塔里木盆地西北部震旦系奇格布拉克组层序地层划分——基于高分辨率相分析和Fischer图解的证据

汪远征; 葛小瞳; 唐攀; 杨钹; 陈代钊; 王斌; 邓模; 赵国伟; 汪远征; 葛小瞳; 唐攀; 杨钹; 陈代钊; 王斌; 邓模; 赵国伟

doi:10.14027/j.issn.1000-0550.2024.040

[1]

曹瑞骥，袁训来. 2006. 叠层石[M]. 合肥：中国科学技术大学出版社.

Cao Ruiji, Yuan Xunlai. 2006. Stromatolites[M]. Hefei: University of Science and Technology of China Press.

[2]

陈代钊，钱一雄. 2017. 深层—超深层白云岩储集层：机遇与挑战[J]. 古地理学报，19（2）：187-196.

Chen Daizhao, Qian Yixiong. 2017. Deep or super-deep dolostone reservoirs: Opportunities and challenges[J]. Journal of Palaeogeography, 19(2): 187-196.

[3]

陈旭东，许启鲁，郝芳，等. 2023. 塔里木盆地塔北地区上震旦统奇格布拉克组白云岩储层形成与成岩演化[J]. 中国科学：地球科学，53（10）：2348-2369.

Chen Xudong, Xu Qilu, Hao Fang, et al. 2023. Dolomite reservoir formation and diagenesis evolution of the Upper Ediacaran Qigebrak Formation in the Tabei area, Tarim Basin[J]. Science China Earth Sciences, 53(10): 2348-2369.

[4]

陈永权，严威，韩长伟，等. 2019. 塔里木盆地寒武纪/前寒武纪构造—沉积转换及其勘探意义[J]. 天然气地球科学，30（1）：39-50.

Chen Yongquan, Yan Wei, Han Changwei, et al. 2019. Structural and sedimentary basin transformation at the Cambrian/Neoproterozoic interval in Tarim Basin: Implication to subsalt dolostone exploration[J]. Natural Gas Geoscience, 30(1): 39-50.

[5]

丁海峰，马东升，姚春彦，等. 2014. 新疆阿克苏地区新元古代冰成沉积地球化学研究[J]. 地球化学，43（3）：224-237.

Ding Haifeng, Ma Dongsheng, Yao Chunyan, et al. 2014. A geochemistry study on Neoproterozoic glaciogenic sediments in Aksu area, Xinjiang[J]. Geochimica, 43(3): 224-237.

[6]

何碧竹，焦存礼，黄太柱，等. 2019. 塔里木盆地新元古代裂陷群结构构造及其形成动力学[J]. 中国科学：地球科学，49（4）：635-655.

He Bizhu, Jiao Cunli, Huang Taizhu, et al. 2019. Structural architecture of Neoproterozoic rifting depression groups in the Tarim Basin and their formation dynamics[J]. Science China Earth Sciences, 49(4): 635-655.

[7]

贾承造，张水昌. 2023. 中国海相超深层油气形成[J]. 地质学报，97（9）：2775-2801.

Jia Chengzao, Zhang Shuichang. 2023. The formation of marine ultra-deep petroleum in China[J]. Acta Geologica Sinica, 97(9): 2775-2801.

[8]

姜海健，陈强路，杨鑫，等. 2017. 塔里木盆地新元古代裂谷盆地层序样式[J]. 地质学报，91（3）：588-604.

Jiang Haijian, Chen Qianglu, Yang Xin, et al. 2017. The style of sequence stratigraphy of Neoproterozoic rift basin in the Tarim Basin[J]. Acta Geologica Sinica, 91(3): 588-604.

[9]

金值民，谭秀成，唐浩，等. 2021. 塔里木盆地西北部寒武系纽芬兰统玉尔吐斯组混积岩早成岩期岩溶特征及其地质意义[J]. 古地理学报，23（1）：191-206.

Jin Zhimin, Tan Xiucheng, Tang Hao, et al. 2021. Eogenetic karst characteristics and its geological significance of mixed rocks in the Cambrian Terreneuvian Yuertus Formation in northwestern Tarim Basin[J]. Journal of Palaeogeography, 23(1): 191-206.

[10]

李朋威，罗平，宋金民，等. 2015. 微生物碳酸盐岩储层特征与主控因素：以塔里木盆地西北缘上震旦统—下寒武统为例[J]. 石油学报，36（9）：1074-1089.

Li Pengwei, Luo Ping, Song Jinmin, et al. 2015. Characteristics and main controlling factors of microbial carbonate reservoirs: A case study of Upper Sinian-lower Cambrian in the northwestern margin of Tarim Basin[J]. Acta Petrolei Sinica, 36(9): 1074-1089.

[11]

李王鹏,王毅,李慧莉,等. 2022. 塔里木地块西北缘阿克苏地区新元古代冰碛岩年代与冰期事件[J]. 现代地质，36（1）：27-47.

Li Wangpeng, Wang Yi, Li Huili, et al. 2022. Geochronology and glaciation of the Neoproterozoic diamictite in Aksu area, northwestern margin of the Tarim Block[J]. Geoscience, 36(1): 27-47.

[12]

刘若涵，何碧竹，焦存礼，等. 2020. 新疆阿克苏地区新元古代沉积特征对裂谷发育过程的指示[J]. 岩石学报， 36（10）：3225-3242.

Liu Ruohan, He Bizhu, Jiao Cunli, et al. 2020. The indication of Neoproterozoic sedimentary characteristics to rift development process in Aksu area, Xinjiang[J]. Acta Petrologica Sinica, 36(10): 3225-3242.

