苏里格气田上古生界气藏主力含气层段有效储集砂体展布规律研究
|
摘要
本论文运用沉积学、高分辨率层序地层学、储层地质学、矿物岩石学、地球化学、地球物理学、石油地质学以及储层评价等理论和技术方法,充分利用岩心、露头、录井、测井和地震资料,在前人研究成果的基础上,以“盆地演化-沉积层序演化-有效储集砂体展布规律”为主线,按照“五步流程+图表定砂体”的岩性油气藏有效储集砂体预测的评价程序,系统研究了苏里格气田上古生界气藏主力含气层段(山1段、盒8段)有效储集砂体的展布规律,取得了如下创新性成果和认识:
①按照“宏观控局+微观定区”的研究思路,通过研究阴山古陆和伊盟隆起的构造演化,并对比分析物源区基岩与盆内沉积物的响应关系,首次明确了二者对研究区沉积物供给的影响。结合Dickinson三角投点图、基岩分布特征、碎屑组分特征、重矿物分布特征、岩屑特征、石英阴极发光特征、稀土元素特征和碎屑锆石定年等方法、手段,揭示了苏里格气田上古生界主力含气层段沉积时期的物源供给区是阴山古陆。
②在物源分析的基础上,按照“单井相-连井相-平面相-沉积演化-沉积模式”的研究流程,结合鄂尔多斯盆地上古生界的宏观沉积背景,根据盆地演化和浅水三角洲的形成机制,确认苏里格气田在山1段、盒8段沉积时期,发育浅水三角洲沉积体系,首次提出了苏里格气田盒8段的沉积环境为“毯式浅水辫状河三角洲”的概念,并首次建立了指导苏里格气田储层评价和预测的浅水曲流河三角洲沉积模式(山1段)和毯式浅水辫状河三角洲沉积模式(盒8段)。
③依据以Cross的基准面旋回为指导思想的高分辨率层序地层学理论和方法,结合苏里格气田主力含气层段(山1段、盒8段)已有的地层划分方案,系统研究了主力含气层段的层序特征、层序结构,建立了地震层序格架和以中期旋回为等时对比单元的高精度层序地层格架。明确了层序格架中大多数长期旋回层序具有区域性湖进-湖退沉积旋回性质,以长期旋回层序为单位,储集砂体的发育可分为2种类型,其一发育于层序分界面两侧,其二发育于层序内,发育于界面两侧的砂体产出层位相对较稳定,厚度较大,垂向上连续叠置,侧向上呈相互重叠的连通的毯状或宽带状展布,是储集砂体最为发育的位置;无论是平行或垂直物源供给方向,随着可容纳空间的增加,每个中期旋回层序的厚度,特别是洪漫细粒沉积的厚度,具有同步增厚,而储集砂体厚度和发育位置出现反向的退缩和减薄的变化趋势(局部地区受古地形影响有所增厚或减薄)。
④通过系统研究储层岩石学特征、成岩特征、物性特征、孔隙结构特征、非均质性特征和储集砂体成因类型等,确立了储层评价参数和标准,进行了储层分类评价和综合评价。其中,未实施压裂改造的条件下即可获得中高产能的Ⅰ类储层和压裂后可获中高产工业气流的Ⅱ类储层主要分布在研究区的盒8段,部分Ⅱ类储层分布山1段,压裂改造后有可能获得工业气流的Ⅲ类储层和Ⅳ类非储层在山1段和盒8段均有分布。
⑤在上述研究工作的基础上,重点结合有效储集砂体沉积特征、层序地层学特征和储层综合评价结果,参考有效储集砂体的主控因素,明确了苏里格气田上古生界山1段、盒8段有效储集砂体的展布规律。其中,山1段砂体为带状分布,有效储集砂体为孤立状分布;盒8段砂体呈大面积毯式分布,有效储集砂体多呈孤立状分布或局部地区呈带状分布。相对富集区块分布在主(辫状)分流河道砂体范围内,其中Ⅰ类区块(有利区)和Ⅱ类区块(较有利区)应该是下一步勘探的重点地区,Ⅲ类区块(中等有利区)也有很重要的经济开采价值。
According to the theory and methods of Sedimentology, high-resolution sequence stratigraphy, reservoir geology, mineralogy, geochemistry, geophysical, petroleum geology and reservoir evaluation, taking full advantage of data of core, outcrop, logging and seismic, on the basis of predecessor’s achievements, along the main line of basin evolution, sedimentary evolution and distribution regulation of effective reservoir sandbody, and according the evaluation process of prediction on effective reservoir sandbody of lithology reservoir, which is five-step and block decided by graphic and table, distribution regulation of effective reservoir sandbody of major gas-bearing interval in Sulige gas field was studied systematically, several creative achievements as follow were obtained.
①According to research idea of provenance direction controlled by tectonism and provenance location determined by analysis and measurement, based on the study on tectonic evolution of Yinshang old land and Yimeng upheave and the analysis of the response between provenance basement and sediment in basin, the influence on sediment supply in study area by both was definited firstly. With combination of Dickinson triangular diagram, distribution character of basement rock type, detrital component character, heavy mineral distribution character, rock detrital character, quartz cathodeluminescence character, REE character and Zircon dating, it is revealed that the provenance of upper Paleozoic major gas-bearing interval in Sulige gas field was from Yinshang old land.
②Based on provenance analysis, according to the research route of single well facies, cross-well facies, plane facies, sedimentary evolution and sedimentary model, with combination of sedimentary setting of upper Paleozoic in Ordos basin, and according to basin evolution and formation mechanism of shallow water delta, it is concluded that shallow water delta system developed in Sulige gas field during period of Shan1 and He8. It is first proposed that the sedimentary environment is blanketed shallow water braided river delta in He8 member of Sulige gas field, and the sedimentary model of shallow water meandering river delta in Shan1 member and the model of blanketed shallow water braided river delta in He8 member were built firstly, which were used to guide reservoir evaluation and prediction in Sulige gas field.
