Rethinking on the sedimentary system of terrestrial petroliferous basins: insights from distributive fluvial system

doi:10.7623/syxb202002001

Acta Petrolei Sinica ›› 2020, Vol. 41 ›› Issue (2): 127-153.DOI: 10.7623/syxb202002001

• Petroleum Exploration • Next Articles

Rethinking on the sedimentary system of terrestrial petroliferous basins: insights from distributive fluvial system

Zhang Changmin¹, Song Xinmin², Zhi Dongming³, Zhou Xinhuai⁴, Yin Taiju¹, Yin Yanshu¹, Zhu Rui¹, Feng Wenjie¹, Zhang Baojin¹

1. School of Geosciences, Yangtze University, Hubei Wuhan 430100, China;
2. PetroChina Research Institute of Petroleum Exploration and Development, Beijing 100083, China;
3. PetroChina Xinjiang Oilfield Company, Xinjiang Karamay 834000, China;
4. CNOOC China Ltd., Beijing 100089, China

Received:2019-04-18 Revised:2019-09-13 Online:2020-02-25 Published:2020-03-09

陆相含油气盆地沉积体系再思考:来自分支河流体系的启示

张昌民¹, 宋新民², 支东明³, 周心怀⁴, 尹太举¹, 尹艳树¹, 朱锐¹, 冯文杰¹, 张宝进¹

1. 长江大学地球科学学院湖北武汉 430100;
2. 中国石油勘探开发研究院北京 100083;
3. 中国石油新疆油田公司新疆克拉玛依 834000;
4. 中海石油(中国)有限公司北京 100089

通讯作者: 张昌民,男,1963年7月生,1984年获江汉石油学院学士学位,1993年获石油勘探开发科学研究院博士学位,现为长江大学地球科学学院教授,主要从事沉积学与石油地质学教学、科研工作。Email:zcm@yangtzeu.edu.cn
作者简介:张昌民,男,1963年7月生,1984年获江汉石油学院学士学位,1993年获石油勘探开发科学研究院博士学位,现为长江大学地球科学学院教授,主要从事沉积学与石油地质学教学、科研工作。Email:zcm@yangtzeu.edu.cn
基金资助:
国家自然科学基金面上项目（No.41772094）和国家科技重大专项（2016ZX05027-002-007）资助。

Abstract

Abstract:

In this paper, the fundamental characteristics of the distributive fluvial system (DFS) are briefly described, and the significance of DFS research in the sedimentology and oil and gas exploration within terrestrial petroliferous basins is analyzed and discussed. Rivers in the DFS enter the basin from a vertex and radiate into the sedimentary system. DFS includes the largest mega-fan, medium-sized fluvial fan and the smallest alluvial fan. DFSs occupy most of the sedimentary basins including the rift basins, the compressional basins, the strike-slip basins and the craton basins. The rivers on DFS are distributive, but not always active simultaneously. Downstream in the DFS, the scale of channels decreases and the grain size becomes finer, whereas the ratio of flood plains to channel deposits increases. The sedimentary model of the DFS share the similar shape with the alluvial fan, but their nature is signigicantly different. The slope and area of DFS is positively related to the slope and area of the draining basin. The concept of DFS is the product of the integration of terrestrial basin sedimentology (e.g., research in alluvial fan sedimentology, fluvial sedimentology, and terrigenous sedimentary systems) with modern computer and geo-information technology. DFS research can promote systematization of classification description of fan-shaped sedimentary systems, diversification of sedimentary microfacies, development of sedimentary model, refinement of interpretation of sedimentary process response, and quantification of source-sink system analysis. China's oil and gas resources are mainly terrigenous in origin. It is therefore of great significance to study DFS for perfecting the theoretical framework of terrigenous sedimentology and reservoir geology in China. The study of DFS enlightens us to rethink the distribution pattern of sedimentary systems, the fluvial depositional system, the lithofacies paleo-geographic pattern, and the potential of oil and gas exploration in terrestrial basins.

Key words: distributive fluvial system, terrestrial basin, oil and gas exploration, sedimentary system, sedimentary model, fluvial deposit, alluvial fan deposit

摘要：

通过分析分支河流体系的基本特征，对分支河流体系在陆相含油气沉积盆地沉积体系研究和油气勘探中的意义进行分析和讨论。分支河流体系是指河流从某一顶点开始进入盆地并呈放射状展布的沉积体系，包括最大规模的巨型扇、中等规模的河流扇以及小规模的冲积扇。分支河流体系广泛发育在拉张、挤压、走滑和克拉通盆地中，占据了沉积盆地大部分地区；河道呈分支状分布，但不一定同时都在活动；河道规模向下游逐渐减小，泛滥平原和河道所占面积之比不断增加，沉积物粒度逐渐变细。分支河流体系的沉积模式与冲积扇模式外形相似，但内容相差很大。河流流域盆地梯度和流域面积与分支河流体系的表面坡降和面积具有正相关性。分支河流体系是随着现代地球信息技术发展而提出的，也是冲积扇沉积学、河流沉积学和陆相沉积体系研究不断深入的结果，是陆相盆地沉积学与现代计算机和地理信息技术融合发展的结果。分支河流体系的研究促进了扇状沉积体系分类描述的系统化，促进了沉积微相和沉积模式的多样化，促进了沉积过程响应解释的精细化，促进了源汇体系分析的定量化。分支河流体系启发了对陆相盆地沉积体系展布模式、陆相沉积体系中河流沉积作用、陆相盆地岩相古地理格局以及陆相盆地油气勘探潜力的再思考。研究分支河流体系对完善中国陆相沉积储层地质理论体系具有重要意义。

关键词: 分支河流体系, 陆相盆地, 油气勘探, 沉积体系, 沉积模式, 河流沉积, 冲积扇沉积

CLC Number:

TE121

Zhang Changmin, Song Xinmin, Zhi Dongming, Zhou Xinhuai, Yin Taiju, Yin Yanshu, Zhu Rui, Feng Wenjie, Zhang Baojin. Rethinking on the sedimentary system of terrestrial petroliferous basins: insights from distributive fluvial system[J]. Acta Petrolei Sinica, 2020, 41(2): 127-153.

张昌民, 宋新民, 支东明, 周心怀, 尹太举, 尹艳树, 朱锐, 冯文杰, 张宝进. 陆相含油气盆地沉积体系再思考:来自分支河流体系的启示[J]. 石油学报, 2020, 41(2): 127-153.