[13]

罗明霞，曹自成，徐勤琪，等. 2024. 塔里木盆地塔河油田塔深5井震旦系原油地球化学特征及地质意义[J]. 地质科技通报，43（1）：135-149.

Luo Mingxia, Cao Zicheng, Xu Qinqi, et al. 2024. Geochemical characteristics and geological significance of Sinian crude oil from well Tashen 5, Tahe oilfield, Tarim Basin[J]. Bulletin of Geological Science and Technology, 43(1): 135-149.

[14]

罗平，王石，李朋威，等. 2013. 微生物碳酸盐岩油气储层研究现状与展望[J]. 沉积学报，31（5）：807-823.

Luo Ping, Wang Shi, Li Pengwei, et al. 2013. Review and prospectives of microbial carbonate reservoirs[J]. Acta Sedimentologica Sinica, 31(5): 807-823.

[15]

钱一雄，杜永明，陈代钊，等. 2014. 塔里木盆地肖尔布拉克剖面奇格布拉克组层序界面与沉积相研究[J]. 石油实验地质，36（1）：1-7.

Qian Yixiong, Du Yongming, Chen Daizhao, et al. 2014. Stratigraphic sequences and sedimentary facies of Qigebulak Formation at Xianerbulak, Tarim Basin[J]. Petroleum Geology & Experiment, 36(1): 1-7.

[16]

沈卫兵，王义凤，谢鸿哲，等. 2023. 塔里木盆地西北缘新元古界层序地层划分及区域对比意义[J]. 地质学报，97（12）：3967-3983.

Shen Weibing, Wang Yifeng, Xie Hongzhe, et al. 2023. Neoproterozoic sequence stratigraphy in the northwestern margin of the Tarim Basin and its regional correlation significance[J]. Acta Geologica Sinica, 97(12): 3967-3983.

[17]

石开波，刘波，姜伟民，等. 2018. 塔里木盆地南华纪—震旦纪构造—沉积格局[J]. 石油与天然气地质，39（5）：862-877.

Shi Kaibo, Liu Bo, Jiang Weimin, et al. 2018. Nanhua-Sinian tectono-sedimentary framework of Tarim Basin, NW China[J]. Oil & Gas Geology, 39(5): 862-877.

[18]

石开波，刘波，田景春，等. 2016. 塔里木盆地震旦纪沉积特征及岩相古地理[J]. 石油学报，37（11）：1343-1360.

Shi Kaibo, Liu Bo, Tian Jingchun, et al. 2016. Sedimentary characteristics and lithofacies paleogeography of Sinian in Tarim Basin[J]. Acta Petrolei Sinica, 37(11): 1343-1360.

[19]

孙冬胜，李双建，李建交，等. 2022. 塔里木与四川盆地震旦系—寒武系油气成藏条件对比与启示[J]. 地质学报，96（1）：249-264.

Sun Dongsheng, Li Shuangjian, Li Jianjiao, et al. 2022. Insights from a comparison of hydrocarbon accumulation conditions of Sinian-Cambrian between the Tarim and the Sichuan Basins[J]. Acta Geologica Sinica, 96(1): 249-264.

[20]

唐攀，汪远征，李双建，等. 2024. 塔里木盆地西北部震旦系—寒武系不整合面成因：来自沉积学的证据[J]. 沉积学报，42（3）：877-891.

Tang Pan, Wang Yuanzheng, Li Shuangjian, et al. 2024. Genesis of the Sinian-Cambrian unconformity in the northwestern Tarim Basin: Evidence from sedimentology[J]. Acta Sedimentologica Sinica, 42(3): 877-891.

[21]

王宇，何金有，卫巍，等. 2010.新疆阿克苏地区新元古代晚期地层沉积相及层序地层研究[J]. 岩石学报，26（8）：2519-2528.

Wang Yu, He Jinyou, Wei Wei, et al. 2010. Study on the Late Proterozoic sedimentary facies and sequence stratigraphy in Aksu area, Xinjiang[J]. Acta Petrologica Sinica, 26(8): 2519-2528.

[22]

吴福志，刘东娜，赵峰华，等. 2021. 塔里木盆地西北缘苏盖特布拉克组沉积环境及构造背景研究[J]. 矿物岩石地球化学通报，40（2）：478-490.

Wu Fuzhi, Liu Dongna, Zhao Fenghua, et al. 2021. Sedimentary conditions and geotectonic setting implicated from the geochemistry of major and trace elements in pelite of the Sugetbrak Formation in northwestern of Tarim Basin, Xinjiang, China[J]. Bulletin of Mineralogy, Petrology and Geochemistry, 40(2): 478-490.

[23]

吴林，管树巍，杨海军，等. 2017. 塔里木北部新元古代裂谷盆地古地理格局与油气勘探潜力[J]. 石油学报，38（4）：375-385.

Wu Lin, Guan Shuwei, Yang Haijun, et al. 2017. The paleogeographic framework and hydrocarbon exploration potential of Neoproterozoic rift basin in northern Tarim Basin[J]. Acta Petrolei Sinica, 38(4): 375-385.

[24]

闫磊，朱光有，王珊，等. 2021. 塔里木盆地震旦系—寒武系万米超深层天然气成藏条件与有利区带优选[J]. 石油学报，42（11）：1446-1457.

Yan Lei, Zhu Guangyou, Wang Shan, et al. 2021. Accmulation conditions and favorable areas for natural gas accumulation in the 10000 meters ultra-deep Sinian-Cambrian in Tarim Basin[J]. Acta Petrolei Sinica, 42(11): 1446-1457.