③According to the theory and methods of high-resolution sequence stratigraphy, which is guided by the Cross’s base level cycle, with combination of stratigraphy classification plan of major gas-bearing interval in Sulige gas field, sequence character and sequence configuration of major gas-bearing interval were studied carefully, seismic framework and high-resolution sequence stratigraphy framework of mid-term cycle were built. It is clear that there are regional progressive and regressive cycles in most long-term cycle of sequence framework, two types of reservoir sandbody developed in the long-term cycle, one of them developed on two sides of sequence boundary, the other one developed within sequence. The position of sandbody developed on sides of sequence is relatively stable, the thickness is great, they usually stacked continuously in vertical direction, and they stacked in shape of blanket or wide belt in horizon direction, where are the best position for developing reservoir sandbody. No matter the supply in horizon or vertical, with the increase of accommodation, the thickness in every mid-term cycle, especially the thickness of fine flooding sediment increased synchronously, meanwhile, the thickness of reservoir sandbody and the developing position showed reverse regression and reduction, part of them were affected by paleotopography.
④Based on the systematical study on character of reservoir mineralogy, diagenesis, geophysical, pore configuration, nonhomogeneity and reservoir sandbody genetic type, parameter and standard of reservoir evaluation are established to evaluate by sorting and synthetically. TypeⅠreservoir with high production without any fracturing and typeⅡreservoir with high industrial gas flow after fracturing mainly located in He8 member, part of typeⅡlocated in Shan1 member, typeⅢreservoir and typeⅣnon-reservoir with industrial gas flow after fracturing can be both found in Shan1 and He8 member.
⑤Based on the forenamed studies, particularly combined with results of sedimentary character of effective reservoir, sequence stratigraphy character and reservoir evaluation, referenced the main control factors of effective reservoir, the distribution regulation of effective reservoir of Shan1 and He8 member of upper Paleozoic in Sulige gas field is explicit. The sandbody of Shan1 member distributed in shape of belt, effective reservoir sandbody distributed isolatedly, the ones of He8 member distributed in large area like blanket, effective ones mostly distributed isolatedly or regionally in shape of belt. Respectively enrichment blocks located in sandbody of main braided distributary channel, the most favorable typeⅠblocks and second most favorable typeⅡblocks should be key area for next exploration, the middle favorable typeⅢblocks also have high value for exploration.
①按照“宏观控局+微观定区”的研究思路,通过研究阴山古陆和伊盟隆起的构造演化,并对比分析物源区基岩与盆内沉积物的响应关系,首次明确了二者对研究区沉积物供给的影响。结合Dickinson三角投点图、基岩分布特征、碎屑组分特征、重矿物分布特征、岩屑特征、石英阴极发光特征、稀土元素特征和碎屑锆石定年等方法、手段,揭示了苏里格气田上古生界主力含气层段沉积时期的物源供给区是阴山古陆。
②在物源分析的基础上,按照“单井相-连井相-平面相-沉积演化-沉积模式”的研究流程,结合鄂尔多斯盆地上古生界的宏观沉积背景,根据盆地演化和浅水三角洲的形成机制,确认苏里格气田在山1段、盒8段沉积时期,发育浅水三角洲沉积体系,首次提出了苏里格气田盒8段的沉积环境为“毯式浅水辫状河三角洲”的概念,并首次建立了指导苏里格气田储层评价和预测的浅水曲流河三角洲沉积模式(山1段)和毯式浅水辫状河三角洲沉积模式(盒8段)。
③依据以Cross的基准面旋回为指导思想的高分辨率层序地层学理论和方法,结合苏里格气田主力含气层段(山1段、盒8段)已有的地层划分方案,系统研究了主力含气层段的层序特征、层序结构,建立了地震层序格架和以中期旋回为等时对比单元的高精度层序地层格架。明确了层序格架中大多数长期旋回层序具有区域性湖进-湖退沉积旋回性质,以长期旋回层序为单位,储集砂体的发育可分为2种类型,其一发育于层序分界面两侧,其二发育于层序内,发育于界面两侧的砂体产出层位相对较稳定,厚度较大,垂向上连续叠置,侧向上呈相互重叠的连通的毯状或宽带状展布,是储集砂体最为发育的位置;无论是平行或垂直物源供给方向,随着可容纳空间的增加,每个中期旋回层序的厚度,特别是洪漫细粒沉积的厚度,具有同步增厚,而储集砂体厚度和发育位置出现反向的退缩和减薄的变化趋势(局部地区受古地形影响有所增厚或减薄)。
④通过系统研究储层岩石学特征、成岩特征、物性特征、孔隙结构特征、非均质性特征和储集砂体成因类型等,确立了储层评价参数和标准,进行了储层分类评价和综合评价。其中,未实施压裂改造的条件下即可获得中高产能的Ⅰ类储层和压裂后可获中高产工业气流的Ⅱ类储层主要分布在研究区的盒8段,部分Ⅱ类储层分布山1段,压裂改造后有可能获得工业气流的Ⅲ类储层和Ⅳ类非储层在山1段和盒8段均有分布。
⑤在上述研究工作的基础上,重点结合有效储集砂体沉积特征、层序地层学特征和储层综合评价结果,参考有效储集砂体的主控因素,明确了苏里格气田上古生界山1段、盒8段有效储集砂体的展布规律。其中,山1段砂体为带状分布,有效储集砂体为孤立状分布;盒8段砂体呈大面积毯式分布,有效储集砂体多呈孤立状分布或局部地区呈带状分布。相对富集区块分布在主(辫状)分流河道砂体范围内,其中Ⅰ类区块(有利区)和Ⅱ类区块(较有利区)应该是下一步勘探的重点地区,Ⅲ类区块(中等有利区)也有很重要的经济开采价值。
According to the theory and methods of Sedimentology, high-resolution sequence stratigraphy, reservoir geology, mineralogy, geochemistry, geophysical, petroleum geology and reservoir evaluation, taking full advantage of data of core, outcrop, logging and seismic, on the basis of predecessor’s achievements, along the main line of basin evolution, sedimentary evolution and distribution regulation of effective reservoir sandbody, and according the evaluation process of prediction on effective reservoir sandbody of lithology reservoir, which is five-step and block decided by graphic and table, distribution regulation of effective reservoir sandbody of major gas-bearing interval in Sulige gas field was studied systematically, several creative achievements as follow were obtained.
