基于米氏旋回理论的高频层序识别与划分——以南八仙油气田下油砂山组为例

热依扎⋅沙依热阿特汗; 姚宗全; 李积永; 张源智; 郑彬; 张士超; 刘少鹏; 马元琨; 热依扎⋅沙依热阿特汗; 姚宗全; 李积永; 张源智; 郑彬; 张士超; 刘少鹏; 马元琨

doi:10.14027/j.issn.1000-0550.2024.020

[1]

常吟善，覃军，赵洪，等. 2019. 基于米氏旋回理论的高频层序识别与划分：以东海陆架盆地平湖斜坡带宝云亭地区平三段为例[J]. 海洋地质与第四纪地质，39（3）：51-60.

Chang Yinshan, Qin Jun, Zhao Hong, et al. 2019. Identification and division of high-frequency sequence based on Milakovitch cycle: A case of the 3rd member of Pinghu Formation in Baoyunting area, Pinghu slope zone, East China Sea Shelf Basin[J]. Marine Geology & Quaternary Geology, 39(3): 51-60.

[2]

陈秋实. 2014. 柴达木盆地西部地区构造演化及圈闭特征研究[D]. 成都：西南石油大学.

Chen Qiushi. 2014. Research on the tectonic evolution and trap characteristics of the western region of the Qaidam Basin[D]. Chengdu: Southwest Petroleum University.

[3]

陈文萍，胡望水，李涛，等. 2020. 柴达木盆地新生代走滑构造特征及成因演化[J]. 科学技术与工程， 20（2）：497-504.

Chen Wenping, Hu Wangshui, Li Tao, et al. 2020. The characteristics and genetic evolution of the Cenozoic strike-slip structure in Qaidam Basin[J]. Science Technology and Engineering, 20(2): 497-504.

[4]

陈云，唐闻强，张承志，等. 2021. 基于自然伽马测井曲线的旋回识别及古气候判断[J]. 测井技术，45（4）：416-423.

Chen Yun, Tang Wenqiang, Zhang Chengzhi, et al. 2021. Study on paleoclimate and dentification of high frequency cycle based on natural gamma ray logging data[J]. Well Logging Technology, 45(4): 416-423.

[5]

陈兆芹，刘景彦，杨宪章，等. 2023. 塔里木盆地英买力地区三叠系相对湖平面变化分析[J]. 西北地质，56（1）：203-216.

Chen Zhaoqin, Liu Jingyan, Yang Xianzhang, et al. 2023. Discussion on relative lacustrine level changes of Triassic in Yingmaili area, Tarim Basin[J]. Northwestern Geology, 56(1): 203-216.

[6]

程日辉，王国栋，王璞珺. 2008. 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，82（1）：55-64.

Cheng Rihui, Wang Guodong, Wang Pujun. 2008. Sedimentary cycles of the Cretaceous Quantou—Nenjiang Formations and Milankovitch cycles of the south hole of the SLCORE-I in the Songliao Basin[J]. Acta Geologica Sinica, 82(1): 55-64.

[7]

冯路尧，张建国，姜在兴，等. 2023. 松辽盆地青山口组高精度沉积旋回格架及有机质富集响应[J]. 石油学报，44（2）：299-311.

Feng Luyao, Zhang Jianguo, Jiang Zaixing, et al. 2023. High-precision sedimentary cycle framework and organic matter enrichment response of Qingshankou Formation in Songliao Basin[J]. Acta Petrolei Sinica, 44(2): 299-311.

[8]

付锁堂，张道伟，薛建勤，等. 2013. 柴达木盆地致密油形成的地质条件及勘探潜力分析[J]. 沉积学报，31（4）：672-682.

Fu Suotang, Zhang Daowei, Xue Jianqin, et al. 2013. Exploration potential and geological conditions of tight oil in the Qaidam Basin[J]. Acta Sedimentologica Sinica, 31(4): 672-682.

[9]

付文钊，余继峰，杨锋杰，等. 2013. 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，42（6）：1025-1032.

Fu Wenzhao, Yu Jifeng, Yang Fengjie, et al. 2013. 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 & Technology, 42(6): 1025-1032.

[10]

黄璞，熊亮，詹国卫，等. 2025.基于米兰科维奇理论页岩岩相组合研究：以四川盆地南部龙马溪组一段为例[J]. 沉积学报，43（4）：1461-1474.