[25]

杨海军，陈永权，田军，等. 2020. 塔里木盆地轮探1井超深层油气勘探重大发现与意义[J]. 中国石油勘探，25（2）：62-72.

Yang Haijun, Chen Yongquan, Tian Jun, et al. 2020. Great discovery and its signifi cance of ultra-deep oil and gas exploration in well Luntan-1 of the Tarim Basin[J]. China Petroleum Exploration, 25(2): 62-72.

[26]

杨翰轩，沈安江，郑剑锋，等. 2020. 塔里木盆地西北缘震旦系奇格布拉克组微生物白云岩发育特征及储集意义[J]. 海相油气地质，25（1）：44-54.

Yang Hanxuan, Shen Anjiang, Zheng Jianfeng, et al. 2020. Sedimentary characteristics and reservoir significance of the microbial dolomite of Sinian Qigebrak Formation in the northwest margin of Tarim Basin[J]. Marine Origin Petroleum Geology, 25(1): 44-54.

[27]

杨云坤，石开波，刘波，等. 2014. 塔里木盆地西北缘震旦纪构造—沉积演化特征[J]. 地质科学，49（1）：19-29.

Yang Yunkun, Shi Kaibo, Liu Bo, et al. 2014. Tectono-sedimentary evolution of the Sinian in the northwest Tarim Basin[J]. Chinese Journal of Geology, 49(1): 19-29.

[28]

郑剑锋，刘禹，朱永进，等. 2021. 塔里木盆地乌什地区上震旦统奇格布拉克组地球化学特征及其地质意义[J]. 古地理学报，23（5）：983-998.

Zheng Jianfeng, Liu Yu, Zhu Yongjin, et al. 2021. Geochemical features and its geological significances of the Upper Sinian Qigeblak Formation in Wushi area, Tarim Basin[J]. Journal of Palaeogeography, 23(5): 983-998.

[29]

周志毅，赵治信，胡兆珣，等. 2001. 塔里木盆地各纪地层[J]. 北京：科学出版社：340-343.

Zhou Zhiyi, Zhao Zhixin, Hu Zhaoxun, et al. 2001. Stratigraphy of the Tarim Basin[M]. Beijing: Science Press: 340-343.

[30]

朱永进，沈安江，刘玲利，等. 2020. 塔里木盆地晚震旦世—中寒武世构造沉积充填过程及油气勘探地位[J]. 沉积学报，38（2）：398-410.

Zhu Yongjin, Shen Anjiang, Liu Lingli, et al. 2020. Tectonic-sedimentary filling history through the Later Sinian to the mid-Cambrian in Tarim Basin and its explorational potential[J]. Acta Sedimentologica Sinica, 38(2): 398-410.

[31]

邹才能，杜金虎，徐春春，等. 2014. 四川盆地震旦系—寒武系特大型气田形成分布、资源潜力及勘探发现[J]. 石油勘探与开发，41（3）：278-293.

Zou Caineng, Du Jinhu, Xu Chunchun, et al. 2014. Formation, distribution, resource potential and discovery of the Sinian-Cambrian giant gas field, Sichuan Basin, SW China[J]. Petroleum Exploration and Development, 41(3): 278-293.

[32]

Brownlaw R L S, Hocking R M, Jell J S. 1996. High frequency sea‐level fluctuations in the Pillara Limestone, Guppy Hills, Lennard Shelf, northwestern Australia[J]. Historical Biology, 11(1/2/3/4): 187-212.

[33]

Catuneanu O. 2002. Sequence stratigraphy of clastic systems: Concepts, merits, and pitfalls[J]. Journal of African Earth Sciences, 35(1): 1-43.

[34]

Catuneanu O. 2019. Scale in sequence stratigraphy[J]. Marine and Petroleum Geology, 106: 128-159.

[35]

Catuneanu O, Khalifa M A, Wanas H A. 2006. Sequence stratigraphy of the Lower Cenomanian Bahariya Formation, Bahariya Oasis, western Desert, Egypt[J]. Sedimentary Geology, 190(1/2/3/4): 121-137.

[36]

Chen D Z, Guo Z H, Jiang M S, et al. 2016. Dynamics of cyclic carbonate deposition and biotic recovery on platforms during the Famennian of Late Devonian in Guangxi, South China: Constraints from high-resolution cycle and sequence stratigraphy[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 448: 245-265.

[37]

Chen D Z, Tucker M E. 2003. The Frasnian–Famennian mass extinction: Insights from high-resolution sequence stratigraphy and cyclostratigraphy in South China[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 193(1): 87-111.

[38]

Chen W Y, Zhu G Y, Zhang K J, et al. 2020. Late Neoproterozoic intracontinental rifting of the Tarim carton, NW China: An integrated geochemical, geochronological and Sr–Nd–Hf isotopic study of siliciclastic rocks and basalts from deep drilling cores[J]. Gondwana Research, 80: 142-156.

[39]

Fischer A G. 1964. The lofer cyclothems of the Alpine Triassic[M]//Merriam D F. Symposium on cyclic sedimentation: Kansas geological survey bulletin 169. Lawrence: State Geological Survey of Kansas.

[40]

Gradstein F M, Ogg J G, Schmitz M D, et al. 2020. Geologic time scale 2020[M]. Amsterdam: Elsevier.

[41]

Guan S W, Zhang C Y, Ren R, et al. 2019. Early Cambrian syndepositional structure of the northern Tarim Basin and a discussion of Cambrian subsalt and deep exploration[J]. Petroleum Exploration and Development, 46(6): 1141-1152.

