate rocks[J].Journal OF Palaeogeography,2011,13(4):456-466.
[10] John C,Tipper.Research articles patterns of stratigraphic cyclicity[J].Journal of Sedimentary Research,2000,70(6):1262-1279.
[11] Cari L,Johnson,Stephan A,et al.Cycles in Perilacustrine facies of Late Mesozoic rift basins,Southeastern Mongolia[J].Journal of Sedimentary Research,2004,74(6):786-804.
[12] 李凤杰,郑荣才,赵俊兴.鄂尔多斯盆地米兰科维奇旋回在延长组发育的一致性[J].西安石油大学学报,2008,23(5):1-5. Li Fengjie,Zheng Rongcai,Zhao Junxing.Uniformity of the Milankovitch cycle developed in the Yanchang Formation in east Gansu with the Milankovitch cycle developed in other areas in Ordos Basin[J].Journal of Xican Shiyou University,2008,23(5):1-5.
[13] 梁定勇,伊海生,邱余波,等.松辽盆地东岭地区泉头组高频沉积旋回的叠加型式分析[J].沉积学报,2014,32(2):198-203 Liang Dingyong,Yi Haisheng,Qiu Yubo,et al.Analysis of high-frequency sedimentary cycle superposition type in Quantou Formation in Dongling area of Songliao Basin[J].Acta Sedimentologica Sinica,2014,32(2):198-203.
[14] Neil F,Humphrey,Paul L,et al.Natural oscillations in coupled geomorphic systems:an alternative origin for cyclic sedimentation[J].Geology,1995,23(6):499-502
[15] 程日辉,王国栋,王璞珺.松辽盆地白垩系泉三段-嫩二段沉积旋回与米兰科维奇周期[J].地质学报,2008,82(1):55-63. Cheng Rihui,Wang Guodong,Wang Pujun.Sedimentary cycles of the Cretaceous Quantou-Nenjiang Formations and Milankovitch Cycles of the South hole of the Slcore-ñ in the Songliao Basin[J].Acta Geolo-gica Sinica,2008,82(1):55-63.
[16] Anderson E J,Goodwin P W.The significance of meter-scale allocycles in the quest for a fundamental stratigraphic unit[J].Journal of Geology,1990,147:507-518.
[17] 陈留勤.从准层序到米级旋回-层序地层学与旋回地层学相互交融的纽带[J].地层学杂志,2008,32(4):447-454. Chen Liuqin.From parasequences to meter-scale cycles:The connection between sequence stratigraphy and cyclostratigraphy[J].Journal of Stratigraphy,2008,32(4):447-454.
[18] 梅冥相.碳酸盐米级旋回层序的成因类型及识别标志[J].岩相古地理,1993,13(6):35-45. Mei minxiang.Genetic types and identification marks of Meter-scale cyclic sequences of carbonate[J].Lithofacies Palaeogeography,1993,33(6):34-45.
[19] 梅冥相.碳酸盐旋回与层序[M] .贵阳:贵州科技出版社,1995:1-245. Mei Minxiang.Carbonate cycles and sequence[M].Guiyang:Guizhou science and Technology Press,1995:1-245.
[20] 王鸿祯,史晓颖.沉积层序及海平面旋回的分类级别旋回周期的成因讨论[J].现代地质,1998,12(1):1-16. Wang Hongzhen,Shi Xiaoying.Hierarchy Of Depositional sequences and eustatic cyclfs-a discussion on the mechanism of sedimentary cycles[J].Geosciencl,1998,12(1):1-16.
[21] Mitchum R M,Van Wagoner J C.High-frequency sequences and their stacking patterns; sequence-stratigraphic evidence of high-frequency eustatic cycles (in the record of sea-level fluctuations)[J].Sedimentary Geology,1991,70:131-160.
[22] 郑荣才,彭军,吴朝容.陆相盆地基准面旋回的级次划分和研究意义[J].沉积学报,2001,19(2):249-254. Zheng Rongcai,Peng Jun,Wu Chaorong.Grade division of base-level cycles of terrigenous basin and its implications[J].Acta Sedimentologica Sinica,2001,19(2):249-254.
[23] Wilgus C K.Sea-level changes-An integratedapproach[M].Tulsa:SEPM Special Publication,1988:1-407.
[24] 杨俊才,马飞宙.单岩性米级旋回在旋回地层划分中识别-以北京西山张夏组为例[J].地层学杂志,2014,38(3):311-316. Yang Juncai,Ma Feizhou.Single-lithology meter-scale cycles in cyclic stratigraphy:a case study of theCambrian changhia formation in xishan[J].Journal of Stratigraphy,2014,38(3):311-316.
[25] 谭先锋.陆相断陷湖盆旋回沉积机理与成岩系统物质耦合关系研究-以济阳坳陷孔店组为例[D].四川成都:成都理工大学,2013. Tan Xianfeng.Study on cyclic sedimentation mechanism and diagenetic system material coupling relationship in continental rift lake basin-Take Jiyang rift lacustrine basin Kongdian formation for example[D].Chengdu:Chengdu Unirersity of Technolog,2013.
[26] 夏国清,伊海生,黄华谷,等.藏北雁石坪地区夏里组米级沉积旋回及成因[J].成都理工大学学报(自然科学版),2010,37(2):133-138. Xia Guoqing,Yi Haisheng,Hang Huagu,et al.Meter-scale sedimentary cycles and their possible genetic mechanism of Middle Jurassic Xiali Formation inYanshiping area,North Tibet,China[J].Journal of Chengdu University of Technology(Science & Technology Edition),2010,37(2):133-138.
[27] Milankovitch M M.Kanon der Erdbestrahlung und seine Anwendung aufdas Eizeitenproblem[J].Academic Serbe,1941,133:1121~1132.
[28] Berger A,Louter M F,Dehant V.Pre-Quaternary Milankovitch frequencies[J].Nature,1989,342(9):133.
[29] 付文钊,余继峰,杨锋杰,等.测井记录中米氏旋回信息提取及其沉积学意义-以济阳坳陷区为例[J].中国矿业大学学报,2013,42(6):1025-1032. Fu Wenzhao,YuJifeng,Yang Fengjie,et al.Feature extraction of Milankovitch cycle in well logs and its sedimentological significance:a case study of Jiyang depression zone[J].Journal of China University of Mining and Technology,2013,42(6):1025-1032.
[30] 徐伟.东营凹陷沙河街组三段、四段高频旋回识别及其地质意义[D].北京:中国地质大学,2011. Xu Wei.High frequency cycle identification and its geological significance of 3th and the 4th of Shahejie Fm in Dongying sag.[M].Beijing:China University of Geosciences,2011.

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Sedimentary record and origin of high frequency cycles in the Paleogene Kongdian Formation in the Jiyang Depression

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