①According to research idea of provenance direction controlled by tectonism and provenance location determined by analysis and measurement, based on the study on tectonic evolution of Yinshang old land and Yimeng upheave and the analysis of the response between provenance basement and sediment in basin, the influence on sediment supply in study area by both was definited firstly. With combination of Dickinson triangular diagram, distribution character of basement rock type, detrital component character, heavy mineral distribution character, rock detrital character, quartz cathodeluminescence character, REE character and Zircon dating, it is revealed that the provenance of upper Paleozoic major gas-bearing interval in Sulige gas field was from Yinshang old land.
②Based on provenance analysis, according to the research route of single well facies, cross-well facies, plane facies, sedimentary evolution and sedimentary model, with combination of sedimentary setting of upper Paleozoic in Ordos basin, and according to basin evolution and formation mechanism of shallow water delta, it is concluded that shallow water delta system developed in Sulige gas field during period of Shan1 and He8. It is first proposed that the sedimentary environment is blanketed shallow water braided river delta in He8 member of Sulige gas field, and the sedimentary model of shallow water meandering river delta in Shan1 member and the model of blanketed shallow water braided river delta in He8 member were built firstly, which were used to guide reservoir evaluation and prediction in Sulige gas field.
③According to the theory and methods of high-resolution sequence stratigraphy, which is guided by the Cross’s base level cycle, with combination of stratigraphy classification plan of major gas-bearing interval in Sulige gas field, sequence character and sequence configuration of major gas-bearing interval were studied carefully, seismic framework and high-resolution sequence stratigraphy framework of mid-term cycle were built. It is clear that there are regional progressive and regressive cycles in most long-term cycle of sequence framework, two types of reservoir sandbody developed in the long-term cycle, one of them developed on two sides of sequence boundary, the other one developed within sequence. The position of sandbody developed on sides of sequence is relatively stable, the thickness is great, they usually stacked continuously in vertical direction, and they stacked in shape of blanket or wide belt in horizon direction, where are the best position for developing reservoir sandbody. No matter the supply in horizon or vertical, with the increase of accommodation, the thickness in every mid-term cycle, especially the thickness of fine flooding sediment increased synchronously, meanwhile, the thickness of reservoir sandbody and the developing position showed reverse regression and reduction, part of them were affected by paleotopography.
④Based on the systematical study on character of reservoir mineralogy, diagenesis, geophysical, pore configuration, nonhomogeneity and reservoir sandbody genetic type, parameter and standard of reservoir evaluation are established to evaluate by sorting and synthetically. TypeⅠreservoir with high production without any fracturing and typeⅡreservoir with high industrial gas flow after fracturing mainly located in He8 member, part of typeⅡlocated in Shan1 member, typeⅢreservoir and typeⅣnon-reservoir with industrial gas flow after fracturing can be both found in Shan1 and He8 member.
⑤Based on the forenamed studies, particularly combined with results of sedimentary character of effective reservoir, sequence stratigraphy character and reservoir evaluation, referenced the main control factors of effective reservoir, the distribution regulation of effective reservoir of Shan1 and He8 member of upper Paleozoic in Sulige gas field is explicit. The sandbody of Shan1 member distributed in shape of belt, effective reservoir sandbody distributed isolatedly, the ones of He8 member distributed in large area like blanket, effective ones mostly distributed isolatedly or regionally in shape of belt. Respectively enrichment blocks located in sandbody of main braided distributary channel, the most favorable typeⅠblocks and second most favorable typeⅡblocks should be key area for next exploration, the middle favorable typeⅢblocks also have high value for exploration.
引文
[1] Bloch,S.Secondary porosity sandstones:significance,origion,relationship to effect predrill reservoir quality prediction[A].in:Wilson M D,Reservoir quality assessment and prediction in elastics rocks[C].SEPM short Course,1994,136-159.
[2] Bloch,S.,Lander,R.H.&Bonnell,L. Anomalously high porosity and permeability in deeply buried sandstone reservoirs:Origin and predictability. American Association of Petroleum GeologistsBulletin:2002,86,301-328.
[3] Bloch,S.Secondary porosity in sandstones:Significance,origin,relationship to subaerial unconformities,and effect on predrill reservoir quality prediction. In:Reservoir Quality Assessment and Prediction in Clastic Rocks (Ed. M. D. Wilson)[J].Short Course 30,Society of Sedimentary Geologist,Tulsa,OK,1994,136-159.
[4] Boles,J.R.Secondary porosity reactions in the Stevens Sandstones,San Joaquin Valley California. In:Clastic Diagenesis(Eds D. A. McDonald&R. C. Surdam) Memoir 37[J].American Association ofPetroleum Geologists,Tulsa,OK,1984,217-225.