Huang Pu, Xiong Liang, Zhan Guowei, et al. 2025.Research on shale facies combination based on Milankovitch theory: Taking the First member of Longmaxi Formation in the southern Sichuan Basin as an example[J]. Acta Sedimentologica Sinica, 43(4): 1461-1474.

[11]

贾东力，田景春，林小兵，等. 2018. 塔里木盆地顺托果勒地区志留系柯坪塔格组米兰科维奇旋回沉积记录[J]. 石油与天然气地质，39（4）：749-758.

Jia Dongli, Tian Jingchun, Lin Xiaobing, et al. 2018. Milankovitch cycles in the Silurian Kepingtage Formation in Shuntuoguole area, Tarim Basin[J]. Oil & Gas Geology, 39(4): 749-758.

[12]

姜玥晗. 2019. 滇黔北地区五峰组—龙马溪组下段米兰科维奇旋回研究[D]. 成都：西南石油大学.

Jiang Yuehan. 2019. Research on the Milankovitch cycles in the lower section of the Wufeng Formation-Longmaxi Formation in the northern Yunnan-Guizhou region[D]. Chengdu: Southwest Petroleum University.

[13]

金之钧，李京昌，刘国臣. 1997. 米兰科维奇旋回识别问题[J]. 地学前缘，4（3/4）：22.

Jin Zhijun, Li Jingchang, Liu Guochen. 1997. Issues in identifying Milankovitch cycles[J]. Earth Science Frontiers, 4(3/4): 22.

[14]

柯学，季军良，宋博文，等. 2013. 柴达木盆地大红沟新生代地层剖面磁化率及其环境意义[J]. 地质学报，87（增刊1）：251-254.

Ke Xue, Ji Junliang, Song Bowen, et al. 2013. Magnetic susceptibility of the Cenozoic strata profile in the Dahonggou area of the Qaidam Basin and its environmental significance[J]. Acta Geologica Sinica, 87(Suppl.1): 251-254.

[15]

闾伟，董艳蕾，葛家旺，等. 2023. 基于频谱属性趋势分析和小波变换的层序界面识别方法——以珠三坳陷中新统珠江组—韩江组为例[J]. 断块油气田，30（3）：448-457.

Wei Lü, Dong Yanlei, Ge Jiawang, et al. 2023. Identification method of sequence boundary based on INPEFA and wavelet transform: A case study of Miocene Zhujiang to Hanjiang Formation in Zhu-3 Depression[J]. Fault-Block Oil & Gas Field, 30(3): 448-457.

[16]

马达德，袁莉，陈琰，等. 2018. 柴达木盆地北缘天然气地质条件、资源潜力及勘探方向[J]. 天然气地球科学，29（10）：1486-1496.

Ma Dade, Yuan Li, Chen Yan, et al. 2018. Geological conditions of natural gas, resource potential and exploration direction in the northern margin of Qaidam Basin[J]. Natural Gas Geoscience, 29(10): 1486-1496.

[17]

潘家伟，李海兵，孙知明，等. 2015. 阿尔金断裂带新生代活动在柴达木盆地中的响应[J]. 岩石学报，31（12）：3701-3712.

Pan Jiawei, Li Haibing, Sun Zhiming, et al. 2015. Tectonic responses in the Qaidam Basin induced by Cenozoic activities of the Altyn Tagh fault[J]. Acta Petrologica Sinica, 31(12): 3701-3712.

[18]

彭军，于乐丹，许天宇，等. 2022. 湖相泥页岩地层米氏旋回测井识别及环境响应特征：以渤海湾盆地济阳坳陷东营凹陷樊页1井Es ^4scs为例[J]. 石油与天然气地质，43（4）：957-969.

Peng Jun, Yu Ledan, Xu Tianyu, et al. 2022. Logging identification of Milankovitch cycle and environmental response characteristics of lacustrine shale: A case study on Es ^4scs in well Fanye 1, Dongying Sag, Jiyang Depression, Bohai Bay Basin[J]. Oil & Gas Geology, 43(4): 957-969.

[19]

任传真，褚润健，吴怀春，等. 2019. 天津蓟县剖面前寒武系洪水庄组—铁岭组米兰科维奇旋回[J]. 现代地质，33（5）：979-989.