[42]

Guo C, Chen D Z, Song Y F, et al. 2018. Depositional environments and cyclicity of the Early Ordovician carbonate ramp in the western Tarim Basin (NW China)[J]. Journal of Asian Earth Sciences, 158: 29-48.

[43]

Haq B U, Schutter S R. 2008. A chronology of Paleozoic sea-level changes[J]. Science, 322(5898): 64-68.

[44]

He B Z, Jiao C L, Cai Z H, et al. 2021. Soft-sediment deformation structures (SSDS) in the Ediacaran and lower Cambrian succession of the Aksu area, NW Tarim Basin, and their implications[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 567: 110237.

[45]

He J W, Zhu W B, Ge R F. 2014. New age constraints on Neoproterozoic diamicites in Kuruktag, NW China and Precambrian crustal evolution of the Tarim Craton[J]. Precambrian Research, 241: 44-60.

[46]

He X B, Xu B, Yuan Z Y. 2007. C-isotope composition and correlation of the Upper Neoproterozoic in Keping area, Xinjiang[J]. Chinese Science Bulletin, 52(4): 504-511.

[47]

Li Z X, Bogdanova S V, Collins A S, et al. 2008. Assembly, configuration, and break-up history of Rodinia: A synthesis[J]. Precambrian Research, 160(1/2): 179-210.

[48]

Merdith A S, Collins A S, Williams S E, et al. 2017. A full-plate global reconstruction of the Neoproterozoic[J]. Gondwana Research, 50: 84-134.

[49]

Read J F, Goldhammer R K. 1988. Use of Fischer plots to define third-order sea-level curves in Ordovician peritidal cyclic carbonates, appalachians[J]. Geology, 16(10): 895-899.

[50]

Sadler P M, Osleger D A, Montanez I P. 1993. On the labeling, length, and objective basis of Fischer plots[J]. Journal of Sedimentary Petrology, 63(3): 360-368.

[51]

Schlager W. 2005. Carbonate sedimentology and sequence stratigraphy[M]. Tulsa: SEPM.

[52]

Shen W B, Zhu X K, Xie H Z, et al. 2022. Tectonic–sedimentary evolution during initiation of the Tarim Basin: Insights from Late Neoproterozoic sedimentary records in the NW Basin[J]. Precambrian Research, 371: 106598.

[53]

Tang P, Chen D Z, Wang Y Z, et al. 2022. Diagenesis of microbialite-dominated carbonates in the Upper Ediacaran Qigebrak Formation, NW Tarim Basin, China: Implications for reservoir development[J]. Marine and Petroleum Geology, 136: 105476.

[54]

Turner S A. 2010. Sedimentary record of Late Neoproterozoic rifting in the NW Tarim Basin, China[J]. Precambrian Research, 181(1/2/3/4): 85-96.

[55]

Vandyk T M, Wu G, Davies B J, et al. 2019. Temperate glaciation on a Snowball Earth: Glaciological and palaeogeographic insights from the Cryogenian Yuermeinak Formation of NW China[J]. Precambrian Research, 331: 105362.

[56]

Wang Y Z, Chen D Z, Liu M, et al. 2022. Ediacaran carbon cycling and Shuram excursion recorded in the Tarim Block, northwestern China[J]. Precambrian Research, 377: 106694.

[57]

Wu G H, Yang S, Liu W, et al. 2021. Switching from advancing to retreating subduction in the Neoproterozoic Tarim Craton, NW China: Implications for Rodinia breakup[J]. Geoscience Frontiers, 12(1): 161-171.

[58]

Xu B, Jian P, Zheng H F, et al. 2005. U–Pb zircon geochronology and geochemistry of Neoproterozoic volcanic rocks in the Tarim Block of Northwest China: Implications for the breakup of Rodinia supercontinent and Neoproterozoic glaciations[J]. Precambrian Research, 136(2): 107-123.

[59]

Xu B, Zou H B, Chen Y, et al. 2013. The Sugetbrak basalts from northwestern Tarim Block of northwest China: Geochronology, geochemistry and implications for Rodinia breakup and ice age in the Late Neoproterozoic[J]. Precambrian Research, 236: 214-226.

[60]

Zhang Y G, Yang T, Hohl S V, et al. 2020. Seawater carbon and strontium isotope variations through the Late Ediacaran to late Cambrian in the Tarim Basin[J]. Precambrian Research, 345: 105769.

[61]

Zhang Y Q, Chen D Z, Zhou X Q, et al. 2015. Depositional facies and stratal cyclicity of dolomites in the Lower Qiulitag Group (upper Cambrian) in northwestern Tarim Basin, NW China[J]. Facies, 61(1): 417.

[62]

Zhao G C, Wang Y J, Huang B C, et al. 2018. Geological reconstructions of the East Asian blocks: From the breakup of Rodinia to the assembly of Pangea[J]. Earth-Science Reviews, 186: 262-286.

[63]

Zhao P, He J Y, Deng C L, et al. 2021. Early Neoproterozoic (870-820 Ma) amalgamation of the Tarim Craton (northwestern China) and the final assembly of Rodinia[J]. Geology, 49(11): 1277-1282.

[64]

Zhu G Y, Wang T S, Xie Z Y, et al. 2015. Giant gas discovery in the Precambrian deeply buried reservoirs in the Sichuan Basin, China: Implications for gas exploration in old cratonic basins[J]. Precambrian Research, 262: 45-66.

[65]

Zhu W B, Zheng B H, Shu L S, et al. 2011. Neoproterozoic tectonic evolution of the Precambrian Aksu blueschist terrane, northwestern Tarim, China: Insights from LA-ICP-MS zircon U–Pb ages and geochemical data[J]. Precambrian Research, 185(3/4): 215-230.