[5] Cross T.A.,Applications of high-resolution sequence stratigraphy in petroleum exploration and pnouetion short course Notes[J]. Canadian Society of Petroleum geologists,1993,290.
[6] Dickinson W R , Beard L S , Brakenridge G R,et al.Provenance of North AmericanPhanerozoic sandstones in relation to tectonic setting[J].GSA Bull,1983,94:225-235.
[7] Dickinson W R.Interpreting provenance relations from detrital modes of sandstones.In:Zuffa G G,ed.Provenance of Arenites[J]. Dordrecht,Reidel Publishing Co,1985.333-361.
[8] Galloway W E. Genetic stratigraphic sequences in basin analysis 1:architecture and genesis of flooding-surface bounded depositional units[J]. AAPG,1989,73:125-142.
[9] Ganil M R,,Bhat tacharya J P. Basic building blocks andprocess variability of a Cretaceous delta:internal faciesarchitecture reveals a more dynamic interaction of river,wave,and tidal processes than is indicated by external shape.Journal of Sedimentary Research,2007,77 (4):284-302.
[10] Hoy R G,Ridgway K D.Sedimentology and sequencestratigraphy of fan-delta and river-delta deposystems , Pennsylvanian Minturn Formation[J].Colorado.AAPG Bulletin,2003,87:1169-1191.
[11] Johnson J G , Klapper G , Sandberg C A. Devonian eustatic fluctuation in Eurameria[J]. Geological Socitery of America bulletin,1982,96:567-87.
[12] Keumsuk L l,McMechan G A,Gani M Ro,Bhattacharya J P,ZengX X,Howell C D. 3-D architecture and sequencest ratigraphic evolution of a forced regressive top-truncated mixed-influenced delta,Cretaceous Wall Creek sandstone,Wyoming,U.S.A.Journal of Sedimentary Research,2007,77(4):284-302.
[13] Lemons D R , Chan M A. Facies architecture and sequencest ratigraphy of fine-grained lacust rine deltas along the eastern margin of late Pleistocene Lake Bonneville,northern Utah and Southern [J].Idaho.AAPG Bulletin,1999,83:635-665.
[14] Plint A G. Sequence stratigraphy and paleogeography of a Cenomanian deltaic complex : the Dunvegan and lower Kaskapau formations in subsurface and outcrop,Alberta and British Columbia,Canada[J].Bulletin of Canadian Petroleum Geology,2000.48(1):43-79.
[15] Postma G.An analysis of the variation in delta architecture[J].Terra Nova,1990,2(2):124-130.
[16] Vail P.R. Seismic Stratigraphy Interpretation Using Sequece Stratigraphy.Part 1:Seismic Stratigraphy interpretation Proceduce. In:Bally A W,ed.Atlas of Seismic Stratigraphy[J]. AAPG,Studies in Geology,1987,27:1-10.
[17]白全明,樊长栓,等.辫状河道砂体模拟—苏里格苏6井区为例[J].石油天然气学报,2005,27(5):580-582.
[18]包洪平,贾亚妮,等.苏里格气田二叠系砂岩储层工业性分类评价[J].天然气工业,2005,25(4):14-15.
[19]包世海,张秀平,等.苏里格庙地区AVO气层类型及检测结果[J].油气井测试,2003,12(6):30-32.
[20]长庆油田石油地质志编写组.中国石油地质志(卷12)[M].北京:石油工业出版社,1992.
[21]陈安清,陈洪德,等.鄂尔多斯东北部山西组-下石盒子组砂岩特征及物源分析[J].成都理工大学学报(自然科学版),2007,34(3):305-311.
[22]陈纯芳,赵澄林,等.板桥和歧北四陷沙河街组深层碎屑岩储层物性特征及其影响因素[J].石油大学学报(自然科学版),2002,26(1):4-7.
[23]陈凤喜,刘海峰,等.变差函数在辫状河沉积砂岩储层规模预测中的应用[J].重庆科技学院学报(自然科学版),2008,10(1):9-11.
[24]陈凤喜,刘海峰,等.变差函数在辫状河沉积砂岩储层规模预测中的应用[J].重庆科技学院学报(自然科学版),2008,10(1):9-11.
[25]陈凤喜,卢涛,等.苏里格气田辫状河沉积相研究及其在地质建模中的应用[J].石油地质与工程,2008,22(2):21-24.
[26]陈洪德,侯中健,等.鄂尔多斯盆地晚古生代沉积层序地层学与盆地构造演化研究[J].矿物岩石,2001,21(3):16-22.
[27]陈洪德,张锦泉,等.鄂尔多斯盆地晚古生代沉积相研究.成都理工学院研究报告[R].2000.
[28]陈丽华,赵澄林.碎屑岩天然气储集层次生孔隙三种成因机理[J].石油勘探与开发,1999,26(5):77-79.
[29]陈衍景,杨忠芳,等.REE沉积物微量元素示踪物源区和地壳成分的方法和现状[J]地质地球化学,1996,(3):7-9.
[30]从连铸,姜波,等.苏里格盒8段储气藏伤害微观机理研究[J].中国矿业大学学报,2006,35(5):808-812.
[31]邓宏文,郭建宇,等.陆相断陷盆地的构造层序地层分析[J].地学前缘,2008,28(3):1-7.
[32]邓宏文,王红亮,等.层序地层地层基准面的识别、对比技术及应用[J].石油与天然气地质,1996,17(3):17-84.
[33]邓宏文,王红亮,等.沉积物体积分配原理一高分辨率层序底层学的基础[J].地学前缘,2000,7(4):305-313.
[34]邓宏文,王红亮,等.高分辨率层序地层在河流相储层分析中的应用[J].石油与天然气地质,1997,18(2):90-95.