Ren Chuanzhen, Chu Runjian, Wu Huaichun, et al. 2019. Milankovitch cycles of the Precambrian Hongshuizhuang-Tieling Formations at Jixian section in Tianjin[J]. Geoscience, 33(5): 979-989.

[20]

任宪军. 2008. 柴达木盆地北缘中新生代含油气性研究[D]. 大庆：大庆石油学院.

Ren Xianjun. 2008. The study on the petroleum properties in northern margin of Qaidam Basin[D]. Daqing: Da-qing Petroleum Institute.

[21]

石巨业，金之钧，刘全有，等. 2017. 米兰科维奇理论的高精度旋回识别与划分：以南图尔盖盆地Ary301井中侏罗统为例[J]. 沉积学报，35（3）：436-448.

Shi Juye, Jin Zhijun, Liu Quanyou, et al. 2017. Recognition and division of high-resolution sequences based on the Milankovitch theory: A case study from the Middle Jurassic of well Ary301 in the South Turgay Basin[J]. Acta Sedimentologica Sinica, 35(3): 436-448.

[22]

宋翠玉，吕大炜. 2022. 米兰科维奇旋回时间序列分析法研究进展[J]. 沉积学报，40（2）：380-395.

Song Cuiyu, Dawei Lü. 2022. Advances in time series analysis methods for Milankovitch cycles[J]. Acta Sedimentologica Sinica, 40(2): 380-395.

[23]

宋明水，李存磊，张金亮. 2012. 东营凹陷盐家地区砂砾岩体沉积期次精细划分与对比[J]. 石油学报，33（5）：781-789.

Song Mingshui, Li Cunlei, Zhang Jinliang. 2012. Fine division and correlation of conglomerate sedimentary cycles in Yanjia area of Dongying Depression[J]. Acta Petrolei Sinica, 33(5): 781-789.

[24]

宋世骏. 2022. 柴达木盆地新生代咸化湖盆细粒岩差异性发育机理及其地质意义[D]. 西安：西北大学.

Song Shijun. 2022. Different developing mechanism of fine-grained sediments in Cenozoic saline lakes in the Qaidam Basin and its geological implications[D]. Xi'an: Northwest University.

[25]

汤济广. 2007. 柴达木北缘西段中、新生代多旋回叠加改造型盆地构造演化及对油气成藏的控制作用[D]. 武汉：中国地质大学.

Tang Jiguang. 2007. Tectonic evolution and its control for hydrocarbon accumulation of Mesozoic-Cenozoic multicycle superi-mposed reformation basin in the west of northern Qaidam Basin[D]. Wuhan: China University of Geosciences.

[26]

唐闻强，伊海生，陈云，等. 2021. 基于测井曲线频谱分析米氏旋回特征：以柴西尕斯地区上干柴沟组为例[J]. 科学技术与工程，21（11）：4360-4368.

Tang Wenqiang, Yi Haisheng, Chen Yun, et al. 2021. Characteristics of Mirankovich cycles based on the spectrum analysis of logging curve: A case study of Shangganchaigou Formation in gas area, western Qaidam Basin[J]. Science Technology and Engineering, 21(11): 4360-4368.

[27]

王浡，石巨业，朱如凯，等. 2025.天文周期驱动下湖相细粒沉积岩有机质富集模式——以东营凹陷LY1井沙三下—沙四上亚段为例[J]. 沉积学报，43（2）：750-768.

Wang Bo, Shi Juye, Zhu Rukai, et al. 2025.Organic matter enrichment model of lacustrine fine-grained sedimentary rocks driven by astronomical cycles: A case study of the lower Es₃ and upper Es₄ sub-member in well LY1, Dongying Sag[J]. Acta Sedimentologica Sinica, 2025, 43(2): 750-768.

[28]

王宏波. 2011. 柴达木盆地北缘冲断带第三系沉积特征与岩性油气藏预测[D]. 成都：成都理工大学.

Wang Hongbo. 2011. Tertiary sedimentary characteristic and lithologic reservoir prediction in thrust belt, north Qaidam Basin[D]. Chengdu: Chengdu University of Technology.

[29]

王倩倩，袁四化，王亚东，等. 2024.柴达木盆地西部地区新生代盆地性质[J]. 吉林大学学报（地球科学版），54（1）：160-181.