References

[1] WEISSMANN G S,HARTLEY A J,NICHOLS G J,et al.Fluvial form in modern continental sedimentary basins:distributive fluvial systems[J].Geology,2010,38(1):39-42.
[2] HARTLEY A J,WEISSMANN G S,NICHOLS G J,et al.Fluvial form in modern continental sedimentary basins:distributive fluvial systems:reply[J].Geology,2010,38(12):e231.
[3] HARTLEY A J,WEISSMANN G S,NICHOLS G J,et al.Large distributive fluvial systems:characteristics,distribution,and controls on development[J].Journal of Sedimentary Research,2010,80(2):167-183.
[4] QUARTERO E M,LEIER A L,BENTLEY L R,et al.Basin-scale stratigraphic architecture and potential Paleocene distributive fluvial systems of the Cordilleran Foreland Basin,Alberta,Canada[J].Sedimentary Geology,2015,316:26-38.
[5] 张昌民,胡威,朱锐,等.分支河流体系的概念及其对油气勘探开发的意义[J].岩性油气藏,2017,29(3):1-9.
ZHANG Changmin,HU Wei,ZHU Rui,et al.Concept of distributive fluvial system and its significance to oil and gas exploration and development[J].Lithologic Reservoirs,2017,29(3):1-9.
[6] WEISSMANN G S,HARTLEY A J,NICHOLS G J,et al.Alluvial facies distributions in continental sedimentary basins-distributive fluvial systems[M]//DAVIDSON S,LELEU S,NORTH C.River To Rock Record:The Preservation Of Fluvial Sediments And Their Subsequent Interpretation.Tulsa:Society for Sedimentary Geology,2011:327-355.
[7] WEISSMANN G S,HARTLEY A J,SCUDERI L A,et al.Prograding distributive fluvial systems-geomorphic models and ancient examples[C]//DRIESE S G,NORDT L C.New Frontiers in Paleopedology and Terrestrial Paleoclimatology:Paleosols and Soil Surface Analog Systems.Tulsa:Society for Sedimentary Geology,2013:131-147.
[8] WEISSMANN G S,HARTLEY A J,SCUDERI L A,et al.Fluvial geomorphic elements in modern sedimentary basins and their potential preservation in the rock record:a review[J].Geomorphology,2015,250:187-219.
[9] HARTLEY A J,WEISSMANN G S,SCUDERI L.Controls on the apex location of large deltas[J].Journal of the Geological Society,2016,174:10-13.
[10] HARTLEY A J,WEISSMANN G S,BHATTACHARAYYA P,et al.Soil development on modern distributive fluvial systems:preliminary observations with implications for interpretation of paleosols in the rock record[M]//DRIESE S G,NORDTNEW L C.Frontiers in Paleopedology and Terrestrial Paleoclimatology:Paleosols and Soil Surface Analog Systems.Tulsa:Society for Sedimentary Geology,2013:149-158.
[11] DAVIDSON S K,HARTLEY A J.A quantitative approach to linking drainage area and distributive-fluvial-system area in modern and ancient endorheic basins[J].Journal of Sedimentary Research,2014,84(11):1005-1020.
[12] OWEN A,NICHOLS G J,HARTLEY A J,et al.Quantification of a distributive fluvial system:the salt wash DFS of the morrison formation,SW U.S.A[J].Journal of Sedimentary Research,2015,85(5):544-561.
[13] OWEN A,HARTLEY A J,WEISSMANN G S,et al.Uranium distribution as a proxy for basin-scale fluid flow in distributive fluvial systems[J].Journal of the Geological Society,2016,173(4):569-572.
[14] OWEN A,NICHOLS G J,HARTLEY A J,et al.Vertical trends within the prograding Salt Wash distributive fluvial system,SW United States[J].Basin Research,2017,29(1):64-80.
[15] SMITH G H S,BEST J L,ASHWORTH P J,et al.Fluvial form in modern continental sedimentary basins:distributive fluvial systems:comment[J].Geology,2010,38(12):e230.
[16] ASHWORTH P J,LEWIN J.How do big rivers come to be different?[J].Earth-Science Reviews,2012,114(1/2):84-107.
[17] FIELDING C R,ASHWORTH P J,BEST J L,et al.Tributary,distributary and other fluvial patterns:What really represents the norm in the continental rock record?[J].Sedimentary Geology,2012,261/262:15-32.
[18] HORTON B K,DECELLES P G.The modern foreland basin system adjacent to the Central Andes[J].Geology,1997,25(10):895-898.
[19] ASSINE M L.River avulsions on the Taquari megafan,Pantanal wetland,Brazil[J].Geomorphology,2005,70(3/4):357-371.
[20] BLAIR T C,MCPHERSON J G.Alluvial fans and their natural distinction from rivers based on morphology,hydraulic processes,sedimentary processes,and facies assemblages[J].Journal of Sedimentary Research,1994,25(10):895-898.
[21] HOOKE R L B.Processes on arid-region alluvial fans[J].The Journal of Geology,1967,75(4):438-460.
[22] SHU Li,FINLAYSON B.Flood management on the lower Yellow River:Hydrological and geomorphological perspectives[J].Sedimentary Geology,1993,85(1/4):285-296.
[23] LEOPOLD L B,WOLMAN M G.River channel patterns:braided,meandering and straight[R].Washington,D.C.:U.S.Government Printing Office.1957:282-B,85.
[24] SCHUMM S A.Evolution and response to the fluvial system,sedimentologic implications[M]//ETHRIDGE F G,FLORES R M.Models for Exploration:Society of Economic Palaeontologists and Mineralogists,1981:19-29.
[25] BATES R L,JACKSON J A.Dictionary of geological terms[M].Alexandria:American Geological Institute,1976.
[26] 刘宝珺.沉积岩石学[M].北京:地质出版社,1980.
LIU Baojun.Sedimentary petrology[M].Beijing:Geological Publishing House,1980.
[27] 冯增昭.沉积岩石学[M].2版.北京:石油工业出版社,1993.
FENG Zengzhao.Sedimentary petrology[M].2nd ed.Beijing:Petroleum Industry Press,1993.
[28] DREW F.Alluvial and lacustrine deposits and glacial records of the upper-indus basin[J].Quarterly Journal of the Geological Society,1873,29(1/2):441-471.
[29] 崔之久.初探沟谷泥石流及其扇形地的沉积类型、宏观特征与形成机制[J].沉积学报,1986,4(2):69-79.