[35]邓宏文,王红亮,等.古地貌对陆相裂谷盆地层序充填特征的控制[J].石油与天然气地质,2001,22(4):293-297.
[36]邓宏文,王红亮,等.河流相层序地层构成模式探讨[J].沉积学报,2004,22(3):373-379.
[37]邓宏文,吴海波,等.河流相层序地层划分方法[J].石油与天然气地质,2007,28(5):621-627.
[38]邓宏文.美国层序地层研究中的新学派一高分辨率层序地层学[J].石油与天然气地质,1995,16(2):89-97.
[39]丁晓琪,张哨楠,等.鄂尔多斯盆地北部上古生界致密砂岩储层特征及其成因探讨[J].石油天然气地质,2007,28(4):491-496.
[40]杜新江,任春玲.利用“同相轴下拉”地震反射特征预测苏里格气田气层[J].石油与天然气学报,2008,30(2):466-467.
[41]杜远生,颜佳新,等.造山带沉积地质学研究的新进展[J].地质科技情报,1995,14(1):21-35.
[42]樊太亮,郭齐军.鄂尔多斯盆地北部上古生界层序地层特征与储层发育规律[J].现代地质,1999,13(1):32-36.
[43]樊太亮,李卫东.层序地层应用于陆相油藏预测的成功实例[J].石油学报,1999,20(2):12-17.
[44]樊太亮,吕延仓,等.层序地层体制中的陆相储层发育规律[J].地学前缘,2007,(4):315-321.
[45]樊太亮,徐怀大,等.新疆塔里木盆地北部应用层序地层学[M].北京:地质出版社,1996.
[46]冯增昭.沉积岩石学(上下册)[M].北京:石油工业出版社,1992.
[47]付金华,席胜利,等.鄂尔多斯盆地上古生界低渗岩性油气藏综合勘探技术[J].石油科学(英文版),2004,1(2):111-118.
[48]付锁堂,田景春,等.鄂尔多斯盆地晚古生代三角洲沉积体系平面展布特征[J].成都理工大学学报(自然科学版),2003,30(3)236-241.
[49]高勇,张连雪.板桥-北大港地区深层碎屑岩储集层特征及影响因素研究[J].石油勘探与开发,2001,28(2):36-39.
[50]龚再升,李思田,等.南海北部大陆边缘盆地分析与油气聚集[M].北京:科学出版社,1997.
[51]郭建林.苏里格气田相对高产富集储层分布规律研究[D].北京:中国地质大学,2008.
[52]郭晓龙,欧阳永林,等.鄂尔多斯盆地苏里格气田地震转换波解释[J].天然气地球科学,2005,16(5):650-653.
[53]郭亚斌,肖文霞,等.苏里格气田多波地震资料解释方法及应用效果[J].石油天然气学报,2005,27(5):738-740.
[54]郭英海,李壮福,等.苏里格地区盒8-山1段砂体分布特征研究[R].2008.
[55]郭英海,李壮福,等.伊金霍洛旗地区盒8-山1段砂体分布特征研究[R].2008.
[56]郭英海,刘焕杰.陕甘宁地区晚古生代沉积体系[J].古地理学报,2000,2(1):19-30.
[57]郭忠铭,于忠平.河套弧形地堑系构造特征和演化机制及其油气勘探[J]石油勘探与开发,1990,(3):11-19.
[58]韩晓东,楼章华,等.松辽盆地湖泊浅水三角洲沉积动力学研究[J].矿物学报,2000,20 (3):305-310.
[59]韩新刚,陈军斌,等.苏里格气田地质随机建模研究[J].西安石油大学学报(自然科学版),2004:19(3):10-13.
[60]何东博,贾爱林,等.苏里格气田储集层成岩作用及有效储集层成因[J].石油勘探与开发,2004,31(3):69-71.
[61]何东博.苏里格气田复杂储层控制因素和有效储层预测[D].北京:中国地质大学,2005.
[62]何顺利、兰朝利,等.苏里格气田储层的新型辫状河沉积模式[J].石油学报,2005,26(6):25-29.
[63]何晓菊,郭亚斌,等.鄂尔多斯盆地苏里格庙地区上古生界砂岩储层预测技术和效果[J].石油地球物理勘探,2002,37(增刊):9-13.
[64]何义中,陈洪德,等.鄂尔多斯盆地中部石炭—二叠系两类三角洲沉积机理探讨[J].石油与天然气地质,2002,22(1):68-71.
[65]何自新,杨华,等.苏里格特大型气田发现及综合勘探技术[R].2006.
[66]何自新、付金华,等.苏里格大气田成藏地质特征[J].石油学报,2003,24(2):6-12.
[67]和钟烨,刘招君,等.柴达木盆地北缘大煤沟剖面重矿物分析及其地质意义[J].世界地质,2001,20(3):279-284.
[68]胡光明.鄂尔多斯盆地苏里格地区二叠系河流相砂体展布规律[J].油气地质与采收率,2004,11(1):4-7.
[69]胡江奈,张哨南,等.鄂尔多斯盆地北部下石盒子组-山西组成岩作用与储层的关系[J].成都理工学院学报,2001,28(2):169-173.
[70]胡骁,牛树根.内蒙古狼山-渣尔泰山中元古界的构造变形与演化[J].中国区域地质,1992,(1):75-82.
[71]黄思静,侯中键.地下孔隙度和渗透率在空间和时间上的变化及影响因素[J].沉积学报,2001,19(2):224-230.
[72]黄思静,谢连文,等.中国三叠系陆相砂岩中自生绿泥石的形成机制及其与储层孔隙保存的关系[J].成都理工大学学报(自然科学版),2004,31(3):273-280.