[66]

Zhou X J, Liu W, Wu G H, et al. 2022. The latest Neoproterozoic basaltic and siliciclastic rocks and tectonic implications in the Tarim Craton, NW China[J]. Journal of Asian Earth Sciences, 232: 1-16.

[1]	曹瑞骥，袁训来. 2006. 叠层石[M]. 合肥：中国科学技术大学出版社. Cao Ruiji, Yuan Xunlai. 2006. Stromatolites[M]. Hefei: University of Science and Technology of China Press.
[2]	陈代钊，钱一雄. 2017. 深层—超深层白云岩储集层：机遇与挑战[J]. 古地理学报，19（2）：187-196. Chen Daizhao, Qian Yixiong. 2017. Deep or super-deep dolostone reservoirs: Opportunities and challenges[J]. Journal of Palaeogeography, 19(2): 187-196.
[3]	陈旭东，许启鲁，郝芳，等. 2023. 塔里木盆地塔北地区上震旦统奇格布拉克组白云岩储层形成与成岩演化[J]. 中国科学：地球科学，53（10）：2348-2369. Chen Xudong, Xu Qilu, Hao Fang, et al. 2023. Dolomite reservoir formation and diagenesis evolution of the Upper Ediacaran Qigebrak Formation in the Tabei area, Tarim Basin[J]. Science China Earth Sciences, 53(10): 2348-2369.
[4]	陈永权，严威，韩长伟，等. 2019. 塔里木盆地寒武纪/前寒武纪构造—沉积转换及其勘探意义[J]. 天然气地球科学，30（1）：39-50. Chen Yongquan, Yan Wei, Han Changwei, et al. 2019. Structural and sedimentary basin transformation at the Cambrian/Neoproterozoic interval in Tarim Basin: Implication to subsalt dolostone exploration[J]. Natural Gas Geoscience, 30(1): 39-50.
[5]	丁海峰，马东升，姚春彦，等. 2014. 新疆阿克苏地区新元古代冰成沉积地球化学研究[J]. 地球化学，43（3）：224-237. Ding Haifeng, Ma Dongsheng, Yao Chunyan, et al. 2014. A geochemistry study on Neoproterozoic glaciogenic sediments in Aksu area, Xinjiang[J]. Geochimica, 43(3): 224-237.
[6]	何碧竹，焦存礼，黄太柱，等. 2019. 塔里木盆地新元古代裂陷群结构构造及其形成动力学[J]. 中国科学：地球科学，49（4）：635-655. He Bizhu, Jiao Cunli, Huang Taizhu, et al. 2019. Structural architecture of Neoproterozoic rifting depression groups in the Tarim Basin and their formation dynamics[J]. Science China Earth Sciences, 49(4): 635-655.
[7]	贾承造，张水昌. 2023. 中国海相超深层油气形成[J]. 地质学报，97（9）：2775-2801. Jia Chengzao, Zhang Shuichang. 2023. The formation of marine ultra-deep petroleum in China[J]. Acta Geologica Sinica, 97(9): 2775-2801.
[8]	姜海健，陈强路，杨鑫，等. 2017. 塔里木盆地新元古代裂谷盆地层序样式[J]. 地质学报，91（3）：588-604. Jiang Haijian, Chen Qianglu, Yang Xin, et al. 2017. The style of sequence stratigraphy of Neoproterozoic rift basin in the Tarim Basin[J]. Acta Geologica Sinica, 91(3): 588-604.
[9]	金值民，谭秀成，唐浩，等. 2021. 塔里木盆地西北部寒武系纽芬兰统玉尔吐斯组混积岩早成岩期岩溶特征及其地质意义[J]. 古地理学报，23（1）：191-206. Jin Zhimin, Tan Xiucheng, Tang Hao, et al. 2021. Eogenetic karst characteristics and its geological significance of mixed rocks in the Cambrian Terreneuvian Yuertus Formation in northwestern Tarim Basin[J]. Journal of Palaeogeography, 23(1): 191-206.
[10]	李朋威，罗平，宋金民，等. 2015. 微生物碳酸盐岩储层特征与主控因素：以塔里木盆地西北缘上震旦统—下寒武统为例[J]. 石油学报，36（9）：1074-1089. Li Pengwei, Luo Ping, Song Jinmin, et al. 2015. Characteristics and main controlling factors of microbial carbonate reservoirs: A case study of Upper Sinian-lower Cambrian in the northwestern margin of Tarim Basin[J]. Acta Petrolei Sinica, 36(9): 1074-1089.
[11]	李王鹏,王毅,李慧莉,等. 2022. 塔里木地块西北缘阿克苏地区新元古代冰碛岩年代与冰期事件[J]. 现代地质，36（1）：27-47. Li Wangpeng, Wang Yi, Li Huili, et al. 2022. Geochronology and glaciation of the Neoproterozoic diamictite in Aksu area, northwestern margin of the Tarim Block[J]. Geoscience, 36(1): 27-47.
[12]	刘若涵，何碧竹，焦存礼，等. 2020. 新疆阿克苏地区新元古代沉积特征对裂谷发育过程的指示[J]. 岩石学报， 36（10）：3225-3242. Liu Ruohan, He Bizhu, Jiao Cunli, et al. 2020. The indication of Neoproterozoic sedimentary characteristics to rift development process in Aksu area, Xinjiang[J]. Acta Petrologica Sinica, 36(10): 3225-3242.
[13]	罗明霞，曹自成，徐勤琪，等. 2024. 塔里木盆地塔河油田塔深5井震旦系原油地球化学特征及地质意义[J]. 地质科技通报，43（1）：135-149. Luo Mingxia, Cao Zicheng, Xu Qinqi, et al. 2024. Geochemical characteristics and geological significance of Sinian crude oil from well Tashen 5, Tahe oilfield, Tarim Basin[J]. Bulletin of Geological Science and Technology, 43(1): 135-149.
[14]	罗平，王石，李朋威，等. 2013. 微生物碳酸盐岩油气储层研究现状与展望[J]. 沉积学报，31（5）：807-823. Luo Ping, Wang Shi, Li Pengwei, et al. 2013. Review and prospectives of microbial carbonate reservoirs[J]. Acta Sedimentologica Sinica, 31(5): 807-823.