CUI Zhijiu.Preliminary study on types,macroscopic characteristics and genesis-mechanism of debris flow deposit[J].Acta Sedimentologica Sinica,1986,4(2):69-79.
[30] 穆桂金.奎屯河山前扇形地的地质灾害分析[J].干旱区地理,1990,13(3):16-21.
MU Guijin.The geologic hazards and its controlment at the developing region of the alluvial fan of Kuitun River[J].Arid Land Geography,1990,13(3):16-21.
[31] 吕辉河,杜国云,吴恙,等.新疆准噶尔盆地西缘白杨河扇形地边缘沉积分析[J].鲁东大学学报:自然科学版,2013,29(1):71-74.
LV Huihe,DU Guoyun,WU Yang,et al.Sediment dynamic analysis on the fan edge of Baiyang River in the western of Junggar Basin,Xinjiang Province[J].Ludong University Journal:Natural Science Edition,2013,29(1):71-74.
[32] 崔鹏,王道杰,庄建琦.泥石流扇形地土地整治与利用[J].中国水土保持科学,2008(增刊1):6-11.
CUI Peng,WANG Daojie,ZHUANG Jianqi.Land exploitation and utilization on debris-flow fan[J].Science of Soil and Water Conservation,2008(S1):6-11.
[33] MUKERJI A B.Geomorphic patterns and processes in the terminal tract of inland streams in Sutlej-Yamuna plain[J].Journal of the Geological Society of India,1975,16:450-459.
[34] MUKERJI A B.Terminal fans of inland streams in Sutlej-Yamuna plain,India[J].Geomorphology, 1976,20(2):190-204
[35] PARKASH B,AWASTHI A K,GOHAIN K.Lithofacies of the Markanda terminal fan,Kurukshetra district,Haryana,India[M]//COLLINSON J D,LEWIN J.Modern and Ancient Fluvial Systems.Oxford,UK:Blackwell Publishing Ltd.,1983:337-344.
[36] 张金亮,俞惠隆.我国东部几个含油气盆地浅水湖泊砂体成因的认识[J].石油与天然气地质,1989,10(1):40-44.
ZHANG Jinliang,YU Huilong.Knowledge on genesis of shallow lacustrine sandbodies from hydrocarbon-bearing basins in east China[J].Oil & Gas Geology,1989,10(1):40-44.
[37] KELLY S B,OLSEN H.Terminal fans-a review with reference to devonian examples[J].Sedimentary Geology,1993,85(1/4):339-374.
[38] CAIN S A,MOUNTNEY N P.Spatial and temporal evolution of a terminal fluvial fan system:the Permian Organ Rock Formation,South -east Utah,USA[J].Sedimentology,2009,56(6):1774-1800.
[39] GALLOWAY W E,HOBDAY D K.Terrigenous clastic depositional systems:applications to petroleum,coal,and uranium exploration[J].Berlin:Springer-Verlag,1983.
[40] GALLOWAY W E,HOBDAY D K.Terrigenous clastic depositional systems:applications to fossil fuel and groundwater resources[M].2nd ed.New York:Springer-Verlag,1996.
[41] STANISTREET I G,MCCARTHY T S.The Okavango fan and the classification of subaerial fan systems[J].Sedimentary Geology,1993,85(1/4):115-133.
[42] LEIER A L,DECELLES P G,PELLETIER J D.Mountains,monsoons,and megafans[J].Geology,2005,33(4):289-292.
[43] DECELLES P G,CAVAZZA W.A comparison of fluvial megafans in the Cordilleran (Upper Cretaceous)and modern Himalayan foreland basin systems[J].GSA Bulletin,1999,111(9):1315-1334.
[44] FONTANA A,MOZZI P,MARCHETTI M.Alluvial fans and megafans along the southern side of the Alps[J].Sedimentary Geology,2014,301:150-171.
[45] TRENDELL A M,ATCHLEY S C,NORDT L C.Facies analysis of a probable large-fluvial-fan depositional system:the Upper Triassic Chinle Formation at petrified forest National Park,Arizona,U.S.A[J].Journal of Sedimentary Research,2013,83(10):873-895.
[46] SHUKLA U K,SINGH I B,SHARMA M,et al.A model of alluvial megafan sedimentation:Ganga Megafan[J].Sedimentary Geology,2001,144(3/4):243-262.
[47] GIBLING M R.Width and thickness of fluvial channel bodies and valley fills in the geological record:a literature compilation and classification[J].Journal of Sedimentary Research,2006,76(5):731-770.
[48] 张纪易.粗碎屑洪积扇的某些沉积特征和微相划分[J].沉积学报,1985,3(3):74-85.
ZHANG Jiyi.Some depositional characteristics and microfacies subdivision of coarse clastic alluvial fans[J].Acta Sedimentologica Sinica,1985,3(3):74-85.
[49] BLAIR T C,MCPHERSON J G.Alluvial fan processes and forms[M]//ABRAHAMS A D,PARSONS A J.Geomorphology of Desert Environments.Dordrecht:Springer,1994:354-402.
[50] NORTH C P,WARWICK G L.Fluvial fans:myths,misconceptions,and the end of the terminal-fan model[J].Journal of Sedimentary Research,2007,77(9):693-701.
[51] HAMPTON B A,HORTON B K.Sheetflow fluvial processes in a rapidly subsiding basin,Altiplano plateau,Bolivia[J].Sedimentology,2010,54(5):1121-1148.
[52] DAVIDSON S K,HARTLEY A J,WEISSMANN G S,et al.Geomorphic elements on modern distributive fluvial systems[J].Geomorphology,2013,180/181:82-95.
[53] FRIEND P F.Distinctive features of some ancient river systems[M]//MIALL A D.Fluvial Sedimentology.Calgary,AB,Canada,1977:531-542.
[54] STANISTREET I G,CAIRNCROSS B,MCCARTHY T S.Low sinuosity and meandering bedload rivers of the Okavango fan:channel confinement by vegetated levées without fine sediment[J].Sedimentary Geology,1993,85(1/4):135-156.
[55] HORTON B K,DECELLES P G.Modern and ancient fluvial megafans in the foreland basin system of the central Andes,southern Bolivia:implications for drainage network evolution in fold-thrust belts[J].Basin Research,2001,13(1):43-63.
[56] NICHOLS G J,FISHER J A,NASH D J,et al.Processes,facies and architecture of fluvial distributary system deposits[J].Sedimentary Geology,2007,195(1/2):75-90.
[57] CHAKRABORTY T,GHOSH P,et al.The geomorphology and sedimentology of the Tista megafan,Darjeeling Himalaya:implications for megafan building processes[J].Geomorphology,2010,115(3/4):252-266.