Wang Qianqian, Yuan Sihua, Wang Yadong, et al. 2024.The nature of the Cenozoic western Qaidam Basin[J]. Journal of Jilin University (Earth Science Edition), 54(1): 160-181.

[30]

魏小松，陆江，刘蕾，等. 2018. 涠西南凹陷流沙港组一段天文旋回识别及高频层序划分[J]. 中国海上油气，30（6）：99-108.

Wei Xiaosong, Lu Jiang, Liu Lei, et al. 2018. Astronomical cycle identification and high frequency sequence division of the 1st member of Liushagang Formation in Weixinan Sag, Beibuwan Basin[J]. China Offshore Oil and Gas, 30(6): 99-108.

[31]

吴怀春，张世红，冯庆来，等. 2011. 旋回地层学理论基础、研究进展和展望[J]. 地球科学：中国地质大学学报，36（3）：409-428.

Wu Huaichun, Zhang Shihong, Feng Qinglai, et al. 2011. Theoretical basis, research advancement and prospects of cyclostratigraphy[J]. Earth Science: Journal of China University of Geosciences, 36(3): 409-428.

[32]

吴怀春，张世红，黄清华. 2008. 中国东北松辽盆地晚白垩世青山口组浮动天文年代标尺的建立[J]. 地学前缘，15（4）：159-169.

Wu Huaichun, Zhang Shihong, Huang Qinghua. 2008. Establishment of floating astronomical time scale for the terrestrial Late Cretaceous Qingshankou Formation in the Songliao Basin of Northeast China[J]. Earth Science Frontiers, 15(4): 159-169.

[33]

吴文雯. 2020. 柴北缘西段冷湖七号构造古近系岩性分布地震预测[D]. 北京：中国石油大学（北京）.

Wu Wenwen. 2020. Lithologic prediction of Paleogene in Lenghu No.7 tectonic structure, the western part of northern Qaidam Basin[D]. Beijing: China University of Petroleum (Beijing).

[34]

颉永琛，关平，杨国军，等. 2012. 南八仙油气田成藏机理再认识[J]. 天然气地球科学， 23（5）：876-883.

Xie Yongchen, Guan Ping, Yang Guojun, et al. 2012. Reanalysis of reservoir accumulation mechanism in Nanbaxian oil-gas field[J]. Natural Gas Geoscience, 23(5): 876-883.

[35]

徐敬领，霍家庆，宋连腾，等. 2022. 基于测井数据的米氏旋回分析及浮动天文年代标尺的建立[J]. 地球物理学报，65（7）：2766-2778.

Xu Jingling, Huo Jiaqing, Song Lianteng, et al. 2022. Analysis of Milankovitch cycles and establishment of floating astronomical date scale based on well-logging data[J]. Chinese Journal of Geophysics, 65(7): 2766-2778.

[36]

徐伟，房磊，张新叶，等. 2019. 乌干达K油田扇三角洲沉积正演模拟与应用[J]. 地球科学，44（2）：513-523.

Xu Wei, Fang Lei, Zhang Xinye, et al. 2019. Sedimentary forward simulation and application of fan delta in K oil field in Uganda[J]. Earth Science, 44(2): 513-523.

[37]

徐为鹏，伊海生，唐闻强，等. 2023. 柴西开特米里克地区干柴沟组米氏旋回及湖平面变化特征[J]. 沉积与特提斯地质，43（4）：712-721.

Xu Weipeng, Yi Haisheng, Tang Wenqiang, et al. 2023. Characteristics of the Milankovitch cycles and lake-level changes in the Ganchaigou Formation of the Kaitemirike area, western Qaidam[J]. Sedimentary Geology and Tethyan Geology, 43(4): 712-721.

[38]

杨国军，王国芝，吴强，等. 2015. 柴达木盆地南八仙油气田构造及演化特征[J]. 重庆科技学院学报（自然科学版），17（2）：15-18，33.

Yang Guojun, Wang Guozhi, Wu Qiang, et al. 2015. The structure and evolution characteristics of Nanbaxian oil and gas field in Qaidam Basin[J]. Journal of Chongqing University of Science and Technology (Natural Sciences Edition), 17(2): 15-18, 33.