[15]	钱一雄，杜永明，陈代钊，等. 2014. 塔里木盆地肖尔布拉克剖面奇格布拉克组层序界面与沉积相研究[J]. 石油实验地质，36（1）：1-7. Qian Yixiong, Du Yongming, Chen Daizhao, et al. 2014. Stratigraphic sequences and sedimentary facies of Qigebulak Formation at Xianerbulak, Tarim Basin[J]. Petroleum Geology & Experiment, 36(1): 1-7.
[16]	沈卫兵，王义凤，谢鸿哲，等. 2023. 塔里木盆地西北缘新元古界层序地层划分及区域对比意义[J]. 地质学报，97（12）：3967-3983. Shen Weibing, Wang Yifeng, Xie Hongzhe, et al. 2023. Neoproterozoic sequence stratigraphy in the northwestern margin of the Tarim Basin and its regional correlation significance[J]. Acta Geologica Sinica, 97(12): 3967-3983.
[17]	石开波，刘波，姜伟民，等. 2018. 塔里木盆地南华纪—震旦纪构造—沉积格局[J]. 石油与天然气地质，39（5）：862-877. Shi Kaibo, Liu Bo, Jiang Weimin, et al. 2018. Nanhua-Sinian tectono-sedimentary framework of Tarim Basin, NW China[J]. Oil & Gas Geology, 39(5): 862-877.
[18]	石开波，刘波，田景春，等. 2016. 塔里木盆地震旦纪沉积特征及岩相古地理[J]. 石油学报，37（11）：1343-1360. Shi Kaibo, Liu Bo, Tian Jingchun, et al. 2016. Sedimentary characteristics and lithofacies paleogeography of Sinian in Tarim Basin[J]. Acta Petrolei Sinica, 37(11): 1343-1360.
[19]	孙冬胜，李双建，李建交，等. 2022. 塔里木与四川盆地震旦系—寒武系油气成藏条件对比与启示[J]. 地质学报，96（1）：249-264. Sun Dongsheng, Li Shuangjian, Li Jianjiao, et al. 2022. Insights from a comparison of hydrocarbon accumulation conditions of Sinian-Cambrian between the Tarim and the Sichuan Basins[J]. Acta Geologica Sinica, 96(1): 249-264.
[20]	唐攀，汪远征，李双建，等. 2024. 塔里木盆地西北部震旦系—寒武系不整合面成因：来自沉积学的证据[J]. 沉积学报，42（3）：877-891. Tang Pan, Wang Yuanzheng, Li Shuangjian, et al. 2024. Genesis of the Sinian-Cambrian unconformity in the northwestern Tarim Basin: Evidence from sedimentology[J]. Acta Sedimentologica Sinica, 42(3): 877-891.
[21]	王宇，何金有，卫巍，等. 2010.新疆阿克苏地区新元古代晚期地层沉积相及层序地层研究[J]. 岩石学报，26（8）：2519-2528. Wang Yu, He Jinyou, Wei Wei, et al. 2010. Study on the Late Proterozoic sedimentary facies and sequence stratigraphy in Aksu area, Xinjiang[J]. Acta Petrologica Sinica, 26(8): 2519-2528.
[22]	吴福志，刘东娜，赵峰华，等. 2021. 塔里木盆地西北缘苏盖特布拉克组沉积环境及构造背景研究[J]. 矿物岩石地球化学通报，40（2）：478-490. Wu Fuzhi, Liu Dongna, Zhao Fenghua, et al. 2021. Sedimentary conditions and geotectonic setting implicated from the geochemistry of major and trace elements in pelite of the Sugetbrak Formation in northwestern of Tarim Basin, Xinjiang, China[J]. Bulletin of Mineralogy, Petrology and Geochemistry, 40(2): 478-490.
[23]	吴林，管树巍，杨海军，等. 2017. 塔里木北部新元古代裂谷盆地古地理格局与油气勘探潜力[J]. 石油学报，38（4）：375-385. Wu Lin, Guan Shuwei, Yang Haijun, et al. 2017. The paleogeographic framework and hydrocarbon exploration potential of Neoproterozoic rift basin in northern Tarim Basin[J]. Acta Petrolei Sinica, 38(4): 375-385.
[24]	闫磊，朱光有，王珊，等. 2021. 塔里木盆地震旦系—寒武系万米超深层天然气成藏条件与有利区带优选[J]. 石油学报，42（11）：1446-1457. Yan Lei, Zhu Guangyou, Wang Shan, et al. 2021. Accmulation conditions and favorable areas for natural gas accumulation in the 10000 meters ultra-deep Sinian-Cambrian in Tarim Basin[J]. Acta Petrolei Sinica, 42(11): 1446-1457.
[25]	杨海军，陈永权，田军，等. 2020. 塔里木盆地轮探1井超深层油气勘探重大发现与意义[J]. 中国石油勘探，25（2）：62-72. Yang Haijun, Chen Yongquan, Tian Jun, et al. 2020. Great discovery and its signifi cance of ultra-deep oil and gas exploration in well Luntan-1 of the Tarim Basin[J]. China Petroleum Exploration, 25(2): 62-72.
[26]	杨翰轩，沈安江，郑剑锋，等. 2020. 塔里木盆地西北缘震旦系奇格布拉克组微生物白云岩发育特征及储集意义[J]. 海相油气地质，25（1）：44-54. Yang Hanxuan, Shen Anjiang, Zheng Jianfeng, et al. 2020. Sedimentary characteristics and reservoir significance of the microbial dolomite of Sinian Qigebrak Formation in the northwest margin of Tarim Basin[J]. Marine Origin Petroleum Geology, 25(1): 44-54.
[27]	杨云坤，石开波，刘波，等. 2014. 塔里木盆地西北缘震旦纪构造—沉积演化特征[J]. 地质科学，49（1）：19-29. Yang Yunkun, Shi Kaibo, Liu Bo, et al. 2014. Tectono-sedimentary evolution of the Sinian in the northwest Tarim Basin[J]. Chinese Journal of Geology, 49(1): 19-29.
[28]	郑剑锋，刘禹，朱永进，等. 2021. 塔里木盆地乌什地区上震旦统奇格布拉克组地球化学特征及其地质意义[J]. 古地理学报，23（5）：983-998. Zheng Jianfeng, Liu Yu, Zhu Yongjin, et al. 2021. Geochemical features and its geological significances of the Upper Sinian Qigeblak Formation in Wushi area, Tarim Basin[J]. Journal of Palaeogeography, 23(5): 983-998.