[58] RALPH T J,HESSE P P.Downstream hydrogeomorphic changes along the Macquarie River,southeastern Australia,leading to channel breakdown and floodplain wetlands[J].Geomorphology,2010,118(1/2):48-64.
[59] BULL W B.The alluvial-fan environment[J].Progress in Physical Geography,1977,1(2):222-270.
[60] BULL W B.Geomorphic Responses to Climatic Change[M].Oxford:Oxford University Press,1991:326.
[61] SCHUMM S A.The fluvial system[M].New York:John Wiley & Sons,1977:338.
[62] HARVEY A M.Alluvial fan dissection:relationships between morphology and sedimentation[J].Geological Society,London,Special Publications,1987,35(1):87-103.
[63] HARVEY A M.The role of alluvial fans in the mountain fluvial systems of southeast Spain:implications of climatic change[J].Earth Surface Processes and Landforms,1996,21(6):543-553.
[64] HARVEY A M.Differential effects of base-level,tectonic setting and climatic change on Quaternary alluvial fans in the northern Great Basin,Nevada,USA[J].Geological Society,London,Special Publications,2005,251(1):117-131.
[65] SCHUMM S A,MOSLEY M P,WEAVER W E.Experimental fluvial geomorphology[M].New York:John Wiley & Sons,1987:413.
[66] MCCARTHY T S,STANISTREET I G,CAIRNCROSS B,et al.Incremental aggradation on the Okavango Delta-fan,Botswana[J].Geomorphology,1988,1(3):267-278.
[67] MCCARTHY T S,ELLERY W N,STANISTREET I G.Avulsion mechanisms on the Okavango fan,Botswana:the control of a fluvial system by vegetation[J].Sedimentology,1992,39(5):779-795.
[68] ZANI H,ASSINE M L,MCGLUE M M.Remote sensing analysis of depositional landforms in alluvial settings:method development and application to the Taquari megafan,Pantanal (Brazil)[J].Geomorphology,2012,161/162:82-92.
[69] MACK G H,LEEDER M R,CAROTHERS-DURR M.Modern flood deposition,erosion,and fan-channel avulsion on the semiarid red canyon and palomas canyon alluvial fans in the southern Rio grande rift,New Mexico,U.S.A.[J].Journal of Sedimentary Research,2008,78(7):432-442.
[70] CHAKRABORTY T,KAR R,GHOSH P,et al.Kosi megafan:historical records,geomorphology and the recent avulsion of the Kosi River[J]. Quaternary International,2010,227(2):143-160.
[71] BRYANT M,FALK P,PAOLA C.Experimental study of avulsion frequency and rate of deposition[J].Geology,1995,23(4):365-368.
[72] ASSINE M L,SILVA A.Contrasting fluvial styles of the Paraguay River in the northwestern border of the Pantanal wetland,Brazil[J].Geomorphology,2009,113(3/4):189-199.
[73] BUEHLER H A,WEISSMANN G S,SCUDERI L A,et al.Spatial and temporal evolution of an avulsion on the Taquari River distributive fluvial system from satellite image analysis[J].Journal of Sedimentary Research,2011,81(8):630-640.
[74] ASSINE M L,CORRADINI F A,PUPIM F D N,et al.Channel arrangements and depositional styles in the São Lourenço fluvial megafan,Brazilian Pantanal wetland[J].Sedimentary Geology,2014,301:172-184.
[75] JEROLMACK D J,PAOLA C.Complexity in a cellular model of river avulsion[J].Geomorphology,2007,91(3/4):259-270.
[76] 朱红涛,徐长贵,朱筱敏,等.陆相盆地源-汇系统要素耦合研究进展[J].地球科学,2017,42(11):1851-1870.
ZHU Hongtao,XU Changgui,ZHU Xiaomin,et al.Advances of the source-to-sink units and coupling model research in continental basin[J].Journal of Earth Science, 2017,42(11):1851-1870.
[77] 徐长贵,杜晓峰,徐伟,等.沉积盆地"源-汇"系统研究新进展[J].石油与天然气地质,2017,38(1):1-11.
XU Changgui,DU Xiaofeng,XU Wei,et al.New advances of the "source-to-sink" system research in sedimentary basin[J].Oil & Gas Geology,2017,38(1):1-11.
[78] 林畅松,夏庆龙,施和生,等.地貌演化、源-汇过程与盆地分析[J].地学前缘,2015,22(1):9-20.
LIN Changsong,XIA Qinglong,SHI Hesheng,et al.Geomorphological evolution,source to sink system and basin analysis[J].Earth Science Frontiers,2015,22(1):9-20.
[79] 李新坡,莫多闻,朱忠礼.祁连山、贺兰山与吕梁山山前冲积扇上的农地对比[J].地理研究,2006,25(6):985-993.
LI Xinpo,MO Duowen,ZHU Zhongli.Comparison between agricultural land on alluvial fans at Qilian Mountain,Helan Mountain and Lvliang Mountain regions[J].Geographical Research,2006,25(6):985-993.
[80] 李新坡,莫多闻,朱忠礼.侯马盆地冲积扇及其流域地貌发育规律[J].地理学报,2006,61(3):241-248.
LI Xinpo,MO Duowen,ZHU Zhongli.Developments of alluvial fans and their catchments in Houma Basin[J].Acta Geographica Sinica,2006,61(3):241-248.
[81] PAOLA C.Quantitative models of sedimentary basin filling[J].Sedimentology,2010,47(S1):121-178.
[82] SØMME T O,HELLAND-HANSEN W,MARTINSEN O J,et al.Relationships between morphological and sedimentological parameters in source-to-sink systems:a basis for predicting semi-quantitative characteristics in subsurface systems[J].Basin Research,2010,21(4):361-387.
[83] 贾承造,邹才能,杨智,等.陆相油气地质理论在中国中西部盆地的重大进展[J].石油勘探与开发,2018,45(4):546-560.
JIA Chengzao,ZOU Caineng,YANG Zhi,et al.Significant progress of continental petroleum geology theory in basins of central and western China[J].Petroleum Exploration and Development,2018,45(4):546-560.
[84] 吴崇筠.中国含油气盆地沉积学[M].北京:石油工业出版社,1992.
WU Chongyun.Sedimentary geology of petroliferous basins in China[M].Beijing:Petroleum Industry Press,1992.
[85] BLAIR T C,MCPHERSON J G.Processes and forms of alluvial fans[M]//PARSONS A J,ABRAHAMS A D.Geomorphology of desert environments.Dordrecht:Springer,2009:413-467.
[86] 李应暹.辽河裂谷渐新世初期的扇三角洲[J].石油勘探与开发,1982(4):17-23.
LI Yingxian.Early Oligocene fan-deltas in Liaohe rift[J].Petroleum Expoloration and Development,1982(4):17-23.
[87] 王夏斌.辽河西部凹陷古近系沙四上亚段沉积相研究[D].北京:中国地质大学,2017.