[39]

张振铎，姚宗全，穆波宇，等. 2023. 坝上河—滩坝微相组合特征——以柴北缘南八仙油气田新近系下油砂山组为例[J]. 中国科技论文，18（9）：942-955.

Zhang Zhenduo, Yao Zongquan, Mu Boyu, et al. 2023. Characteristics of upper distributary bar and beach-bar microfacies assemblages: A case study of Neogene Xiayoushashan Formation in Nanbaxian oil and gas field on northern margin of Qaidam Basin[J]. China Sciencepaper, 18(9): 942-955.

[40]

赵军，曹强，付宪弟，等. 2018. 基于米兰科维奇天文旋回恢复地层剥蚀厚度：以松辽盆地X油田青山口组为例[J]. 石油实验地质，40（2）：260-267.

Zhao Jun, Cao Qiang, Fu Xiandi, et al. 2018. Recovery of denuded strata thickness based on Milankovitch astronomical cycles: A case study of Qingshankou Formation in X oilfield, Songliao Basin[J]. Petroleum Geology & Experiment, 40(2): 260-267.

[41]

Cao H Y, Jin S D, Sun M, et al. 2016. Astronomical forcing of sedimentary cycles of Late Eocene Liushagang Formation in the Bailian Sag, Fushan Depression, Beibuwan Basin, South China Sea[J]. Journal of Central South University, 23(6): 1427-1438.

[42]

Falahatkhah O, Kordi M, Fatemi V, et al. 2021. Recognition of Milankovitch cycles during the Oligocene-Early Miocene in the Zagros Basin, SW Iran: Implications for Paleoclimate and sequence stratigraphy[J]. Sedimentary Geology, 421: 105957.

[43]

Fang Q, Wu H C, Hinnov L A, et al. 2017. Astronomical cycles of Middle Permian Maokou Formation in South China and their implications for sequence stratigraphy and paleoclimate[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 474: 130-139.

[44]

Guo G, Tong J N, Zhang S H, et al. 2008. Cyclostratigraphy of the Induan (Early Triassic) in West Pingdingshan section, Chaohu, Anhui province[J]. Science in China Series D: Earth Sciences, 51(1): 22-29.

[45]

He P, Zhang S F, Xu E Z, et al. 2022. Milankovitch cycles and the astronomical time scale of the Zhujiang Formation in the Baiyun Sag, Pearl River Mouth Basin, China[J]. Open Geosciences, 14(1): 1380-1392.

[46]

Huang C J, Tong J N, Hinnov L, et al. 2011. Did the great dying of life take 700 k.y.? Evidence from global astronomical correlation of the Permian-Triassic boundary interval[J]. Geology, 39(8): 779-782.

[47]

Laskar J, Robutel P, Joutel F, et al. 2004. A long-term numerical solution for the insolation quantities of the earth[J]. Astronomy & Astrophysics, 428(1): 261-285.

[48]

Li M S, Hinnov L, Kump L. 2019. Acycle: Time-series analysis software for paleoclimate research and education[J]. Computers & Geosciences, 127: 12-22.

[49]

Shi J Y, Jin Z J, Liu Q Y, et al. 2018. Terrestrial sedimentary responses to astronomically forced climate changes during the Early Paleogene in the Bohai Bay Basin, eastern China[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 502: 1-12.

[50]

Wei X S, Deng Y, Yan D T, et al. 2023. Organic matter enrichment in Asia's Palaeolake controlled by the Early and Middle Eocene global warming and astronomically driven precessional climate[J]. Marine and Petroleum Geology, 154: 106342.

[51]

Wu H C, Zhang S H, Jiang G Q, et al. 2009. The floating astronomical time scale for the terrestrial Late Cretaceous Qingshankou Formation from the Songliao Basin of Northeast China and its stratigraphic and paleoclimate implications[J]. Earth and Planetary Science Letters, 278(3/4): 308-323.

[52]

Xue Z Y, Chen P P, Li C L, et al. 2022. High frequency sequence stratigraphy analysis for Dawangbei subsag based on the spectrum analysis of the logging curve[J]. Arabian Journal of Geosciences, 15(11): 1047.

[53]

Zhang R, Li L, Nai W H, et al. 2019. Astronomical forcing of terrestrial climate recorded in the Pleistocene of the western Tarim Basin, NW China[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 530: 78-89.