[73]黄思静,张萌,等.砂岩孔隙成因对孔隙度/渗透率关系的控制作用-以鄂尔多斯盆地陇东地区三叠系延长组为例[J].成都理工大学学报(自然科学版),2002,31(6):628-653.
[74]惠宽平,张哨南,等.鄂尔多斯盆地北部下石盒子组-山西组储层岩石学和成岩作用[J].成都理工学院学报,2002,29(3):272-278.
[75]纪友亮,张世奇,等.层序地层学原理及层序成因机制模式[M].北京:地质出版社,1998.
[76]姜在兴.沉积学[M].北京:石油工业出版社,2003.
[77]解国爱,张庆龙,等.鄂尔多斯盆地两种不同成因古隆起的特征及其在油气勘探中的意义[J]地质通报,2005,24(4):373-377.
[78]康玉柱.中国塔单木盆地石油地质特征及资源评价[M].北京地质出版社,1996.
[79]兰朝利,何顺利,等.基于密度-孔隙度-自然伽玛的储层多参数反演—以苏里格气田为例[J].西安石油大学学报(自然科学版),2008,23(1):37-39.
[80]兰朝利,何顺利,等.利用岩心或露头的交错层组厚度预测辫状河河带宽度—以鄂尔多斯盆地苏里格气田为例[J].油气地质与采收率,2005,12(2):16-19.
[81]李海燕,彭仕宓,等.苏里格气田低渗透储层成岩储集相特征[J].石油学报,2007,28(3):100-104.
[82]李会军,吴泰然,等.苏里格气田优质储层的控制因素[J].天然气工业,2004,24(8):12-14.
[83]李洁,陈洪德,等.鄂尔多斯盆地东北部下石盒子组盒8段辫状河三角洲沉积特征[J].沉积与特提斯地质,2008,28(1):27-32.
[84]李朋武,高锐,等.华北与西伯利亚地块碰撞时代的古地磁分析[J]地球学报,2007,28(3):234-252.
[85]李文厚,魏红红,等.苏里格庙气田碎屑岩储集层特征与天然气富集规律[J]石油与天然气地质,2002,23(4):387-392.
[86]李文厚,魏红红等.苏里格庙地区二叠系储层特征及有利相带预测[J].西北大学学报(自然科学版),2002,32(4):335-340.
[87]李增学,魏久传,等.鲁西河控浅水三角洲沉积体系及煤聚集规律[J].煤田地质与勘探,1995,23 (2):7-12.
[88]林畅松,刘景彦,等.高精度层序地层分析:建立沉积相和储层规模的等时地层格架田[J].现代地质,2002,16(3):276-281.
[89]林畅松,刘景彦,等.构造活动盆地的层序地层与构造地层分析—以中国中、新生代构造活动湖盆分析为例[J].地学前缘,2005,12(4):365-374.
[90]林畅松,张燕梅,等.高精度层序地层学和储层预测[J].地学前缘一中国地质大学(北京),2000,7(3):111-117.
[91]林畅松.沉积盆地的构造地层分析—以中国构造运动盆地研究为例[J].现代地质,2006,20(2):185-194.
[92]林雄,徐小蓉,等.鄂尔多斯盆地北部山西期-下石盒子期盆地演化与天然气富集规律[J].成都理工大学学报(自然科学版),2005,32(2):138-141.
[93]刘宝珺,张锦泉.沉积成岩作用[M].北京:科学出版社,1992.
[94]刘宝珺.岩相古地理基础和工作方法[M].北京:地质出版社,1985.
[95]刘宝珺主编,沉积岩石学[M].北京:地质出版社,1980.
[96]刘成林、朱筱敏,等.苏里格气田储层成岩序列与孔隙演化[J].天然气工业,2005,25(11):1-3.
[97]刘林玉,陈刚,等.碎屑岩储集层溶蚀型次生孔隙发育的影响因素分析[J].沉积学报,1998,16(2):97-101.
[98]刘锐蛾,黄月明,等.鄂尔多斯盆地北部晚古生代物源区分析及其地质意义[J].矿物岩石,2003,23(23):82-86.
[99]刘锐蛾,李文厚,等.苏里格庙地区盒8段高渗储层成岩相研究[J].西北大学学报(自然科学版),2002,32(6):667-671.
[100]刘锐蛾,孙粉锦,等.鄂尔多斯盆地北部上古生界储集岩的化学分类及储集性能评价[J].天然气地球科学,2003,14(3):193-199.
[101]刘少峰,柯爱蓉,等.鄂尔多斯西南缘前陆盆地沉积物物源分析及其构造意义[J].沉积学报,1997,15(1):156-159.
[102]刘圣志,李景明,等.鄂尔多斯盆地苏里格气田成藏机理研究[J].天然气工业,2005,25(3):4-6.
[103]楼章华,兰翔,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例[J].地质学报,1999,73(1):83-92.
[104]罗利,朱心万,等.苏5、桃7区块不同粒度碎屑岩测井识别方法[J].天然气工业,2007,27(12):36-38.
[105]罗孝俊,杨卫东,等.pH值对长石溶解度及次生孔隙发育的影响[J].矿物岩石地球化学通报,2001,20(2):103-107.
[106]孟元林,姜文亚,等.储层孔隙度预测与孔隙演化史模拟方法探讨—以辽河凹陷双清地区为例[J].沉积学报,2008,26(5):780-788.
[107]孟元林,修洪文,等.用泥岩热解资料预测储层次生孔隙发育带[J].天然气工业,2008,28(10):41-44.
[108]南珺祥、解丽琴,等,鄂尔多斯苏里格气田二叠系低孔低渗储层成因[J].西北大学学报(自然科学版),2005,35(2):207-211.