WANG Xiabin.Sedimentary facies of the Upper Member of the Shahejie Formation in the Paleogene in the western sag of Liaohe Basin[D].Beijing:China University of Geosciences,2017.
[88] 于兴河,张道建,郜建军,等.辽河油田东、西部凹陷深层沙河街组沉积相模式[J].古地理学报,1999,1(3):40-49.
YU Xinghe,ZHANG Daojian,GAO Jianjun,et al.Depositional facies and models of deep burial strata of the Shahejie Formation in the eastern and western depressions of Liaohe Oilfield[J].Journal of Palaeogeography,1999,1(3):40-49.
[89] 郑浚茂,王德发,孙永传.东濮断陷盐湖盆地下第三系砂体类型及沉积模式[J].沉积学报,1984,2(2):17-28.
ZHENG Junmao,WANG Defa,SUN Yongchuan.Lower Tertiary sandbody types and depositional model of Dongpu faulted salt lake basin[J]. Acta Sedimentologica Sinica,1984,2(2):17-28.
[90] 朱筱敏,刘泽容,信荃麟.东濮凹陷黄河南地区东营组沉积相研究[J].中国石油大学学报:自然科学版,1990,14(4):1-10.
ZHU Xiaomin,LIU Zerong,XIN Quanlin.Study on the sedimentary facies of Dongying Formation of Tertiary in Dongpu depression[J].Journal of China University of Petroleum:Edition of Natural Science,1990,14(4):1-10.
[91] 尹楠鑫,李存贵,贾云超,等.东濮凹陷马寨油田卫95块扇三角洲沉积特征及沉积模式[J].东北石油大学学报,2015,39(6):20-29.
YIN Nanxin,LI Cungui,JIA Yunchao,et al.Sedimentary characteristics and sedimentary model of Wei95 block in Mazhai oilfield,Dongpu depression[J].Journal of Northeast Petroleum University,2015,39(6):20-29.
[92] 王寿庆.双河扇三角洲沉积相及其模式[J].新疆石油地质,1986,7(3):22-30.
WANG Shouqing.Sedimentary facies of Shuanghefan delta and its model[J].Xinjiang Petroleum Geology,1986,7(3):22-30.
[93] 胡受权,陈国能.南襄盆地泌阳断陷下第三系陆相层序地层[J].地球学报,1999,20(2):207-214.
HU Shouquan,CHEN Guoneng.Terrigenous sequence analysis on Early Tertiary in Biyang fault-depression of Nanxiang Basin[J].Acta Geoscientica Sinica,2009,20(2):207-214.
[94] 张昌民,尹太举,张尚锋,等.再论双河油田扇三角洲沉积模式[J].江汉石油学院学报,2004,26(1):1-4.
ZHANG Changmin,YIN Taiju,ZHANG Shangfeng,et al.Fan delta depositional modes in Shuanghe oilfield[J].Journal of Jianghan Petroleum Institute,2004,26(1):1-4.
[95] 张昌民,尹太举,张尚锋,等.双河油田陆架型扇三角洲的沉积机理及向上变粗层序的成因[J].石油与天然气地质,2005,26(1):99-103.
ZHANG Changmin,YIN Taiju,ZHANG Shangfeng,et al.Sedimentary mechanism of shelf-type fan delta and genesis of coarsening-upward sequence in Shuanghe oilfield[J].Oil & Gas Geology,2005,26(1):99-103.
[96] 张惠良,沈扬,张荣虎,等.塔里木盆地西南部昆仑山前下白垩统沉积相特征及石油地质意义[J].古地理学报,2005,7(2):157-168.
ZHANG Huiliang,SHEN Yang,ZHANG Ronghu,et al.Characteristics of sedimentary facies and petroleum geological significance of the Lower Cretaceous in front of Kunlun Mountains in southwestern Tarim Basin[J].Journal of Palaeogeography,2005,7(2):157-168.
[97] 李健,王德仁,白兴盈.东濮凹陷沙三3-4亚段层序地层与沉积体系分析[J].石油与天然气地质,2001,22(2):161-164.
LI Jian,WANG Deren,BAI Xingying.Depositional system and sequence stratigraphy of S33-4 submember in Dongpu depression[J].Oil & Gas Geology,2001,22(2):161-164.
[98] GEDDES A.The alluvial morphology of the indo-gangetic plain:its mapping and geographical significance[J].Transactions and Papers,1960,28:253-276.
[99] SINHA R,FRIEND P F.River systems and their sediment flux,Indo-Gangetic plains,Northern Bihar,India[J].Sedimentology,1994,41(4):825-845.
[100] SINHA R.Channel avulsion and floodplain structure in the Gandak-Kosi interfan,North Bihar plains,India[J].Zeitschrift fur Geomorphol, 1996,103:249-268.
[101] SINGH I B.The Ganga river[M]//GUPTA A.Large Rivers:Geomorphology and Management.Chichester:John Wiley & Sons,Ltd.,2007:347-371.
[102] SINGH S K.Erosion and weathering in the Brahmaputra river system[M]//GUPTA A.Large Rivers:Geomorphology and Management.Chichester:John Wiley & Sons,Ltd,2007.
[103] SINGH H,PARKASH B,GOHAIN K.Facies analysis of the Kosi megafan deposits[J].Sedimentary Geology,1993,85(1/4):87-113.
[104] 张昌民,刘江艳,潘进,等.玛湖凹陷百口泉组砂砾岩建筑结构要素层次分析[J].新疆石油地质,2018,39(1):23-34.
ZHANG Changmin,LIU Jiangyan,PAN Jin,et al.Hierarchical architectural element analysis for sandy conglomerate deposits of Baikouquan Formation,Mahu sag[J].Xinjiang Petroleum Geology,2018,39(1):23-34.
[105] 任宇泽,林畅松,高志勇,等.塔里木盆地西南坳陷白垩系层序地层与沉积充填演化[J].天然气地球科学,2017,28(9):1298-1311.
REN Yuze,LIN Changsong,GAO Zhiyong,et al.Sequence stratigraphy and sedimentary filling evolution of the Cretaceous in southwest depression,Tarim Basin[J].Natural Gas Earth Science Frontiers,2017,28(9):1298-1311.
[106] 岳勇,徐勤琪,傅恒,等.塔里木盆地西南部白垩系-古近系沉积特征与储盖组合[J].石油实验地质,2017,39(3):318-326.
YUE Yong,XU Qinqi,FU Heng,et al.Reservoir-cap rock assemblage and sedimentary characteristics of Cretaceous-Paleogene in southwestern Tarim Basin[J].Petroleum Geology & Experiment,2017,39(3):318-326.
[107] 吴林,管树巍,杨海军,等.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,2017,38(4):375-385.
WU Lin,GUAN Shuwei,YANG Haijun,et al.The paleogeographic framework and hydrocarbon exploration potential of Neoproterozoic rift basin in northern Tarim Basin[J].Acta Petrolei Sinica,2017,38(4):375-385.
[108] 贾进华,申银民.塔里木盆地东河砂岩段准层序组特征及岩相古地理与砂体分布[J].石油学报,2017,38(2):135-149.
JIA Jinhua,SHEN Yinmin.Parasequence set division,lithofacies paleogeography and sandbody distribution of Donghe sandstone member in Tarim Basin[J].Acta Petrolei Sinica,2017,38(2):135-149.
[109] 石开波,刘波,田景春,等.塔里木盆地震旦纪沉积特征及岩相古地理[J].石油学报,2016,37(11):1343-1360.
SHI Kaibo,LIU Bo,TIAN Jingchun,et al.Sedimentary characteristics and lithofacies paleogeography of Sinian in Tarim Basin[J].Acta Petrolei Sinica,2016,37(11):1343-1360.
[110] 高志勇,周川闽,冯佳睿,等.库车坳陷白垩系巴什基奇克组泥砾的成因机制与厚层状砂体展布[J].石油学报,2016,37(8):996-1010.