[29]	周志毅，赵治信，胡兆珣，等. 2001. 塔里木盆地各纪地层[J]. 北京：科学出版社：340-343. Zhou Zhiyi, Zhao Zhixin, Hu Zhaoxun, et al. 2001. Stratigraphy of the Tarim Basin[M]. Beijing: Science Press: 340-343.
[30]	朱永进，沈安江，刘玲利，等. 2020. 塔里木盆地晚震旦世—中寒武世构造沉积充填过程及油气勘探地位[J]. 沉积学报，38（2）：398-410. Zhu Yongjin, Shen Anjiang, Liu Lingli, et al. 2020. Tectonic-sedimentary filling history through the Later Sinian to the mid-Cambrian in Tarim Basin and its explorational potential[J]. Acta Sedimentologica Sinica, 38(2): 398-410.
[31]	邹才能，杜金虎，徐春春，等. 2014. 四川盆地震旦系—寒武系特大型气田形成分布、资源潜力及勘探发现[J]. 石油勘探与开发，41（3）：278-293. Zou Caineng, Du Jinhu, Xu Chunchun, et al. 2014. Formation, distribution, resource potential and discovery of the Sinian-Cambrian giant gas field, Sichuan Basin, SW China[J]. Petroleum Exploration and Development, 41(3): 278-293.
[32]	Brownlaw R L S, Hocking R M, Jell J S. 1996. High frequency sea‐level fluctuations in the Pillara Limestone, Guppy Hills, Lennard Shelf, northwestern Australia[J]. Historical Biology, 11(1/2/3/4): 187-212.
[33]	Catuneanu O. 2002. Sequence stratigraphy of clastic systems: Concepts, merits, and pitfalls[J]. Journal of African Earth Sciences, 35(1): 1-43.
[34]	Catuneanu O. 2019. Scale in sequence stratigraphy[J]. Marine and Petroleum Geology, 106: 128-159.
[35]	Catuneanu O, Khalifa M A, Wanas H A. 2006. Sequence stratigraphy of the Lower Cenomanian Bahariya Formation, Bahariya Oasis, western Desert, Egypt[J]. Sedimentary Geology, 190(1/2/3/4): 121-137.
[36]	Chen D Z, Guo Z H, Jiang M S, et al. 2016. Dynamics of cyclic carbonate deposition and biotic recovery on platforms during the Famennian of Late Devonian in Guangxi, South China: Constraints from high-resolution cycle and sequence stratigraphy[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 448: 245-265.
[37]	Chen D Z, Tucker M E. 2003. The Frasnian–Famennian mass extinction: Insights from high-resolution sequence stratigraphy and cyclostratigraphy in South China[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 193(1): 87-111.
[38]	Chen W Y, Zhu G Y, Zhang K J, et al. 2020. Late Neoproterozoic intracontinental rifting of the Tarim carton, NW China: An integrated geochemical, geochronological and Sr–Nd–Hf isotopic study of siliciclastic rocks and basalts from deep drilling cores[J]. Gondwana Research, 80: 142-156.
[39]	Fischer A G. 1964. The lofer cyclothems of the Alpine Triassic[M]//Merriam D F. Symposium on cyclic sedimentation: Kansas geological survey bulletin 169. Lawrence: State Geological Survey of Kansas.
[40]	Gradstein F M, Ogg J G, Schmitz M D, et al. 2020. Geologic time scale 2020[M]. Amsterdam: Elsevier.
[41]	Guan S W, Zhang C Y, Ren R, et al. 2019. Early Cambrian syndepositional structure of the northern Tarim Basin and a discussion of Cambrian subsalt and deep exploration[J]. Petroleum Exploration and Development, 46(6): 1141-1152.
[42]	Guo C, Chen D Z, Song Y F, et al. 2018. Depositional environments and cyclicity of the Early Ordovician carbonate ramp in the western Tarim Basin (NW China)[J]. Journal of Asian Earth Sciences, 158: 29-48.
[43]	Haq B U, Schutter S R. 2008. A chronology of Paleozoic sea-level changes[J]. Science, 322(5898): 64-68.
[44]	He B Z, Jiao C L, Cai Z H, et al. 2021. Soft-sediment deformation structures (SSDS) in the Ediacaran and lower Cambrian succession of the Aksu area, NW Tarim Basin, and their implications[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 567: 110237.
[45]	He J W, Zhu W B, Ge R F. 2014. New age constraints on Neoproterozoic diamicites in Kuruktag, NW China and Precambrian crustal evolution of the Tarim Craton[J]. Precambrian Research, 241: 44-60.
[46]	He X B, Xu B, Yuan Z Y. 2007. C-isotope composition and correlation of the Upper Neoproterozoic in Keping area, Xinjiang[J]. Chinese Science Bulletin, 52(4): 504-511.