[109]欧阳永林,杨池银,等.用常规及近、远道叠加剖面识别气层[J].天然气地球科学,2003,14(4):287-290.
[110]潘仁芳,赵玉华,等.苏里格庙气田盒8段砂岩AVO正演模型研究[J].天然气工业,2002,22(5):7-10.
[111]彭澎,翟明国,等.华北陆块前寒武纪两次重大地质事件的特征和性质[J].地球科学进展,2002,17(6):818-825.
[112]钱峥,赵澄林,等.济阳坳陷深层天然气致密砂岩储集空间成因[J].石油大学学报(自然科学版),1992,18(6):21-25.
[113]谯汉生,方朝亮,等.中国东部深层石油地质[M].北京:石油工业出版社,2002.
[114]秦通社.利苏里格气田气层伤害的微观机理[J].新疆石油天然气,2007,3(2):7-12.
[115]邱隆伟,姜在兴,等.一种新的储层孔隙类型一石英溶解次生孔隙[J].沉积学报:2002,20(4):621-627.
[116]邱隆伟,赵伟,等.碱性成岩作用及其在济阳凹陷中的应用展望[J].油气地质与采收率,2007,14(2):10-15.
[117]裘亦楠,薛叔浩,等.油气储层评价技术[M].北京:石油工业出版社,1997.
[118]裘亦楠,薛叔浩,等.中国陆相油气储集层[M].北京:石油工业出版社,1997.
[119]邵济安,藏绍先.造山带的伸展构造与软流圈隆起-以兴蒙造山带为例[J].科学通报,1994,39(6):533-537.
[120]邵济安,唐克东,等.那丹哈达地体的构造特征及演化[J].中国科学B辑,1991,(7):744-751.
[121]邵维志.利用测井资料评价低孔隙度低渗透率气层产能方法研究[J].测井技术,2007,31(6):541-545.
[122]沈玉林,郭英海,等.鄂尔多斯盆地苏里格庙地区二叠系山西组及下石盒子组盒八段沉积相[J].古地理学报,2006,8(1):53-62.
[123]史基安,王琪.影响碎屑岩天然气储层物性的主要控制因素[J].沉积学报,1995,13(2):128-138.
[124]史松群,赵玉华.苏里格气田盒8砂岩储层的气储特征[J].中国石油勘探,2003,8(2):29-33.
[125]寿建峰,朱国华.砂岩储层孔隙保存的定量预测研究[J].地质科学,1998,32(2):224-249.
[126]寿建峰.碎屑岩储层控制因素及钻前定量地质预测[J].海相油气地质,1999,1:21-26.
[127]孙吉原,单冬梅,等.松辽盆地头台地区扶杨油层砂岩次生孔隙特征及其控制因素[J].大庆石油学院学报,2001,25(4):11-14.
[128]孙永传,李忠,等.中国东部含油气断陷盆地的成岩作用[M].北京:科学出版社,1996.
[129]汤锡元,郭忠铭,等.鄂尔多斯盆地西部逆冲推覆构造带特征及其演化与油气勘探[J].地球科学与环境学报,1988,9(1):2-10.
[130]唐俊伟,贾爱林,等.苏里格庙低渗强非均质性气田开发技术对策探讨[J].石油勘探与开发,2006,3(1):107-110.
[131]唐克东.中朝板块北侧褶皱带构造演化及成矿规律[M].北京:北京大学出版社,1992.
[132]田克勤,于志海,等.渤海湾盆地下第三系深层油气地质与勘探[M].北京:石油工业出版社,2000.
[133]田冷,李杰,等.储层流动单元划分方法在苏里格气田的应用[J].天然气工业,2005,25(10):44-46.
[134]王长江,令狐松,等.苏里格庙地区盒8段和山1段沉积微相特征[J].重庆科技学院学报(自然科学版),2005,7(3):1-5.
[135]王大兴,史松群,等.苏里格庙储层预测技术及效果[J].中国石油勘探,2001,6(3):32-43.
[136]王国灿.沉积物源区剥蚀历史分析的一种新途径—碎屑锆石和磷灰石裂变径迹热年代学[J].地质科技情报,2002,21(4):35-40.
[137]王洪建,邹新宁,等.储层预测技术在苏里格气田开发评价中的应用[J].煤田地质与勘探,2006,34(3):75-78.
[138]王树寅.苏里格地区上古生界气田沉积特征测井分析[J].测井技术,2006,30(2):146-148.
[139]王同和.晋陕地区构造演化与油气聚集[J].华北地质矿产杂志,1990,10(3):283-398.
[140]王维斌,朱心万,等.苏里格气田桃7区块盒8段、山1段储层特征[J].天然气工业,2007,27(12):22-24.
[141]王勇,徐晓荣,等.苏里格气田苏6井区上古生界沉积相特征研究[J].西北大学学报(自然科学版),2007,37(2):266-272.
[142]王瑜.晚古生代末-中生代内蒙古-燕山地区造山过程中岩浆热事件与构造演化[J].现代地质,1996,10(1):66-75.
[143]王振奇,何贞铭,等.鄂尔多斯盆地葫芦河地区三叠系延长组低渗致密砂岩储层特征研究[J].江汉石油学院学报,1998,20(2):27-33.
[144]王正江,张锦泉,等.鄂尔多斯盆地晚古生代陆源碎屑沉积源区分析[J].成都理工学院学报,2001,28(1):7-12.
[145]王志雄,徐国盛,等.鄂尔多斯盆地苏里格庙气田上古生界盒8段地质与地球物理相应特征[J].物探化探计算技术,2004,26(1):27-32.
[146]卫生平,郭彦如,等.古隆起与大气田的关系[J].天然气地球科学,1998,9(5):1-9.