GAO Zhiyong,ZHOU Chuanmin,FENG Jiarui,et al.Mechanism and sedimentary environment of the muddy gravel concomitant with thick layer sandstone of Cretaceous in Kuqa depression[J].Acta Petrolei Sinica,2016,37(8):996-1010.
[111] 唐勇,徐洋,瞿建华,等.玛湖凹陷百口泉组扇三角洲群特征及分布[J].新疆石油地质,2014,35(6):628-635.
TANG Yong,XU Yang,QU Jianhua,et al.Fan-delta group characteristics and its distribution of the triassic baikouquan reservoirs in Mahu sag of Junggar Basin[J].Xinjiang Petroleum Geology,2014,35(6):628-635.
[112] 李学良,张奎华,林会喜,等.哈山及周缘二叠系风城组沉积环境及沉积相发育特征[J].西北大学学报:自然科学版,2018,48(5):76-85.
LI Xueliang,ZHANG Kuihua,LIN Huixi,et al.Sedimentary environment and facies of Permian Fengcheng Formation in Hashan and its adjacent areas[J].Journal of Northwest University:Natural Science,2018,48(5):76-85.
[113] 邱争科,王辉,李婷,等.准噶尔盆地八道湾组湿地扇三角洲沉积特征[J].西南石油大学学报:自然科学版,2018,40(5):47-58.
QIU Zhengke,WANG Hui,LI Ting,et al.Humid fan-delta sedimentation characteristics in the Badaowan Formation in the Northwestern Junggar Basin[J].Journal of Southwest Petroleum University:Science & Technology Edition,2018,40(5):47-58.
[114] 秦国省,胡文瑞,宋新民,等.砾质辫状河构型及隔夹层分布特征——以准噶尔盆地西北缘八道湾组露头为例[J].中国矿业大学学报,2018,47(5):1008-1020.
QIN Guosheng,HU Wenrui,SONG Xinmin,et al.Gravel braided river architecture and inter-layers distribution:a case study of Jurassic Badaowan Formation outcrop in the northwest of Junggar Basin[J].Journal of China University of Mining & Technology,2018,47(5):1008-1020.
[115] 王越,陈世悦,张关龙,等.咸化湖盆混积岩分类与混积相带沉积相特征——以准噶尔盆地南缘芦草沟组与吐哈盆地西北缘塔尔朗组为例[J].石油学报,2017,38(9):1021-1035.
WANG Yue,CHEN Shiyue,ZHANG Guanlong,et al.Classifications of mixosedimentite and sedimentary facies characteristics of mixed sedimentary facies belt in saline lacustrine basin:taking examples as the Lucaogou Formation in the south of Junggar Basin and the Taerlang Formation in the northwest of Tuha Basin[J].Acta Petrolei Sinica,2017,38(9):1021-1035.
[116] 陈轩,杨振峰,王振奇,等.大型斜坡区冲积-河流体系沉积特征与岩性油气藏形成条件——以准噶尔盆地春光区块沙湾组为例[J].石油学报,2016,37(9):1090-1101.
CHEN Xuan,YANG Zhenfeng,WANG Zhenqi,et al.Sedimentary characteristics of alluvial-fluvial systems and forming conditions of lithologic reservoirs in the large slope area:a case study of Neogene Shawan Formation in Chunguang block,Junggar Basin[J].Acta Petrolei Sinica,2016,37(9):1090-1101.
[117] 宫清顺,刘占国,宋光永,等.柴达木盆地昆北油田冲积扇厚层砂砾岩储集层内部隔夹层[J].石油学报,2019,40(2):152-164.
GONG Qingshun,LIU Zhanguo,SONG Guangyong,et al.Inter-layers in alluvial-fan thick sandy conglomerate reservoir of Kunbei oilfield,Qaidam Basin[J].Acta Petrolei Sinica,2019,40(2):152-164.
[118] 付锁堂,马达德,陈琰,等.柴达木盆地油气勘探新进展[J].石油学报,2016,37(增刊1):1-10.
FU Suotang,MA Dade,CHEN Yan,et al.New advance of petroleum and gas exploration in Qaidam Basin[J].Acta Petrolei Sinica,2016,37(S1):1-10.
[119] 黄成刚,常海燕,崔俊,等.柴达木盆地西部地区渐新世沉积特征与油气成藏模式[J].石油学报,2017,38(11):1230-1243.
HUANG Chenggang,CHANG Haiyan,CUI Jun,et al.Oligocene sedimentary characteristics and hydrocarbon accumulation model in the western Q aidam Basin[J].Acta Petrolei Sinica,2017,38(11):1230-1243.
[120] 夏志远,刘占国,李森明,等.岩盐成因与发育模式——以柴达木盆地英西地区古近系下干柴沟组为例[J].石油学报,2017,38(1):55-66.
XIA Zhiyuan,LIU Zhanguo,LI Senming,et al.Origin and developing model of rock salt:a case study of Lower Ganchaigou Formation of Paleogene in the west of Yingxiong ridge,Qaidam Basin[J].Acta Petrolei Sinica,2017,38(1):55-66.
[121] 钱涛,王宗秀,柳永清,等.柴达木盆地北缘侏罗纪沉积物源分析:地层序列及LA-ICP-MS年代学信息[J].中国科学:地球科学,2018,48(2):224-242.
QIAN Tao,WANG Zongxiu,LIU Yongqing,et al.Provenance analysis of the Jurassic northern Qaidam Basin:stratigraphic succession and LA-ICP-MS geochronology[J].Chinese Science:Earth Science,2018,48(2):224-242.
[122] 刘欣,朱世发,杜建军,等.柴北缘西段侏罗系沉积特征[J].古地理学报,2017,19(4):595-608.
LIU Xin,ZHU Shifa,DU Jianjun,et al.Sedimentary characteristics of the Jurassic in western north margin of Qaidam Basin[J].Journal of Palaeogeography,2017,19(4):595-608.
[123] 罗启后.再论水进型三角洲——兼论四川盆地须家河组巨厚砂层成因[J].沉积学报,2015,33(5):845-854.
LUO Qihou.Further discussion on water-transgression delta:genesis of great thickness large distributed sandstone of Xujiahe Formation in Sichuan Basin[J].Acta Sedimentologica Sinica,2015,33(5):845-854.
[124] 柳妮,陈洪德,林良彪,等.四川盆地须家河组第四段湖泊三角洲沉积差异[J].成都理工大学学报:自然科学版,2014(5):625-632.
LIU Ni,CHEN Hongde,LIN Liangbiao,et al.Sedimentary differences of lacus deltas in Member 4 of Upper Triassic Xujiahe Formation in Sichuan Basin,China[J].Journal of Chengdu University of Technology:Science & Technology Edition,2014(5):625-632.
[125] 梅冥相,刘少峰.基于陆生植被对河流沉积作用的影响论上三叠统须家河组的冲积构架:以重庆永川普安剖面为例[J].古地理学报,2013,15(2):143-154.
MEI Mingxiang,LIU Shaofeng.Discussion of alluvial architecture for the Upper Triassic Xujiahe Formation in terms of sedimentological impact of terrestrial vegetation on fluvial sedimentation:a case study at Pu'an section in Yongchuan of Chongqing[J].Journal of Palaeogeography,2013,15(2):143-154.
[126] 徐兆辉,胡素云,汪泽成,等.古气候恢复及其对沉积的控制作用——以四川盆地上三叠统须家河组为例[J].沉积学报,2011,29(2):235-244.
XU Zhaohui,HU Suyun,WANG Zecheng,et al.Restoration of paleoclimate and its geological significance:as an example from Upper Triassic Xujiahe Formation in Sichuan Basin[J].Acta Sedimentologica Sinica,2011,29(2):235-244.
[127] 付金华,李士祥,徐黎明,等.鄂尔多斯盆地三叠系延长组长7段古沉积环境恢复及意义[J].石油勘探与开发,2018,45(6):18-28.
FU Jinhua,LI Shixiang,XU Liming,et al.Paleo-sedimentary environmental restoration and its significance of Chang 7 Member of Triassic Yanchang Formation in Ordos Basin,NW China[J].Petroleum Exploration and Development,2018,45(6):18-28.