[47]	Li Z X, Bogdanova S V, Collins A S, et al. 2008. Assembly, configuration, and break-up history of Rodinia: A synthesis[J]. Precambrian Research, 160(1/2): 179-210.
[48]	Merdith A S, Collins A S, Williams S E, et al. 2017. A full-plate global reconstruction of the Neoproterozoic[J]. Gondwana Research, 50: 84-134.
[49]	Read J F, Goldhammer R K. 1988. Use of Fischer plots to define third-order sea-level curves in Ordovician peritidal cyclic carbonates, appalachians[J]. Geology, 16(10): 895-899.
[50]	Sadler P M, Osleger D A, Montanez I P. 1993. On the labeling, length, and objective basis of Fischer plots[J]. Journal of Sedimentary Petrology, 63(3): 360-368.
[51]	Schlager W. 2005. Carbonate sedimentology and sequence stratigraphy[M]. Tulsa: SEPM.
[52]	Shen W B, Zhu X K, Xie H Z, et al. 2022. Tectonic–sedimentary evolution during initiation of the Tarim Basin: Insights from Late Neoproterozoic sedimentary records in the NW Basin[J]. Precambrian Research, 371: 106598.
[53]	Tang P, Chen D Z, Wang Y Z, et al. 2022. Diagenesis of microbialite-dominated carbonates in the Upper Ediacaran Qigebrak Formation, NW Tarim Basin, China: Implications for reservoir development[J]. Marine and Petroleum Geology, 136: 105476.
[54]	Turner S A. 2010. Sedimentary record of Late Neoproterozoic rifting in the NW Tarim Basin, China[J]. Precambrian Research, 181(1/2/3/4): 85-96.
[55]	Vandyk T M, Wu G, Davies B J, et al. 2019. Temperate glaciation on a Snowball Earth: Glaciological and palaeogeographic insights from the Cryogenian Yuermeinak Formation of NW China[J]. Precambrian Research, 331: 105362.
[56]	Wang Y Z, Chen D Z, Liu M, et al. 2022. Ediacaran carbon cycling and Shuram excursion recorded in the Tarim Block, northwestern China[J]. Precambrian Research, 377: 106694.
[57]	Wu G H, Yang S, Liu W, et al. 2021. Switching from advancing to retreating subduction in the Neoproterozoic Tarim Craton, NW China: Implications for Rodinia breakup[J]. Geoscience Frontiers, 12(1): 161-171.
[58]	Xu B, Jian P, Zheng H F, et al. 2005. U–Pb zircon geochronology and geochemistry of Neoproterozoic volcanic rocks in the Tarim Block of Northwest China: Implications for the breakup of Rodinia supercontinent and Neoproterozoic glaciations[J]. Precambrian Research, 136(2): 107-123.
[59]	Xu B, Zou H B, Chen Y, et al. 2013. The Sugetbrak basalts from northwestern Tarim Block of northwest China: Geochronology, geochemistry and implications for Rodinia breakup and ice age in the Late Neoproterozoic[J]. Precambrian Research, 236: 214-226.
[60]	Zhang Y G, Yang T, Hohl S V, et al. 2020. Seawater carbon and strontium isotope variations through the Late Ediacaran to late Cambrian in the Tarim Basin[J]. Precambrian Research, 345: 105769.
[61]	Zhang Y Q, Chen D Z, Zhou X Q, et al. 2015. Depositional facies and stratal cyclicity of dolomites in the Lower Qiulitag Group (upper Cambrian) in northwestern Tarim Basin, NW China[J]. Facies, 61(1): 417.
[62]	Zhao G C, Wang Y J, Huang B C, et al. 2018. Geological reconstructions of the East Asian blocks: From the breakup of Rodinia to the assembly of Pangea[J]. Earth-Science Reviews, 186: 262-286.
[63]	Zhao P, He J Y, Deng C L, et al. 2021. Early Neoproterozoic (870-820 Ma) amalgamation of the Tarim Craton (northwestern China) and the final assembly of Rodinia[J]. Geology, 49(11): 1277-1282.
[64]	Zhu G Y, Wang T S, Xie Z Y, et al. 2015. Giant gas discovery in the Precambrian deeply buried reservoirs in the Sichuan Basin, China: Implications for gas exploration in old cratonic basins[J]. Precambrian Research, 262: 45-66.
[65]	Zhu W B, Zheng B H, Shu L S, et al. 2011. Neoproterozoic tectonic evolution of the Precambrian Aksu blueschist terrane, northwestern Tarim, China: Insights from LA-ICP-MS zircon U–Pb ages and geochemical data[J]. Precambrian Research, 185(3/4): 215-230.
[66]	Zhou X J, Liu W, Wu G H, et al. 2022. The latest Neoproterozoic basaltic and siliciclastic rocks and tectonic implications in the Tarim Craton, NW China[J]. Journal of Asian Earth Sciences, 232: 1-16.