[128] 肖红平,刘锐娥,张福东,等.鄂尔多斯盆地二叠系盒8段沉积模式重建及其勘探意义[J].石油勘探与开发,2019,46(2):268-280.
XIAO Hongping,LIU Rui'e,ZHANG Fudong,et al.Sedimentary model reconstruction and exploration significance of Permian He 8 Member in Ordos Basin,NW China[J].Petroleum Exploration and Development,2019,46(2):268-280.
[129] 尹泽,刘自亮,彭楠,等.鄂尔多斯盆地西缘上三叠统延长组沉积相特征研究[J].沉积学报,2019,37(1):163-176.
YIN Ze,LIU Ziliang,PENG Nan,et al.Study on sedimentary faciess features of the Upper Triassic Yanchang Formation,in the Western Margin,Ordos Basin[J].Acta Sedimentologica Sinica,2019,37(1):163-176.
[130] 郭艳琴,惠磊,张秀能,等.鄂尔多斯盆地三叠系延长组沉积体系特征及湖盆演化[J].西北大学学报:自然科学版,2018,48(4):593-602.
GUO Yanqin,HUI Lei,ZHANG Xiuneng,et al.Sedimentary system characteristics and lake basin evolution of Triassic Yanchang Formation in Ordos Basin[J].Journal of Northwest University:Natural Science,2018,48(4):593-602.
[131] 刘家铎,王峻,王易斌,等.塔里木盆地喀什北地区白垩系层序岩相古地理特征[J].地球科学与环境学报,2013,35(1):1-14.
LIU Jiaduo,WANG Jun,WANG Yibin,et al.Sequence-lithology palaeogeography charateristic of cretaceous in northern Kashi area of Tarim Basin[J].Journal of Earth Sciences and Environment,2013,35(1):1-14.
[132] 谢俊,张金亮,梁会珍,等.塔里木盆地志留系柯坪塔格组沉积相与沉积模式研究[J].西安石油大学学报:自然科学版,2008,23(2):1-5.
XIE Jun,ZHANG Jinliang,LIANG Huizhen,et al.Study on the sedimentary facies and sedimentary modes of Kepingtage Formation of the Silurian in Tarim Basin[J].Journal of Xi'an Shiyou University:Naturnal Science Edition,2008,23(2):1-5.
[133] 郭艳琴,余芳,李洋,等.鄂尔多斯盆地东部盒8致密砂岩沉积特征及沉积模式[J].地质通报,2015,34(10):1971-1980.
GUO Yanqin,YU Fang,LI Yang,et al.Sedimentary characteristics and model of the tight sand of He 8 Formation in eastern Ordos Basin[J].Geological Bulletin of China,2015,34(10):1971-1980.
[134] 朱筱敏,刘媛,方庆,等.大型坳陷湖盆浅水三角洲形成条件和沉积模式:以松辽盆地三肇凹陷扶余油层为例[J].地学前缘,2012,19(1):89-99.
ZHU Xiaomin,LIU Yuan,FANG Qing,et al.Formation and sedimentary model of shallow delta in large-scale lake.example from Cretaceous Quantou Formation in Sanzhao sag,Songliao Basin[J].Earth Science Frontiers,2012,19(1):89-99.
[135] 徐振华,吴胜和,刘钊,等.浅水三角洲前缘指状砂坝构型特征——以渤海湾盆地渤海BZ25油田新近系明化镇组下段为例[J].石油勘探与开发,2019,46(2):322-333.
XU Zhenhua,WU Shenghe,LIU Zhao,et al.Sandbody architecture of the bar finger within shoal water delta front:Insights from the Lower Member of Minghuazhen Formation,Neogene,Bohai BZ25 oilfield,Bohai Bay Basin,East China[J].Petroleum Exploration and Development,2019,46(2):322-333.
[136] 杨帆,曹正林,卫延召,等.玛湖地区三叠系克拉玛依组浅水辫状河三角洲沉积特征[J].岩性油气藏,2019,31(1):30-39.
YANG Fan,CAO Zhenglin,WEI Yanzhao,et al.Sedimentary characteristics of shallow-water braided delta of Karamay Formation in Mahu area[J].Lithologic Reservoirs,2019,31(1):30-39.
[137] 李维,朱筱敏,马英俊,等.陆相断陷湖盆浅水三角洲沉积特征——以高邮凹陷刘五舍次凹戴南组一段为例[J].石油实验地质,2018,40(5):676-683.
LI Wei,ZHU Xiaomin,MA Yingjun,et al.Depositional characteristics of a shallow-water delta in a continental faulted basin:a case study of the first Member of Dainan Formation,Liuwushe subsag,Gaoyou sag,North Jiangsu Basin[J].Petroleum Geology,2018,40(5):676-683.
[138] 刘君龙,孙冬胜,纪友亮,等.川西地区晚侏罗世浅水三角洲沉积特征及主控因素[J].新疆石油地质,2018,39(4):393-400.
LIU Junlong,SUN Dongsheng,JI Youliang,et al.Sedimentary characteristics and its main controlling factors of the Late Jurassic shallow-water delta in western Sichuan depression[J].Xinjiang Petroleum Geology,2018,39(4):393-400.
[139] 张莉,鲍志东,林艳波,等.浅水三角洲砂体类型及沉积模式——以松辽盆地南部乾安地区白垩系姚家组一段为例[J].石油勘探与开发,2017,44(5):727-736.
ZHANG Li,BAO Zhidong,LIN Yanbo,et al.Genetic types and sedimentary model of sandbodies in a shallow-water delta:a case study of the first Member of Cretaceous Yaojia Formation in Qian'an area,south of Songliao Basin,NE China[J].Petroleum Exploration and Development,2017,44(5):727-736.
[140] 楼章华,兰翔,卢庆梅,等.地形、气候与湖面波动对浅水三角洲沉积环境的控制作用——以松辽盆地北部东区葡萄花油层为例[J].地质学报,1999,73(1):83-92.
LOU Zhanghua,LAN Xiang,LU Qingmei,et al.Controls of the topography,climate and lake level fluctuation on the depositional environment of a shallow-water delta-a case study of the Cretaceous Putaohua reservoir in the northern part of Songliao Basin[J].Acta Geologica Sinica,1999,73(1):83-92.
[141] 朱伟林,李建平,周心怀,等.渤海新近系浅水三角洲沉积体系与大型油气田勘探[J].沉积学报,2008,26(4):575-582.
ZHU Weilin,LI Jianping,ZHOU Xinhuai,et al.Neogene shallow water deltaic system and large hydrocarbon accumulations in Bohai Bay,China[J].Acta Sedimentologica Sinica,2008,26(4):575-582.
[142] 邹才能,赵文智,张兴阳,等.大型敞流坳陷湖盆浅水三角洲与湖盆中心砂体的形成与分布[J].地质学报,2008,82(6):813-825.
ZOU Caineng,ZHAO Wenzhi,ZHANG Xingyang,et al.Formation and distribution of shallow-water deltas and central-basin sandbodies in large open depression lake basins[J].Acta Geologica Sinica,2008,82(6):813-825.
[143] 张昌民,尹太举,朱永进,等.浅水三角洲沉积模式[J].沉积学报,2010,28(5):933-944.
ZHANG Changmin,YIN Taiju,ZHU Yongjin,et al.Shallow-water deltas and models[J].Acta Sedimentologica Sinica,2010,28(5):933-944.
[144] 尹太举,李宣玥,张昌民,等.现代浅水湖盆三角洲沉积砂体形态特征——以洞庭湖和鄱阳湖为例[J].石油天然气学报,2012,34(10):1-7.
YIN Taiju,LI Xuanyue,ZHANG Changmin,et al.Sandbody shape of modern shallow lake basin delta sediments-by taking Dongting Lake and Poyang Lake for example[J].Journal of Oil and Gas Technology,2012,34(10):1-7.
[145] 高志勇,周川闽,董文彤,等.浅水三角洲动态生长过程模型与有利砂体分布——以鄱阳湖赣江三角洲为例[J].现代地质,2016,30(2):341-352.
GAO Zhiyong,ZHOU Chuanmin,DONG Wentong,et al.Sedimentary processes,depositional model and sandbody prediction of lacustrine shallow water delta:a case study of Ganjiang river delta in Poyang Lake[J].Geoscience,2016,30(2):341-352.
[146] 叶蕾,朱筱敏,秦祎,等.断陷湖盆浅水三角洲沉积体系[J].地球科学与环境学报,2018,40(2):186-202.
YE Lei,ZHU Xiaomin,QIN Yi,et al.Depositional system of shallow water delta in rifted lacustrine basin[J].Journal of Earth Sciences and Environment,2018,40(2):186-202.
[147] 王文涛,闫百泉,孙力.浅水湖盆三角洲沉积特征及模式研究[J].能源与环保,2017,39(9):115-119.
WANG Wentao,YAN Baiquan,SUN Li.Study on sedimentary characteristics and model in shallow-water delta[J].China Energy and Environmental Protection,2017,39(9):115-119.
[148] 孙靖,薛晶晶,吴海生,等.远源、细粒型浅水三角洲沉积特征与演化——以准噶尔盆地腹部莫索湾地区八道湾组为例[J].沉积学报,2016,34(1):129-136.
SUN Jing,XUE Jingjing,WU Haisheng,et al.Distal fine-grain shallow-water delta sedimentary characteristics and evolution:a case from Badaowan Formation in the central Junggar Basin[J].Acta Sedimentologica Sinica,2016,34(1):129-136.
[149] 胡忠贵,胡明毅,胡九珍,等.潜江凹陷东部地区新沟咀组下段浅水三角洲沉积模式[J].中国地质,2011,38(5):1263-1273.
HU Zhonggui,HU Mingyi,HU Jiuzhen,et al.Shallow water delta depositional model of the lower segment of the Xingouzui Formation in eastern Qianjiang depression[J].Geology in China,2011,38(5):1263-1273.
[150] 赵宝峰,徐东浩,徐蒙,等.松辽盆地新立-新北地区嫩江组三段浅水三角洲水下分流河道砂体半定量解剖[J].沉积学报,2012,30(3):511-521.
ZHAO Baofeng,XU Donghao,XU Meng,et al.Semi-quantitative research on subaqueous distributary channel sandbodies of the 3th Member of Nenjiang Formation in Xinli-Xinbei area,Songliao Basin[J].Acta Sedimentologica Sinica,2012,30(3):511-521.
[151] 吴忱,赵明轩.太行山、燕山山前冲积扇的地貌特征与遥感信息[M]//吴忱.华北平原古河道研究论文集.北京:中国科学技术出版社,1991:499-511.
WU Chen,ZHAO Mingxuan.Geomorphic features and remote sensing information of the alluvial fan in the Taihang Mountains and Yanshan Mountains[M]//WU Chen.Collected Works on Palaeochannel in the North China Plain.Beijing:China Science and Technology Press,1991:499-511.
[152] 吴忱,赵明轩.拒马河下游河道变迁与地貌演变[J].地理学与国土研究,1993,9(4):42-47.
WU Chen,ZHAO Mingxuan.River channel changes and geomorphological evolution in the lower reaches of the Juma River[J].Geography and Territorial Research,1993,9(4):42-47.
[153] 吴忱.河北平原的地面古河道[J].地理学报,1984,39(3):268-276.
WU Chen.Surface ancient channels in Hebei Plain[J].Acta Geographica Sinica,1984,39(3):268-276.
[154] 吴忱,王子惠,许清海.河北平原的浅埋古河道[J].地理学报,1986,41(4):332-340.
WU Chen,WANG Zihui,XU Qinghai.The shallow burried paleo-channelsin Hebei Plain[J].Acta Geographica Sinica,1986,41(4):332-340.
[155] 吴忱,朱宣清,何乃华,等.华北平原古河道的形成研究[J].中国科学B辑,1991,21(2):188-197.
WU Chen,ZHU Xuanqing,HE Naihua,et al.Study on the formation of ancient river channels in North China plain[J].Chinese Science:Chemistry Life Science and Geology,1991,21(2):188-197.
[156] 吴忱,许清海,刘劲松.华北地貌新论[M].北京:科学出版社,2017:50-150.
WU Chen,XU Qinghai,LIU Jinsong.A new perspective on landforms in North China[M].Beijing:Science Press,2017:50-150.
[157] 马玉凤,李双权,潘星慧.黄河冲积扇发育研究述评[J].地理学报,2015,70(1):49-62.
MA Yufeng,LI Shuangquan,PAN Xinghui.A review on development of the Yellow River alluvial fan[J].Acta Geographica Sinica,2015,70(1):49-62.
[158] 叶青超,杨毅芬,张义丰.黄河冲积扇形成模式和下游河道演变[J].人民黄河,1982(4):32-37.
YE Qingchao,YANG Yifen,ZHANG Yifeng.Formation mode of the alluvial fan of the Yellow River and evolution of downstream rivers[J].Yellow River,1982(4):32-37.
[159] 石雨昕,高志勇,周川闽,等.新疆博斯腾湖北缘现代冲积扇与扇三角洲平原分支河流体系的沉积特征与意义[J].石油学报,2019,40(5):542-556.
SHI Yuxin,GAO Zhiyong,ZHOU Chuanmin,et al.Sedimentary characteristics and significance of distributive fluvial system of modern alluvial fan and fan delta plain in the northern margin of Bosten lake,Xinjiang[J].Acta Petrolei Sinica,2019,40(5):542-556.
[160] 付锁堂.柴达木盆地油气地质成藏条件研究[M].北京:科学出版社,2014.
FU Suotang.Research on oil and gas geological accumulation conditions in Qaidam Basin[M].Beijing:Science Press,2014.
[161] 张服民,简宗渝.黄骅盆地早第三纪沉积史与环境特征[J].石油与天然气地质,1981,2(2):57-73.
ZHANG Fumin,JIAN Zongyu.The sedimentation history and environmental characteristics of the early tertiary in Huanghua Basin[J].Oil & Gas Geology,1981,2(2):57-73.
[162] 蒲秀刚,赵贤正,李勇,等.黄骅坳陷新近系古河道恢复及油气地质意义[J].石油学报,2018,39(2):163-171.
PU Xiugang,ZHAO Xianzheng,LI Yong,et al.Paleochannel restoration and petroleum geological significance of Neogene in Huanghua depression[J].Acta Petrolei Sinica,2018,39(2):163-171.
[163] 李勇.河流相层序地层学:以黄骅坳陷新近系为例[M].北京:科学出版社,2014.
LI Yong.River sequence sequence stratigraphy:taking the Neogene in the Huanghua depression as an example[M].Beijing:Science Press,2014.
[164] GOHAIN K,PARKASH B.Morphology of the Kosi megafan[M]//RACHOKI A H,CHURCH M.Alluvial Fans:A Field Approach.Chichester,U.K.:John Wiley,1990:151-178.
[165] 唐勇,徐洋,李亚哲,等.玛湖凹陷大型浅水退覆式扇三角洲沉积模式及勘探意义[J].新疆石油地质,2018,39(1):16-22.
TANG Yong,XU Yang,LI Yazhe,et al.Sedimentation model and exploration significance of large-scaled shallow retrogradation fan delta in Mahu sag[J].Xinjiang Petroleum Geology,2018,39(1):16-22.
[166] 杜金虎,支东明,唐勇,等.准噶尔盆地上二叠统风险领域分析与沙湾凹陷战略发现[J].中国石油勘探,2019,41(1):24-35.
DU Jinhu,ZHI Dongming,TANG Yong,et al.Prospects in Upper Permian and strategic discovery in Shawan sag,Junggar Basin[J].China Petroleum Exploration,2019,41(1):24-35.

Rethinking on the sedimentary system of terrestrial petroliferous basins: insights from distributive fluvial system

陆相含油气盆地沉积体系再思考:来自分支河流体系的启示

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