[147]魏红红,李文厚,等.苏里格庙地区二叠系储层特征及影响因素分析[J].矿物岩石,2002,22(3):42-46.
[148]魏红红,彭惠群,等.鄂尔多斯盆地中部石炭-二叠系沉积相带与砂体展布[J].沉积学报,1999,9(3):403-408.
[149]文华国,郑荣才,等.苏里格气田苏6井区下石盒子组盒8段沉积相特征[J].沉积学报,2007,25(1):90-98.
[150]吴昌华,孙敏,等.乌拉山-集宁孔兹岩锆石激光探针等离子质谱年龄—孔兹岩沉积时限的年代学研究[J].岩石学报,2006,22(11):2639-2654.
[151]吴世敏,陈汉宗,等.沉积物物源分析的现状[J].海洋科学,1999,(2):35-37.
[152]席胜利,王怀厂,等.鄂尔多斯盆地北部山西组、下石盒子组物源分析[J].天然气工业,2002,22(2):21-24.
[153]肖建新,孙粉锦,等.鄂尔多斯盆地二叠系山西组及下石盒子组8段南北物源沉积汇水区与古地理[J].古地理学报,2008,10(4):341-354.
[154]徐明华,朱心万.苏里格气田苏5区块储层地震反演预测技术[J].天然气工业,2007,27(12):33-35.
[155]徐亚军,杜远生,等.沉积物物源分析研究进展[J].地质科技情报,2007,26(3):26-32.
[156]杨仁超.储层地质学研究新进展[J].特种油气藏,2006,13(2):1-5.
[157]杨守业,李从先.REE示踪沉积物物源研究进展[J]地球科学进展,1999,14(2):164-167.
[158]杨文秀,张刘平,等.苏里格庙气田二叠系盒8段孔隙发育控制因素[J].新疆石油地质,2006,27(4):419-421.
[159]杨晓宁,陈洪德,等.碎屑岩次生孔隙形成机制[J].大庆石油学院学报,2002,18(1):4-6.
[160]杨勇,达世攀,等.苏里格气田盒8段储层孔隙结构研究[J].天然气工业,2005,25(4):50-53.
[161]叶兴树.闵桥地区阜三段高分辨率层序地层学及低阻油藏预测[D].北京:中国石油大学,2007.
[162]尹志军,余兴云,等.苏里格气田苏6井区盒8段沉积相研究[J].天然气工业,2006,26(3):26-28.
[163]应凤祥,罗平,等.中国含油气盆地碎屑岩储集层成岩作用与成岩数值模拟[M].北京:石油工业出版社,2004.
[164]于兴河,李剑峰.油气储层研究所面临的挑战与新动向[J].地学前缘,1995,2(2):213-219.
[165]袁志祥,李良,等.鄂尔多斯盆地北部天然气地质[M].四川:四川大学出版社,2000.
[166]曾允孚、夏文杰.沉积岩石学[M].北京:地质出版社,1984.
[167]曾忠,阎世信,等.苏里格气田地震预测技术效果分析及对策[J].石油勘探与开发,2003,30(6):63-67.
[168]翟爱军,邓宏文,等.鄂尔多斯盆地上古生界层序地层与储层预测[J].石油与天然气地质,1999,20(4):336-340.
[169]翟光明.中国石油地质志(卷十二)[M].北京:石油工业出版社,1992.
[170]张臣,李茂松.内蒙古苏左旗地区晚古生代构造-岩浆活动及地壳演化特征[J].高校地质学报,1997,3(1):31-39.
[171]张传凤,郭英海,等.测井曲线在沉积环境中的应用[J].西部探矿工程,126(10):145-147.
[172]张福东,田世澄.鄂尔多斯盆地北部储层物源区与高渗带的发育关系[J].地学前缘,2003,10(3):66.
[173]张丽华,潘保芝,等.应用三重模型评价火成岩储层[J].测井技术,2008,32(1):37-40.
[174]张盟勃,史松群,等.叠前反演技术在苏里格地区的应用[J].岩性油气藏,2007,19(4):91-94.
[175]张明禄、达世攀,等.苏里格气田二叠系盒8段储集层的成岩作用及孔隙演化[J].天然气工业,2002,22(6):13-16.
[176]张生,李统锦.石英溶解动力学研究进展[J].世界地质,1996,15(4):8-13.
[177]张文才,顾岱鸿,等.苏里格气田相对低密度砂岩特征及成因[J].石油勘探与开发,2004,31(1):57-59.
[178]张玉清,王弢,等.内蒙古中部大青山北西乌兰不浪紫苏斜长麻粒岩锆石U-Pb年龄[J].中国地质,2003,30(4):394-399.
[179]赵澄林,刘孟彗,等.东淮四陷下第三系碎屑岩沉积体系与成岩作用[M].北京:石油工业出版社,1992.
[180]赵澄林.储层沉积学[M].北京:石油工业出版社,1998.
[181]赵红格等.物源分析方法及研究进展[J].沉积学报,2003,21(3):409-415.
[182]赵俊峰,魏昭冰,等.苏里格气层测井识别与评价研究[J].断块油气田,004,11(1):77-81.
[183]赵文智、汪泽成,等.鄂尔多斯盆地苏里格气田低效气藏的形成机理[J].石油学报,2005,26(5):5-9.
[184]郑荣才,彭军,等.高分辨率层序分析在油藏开发工程中的应用[J].沉积学报,2003,21(4):654-662.
[185]郑荣才,彭军,等.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):249-255.
[186]郑荣才,彭军,等.陆相盆地基准面旋回与沉积划分和研究[J].沉积学报,2001,19(20):249-255.
[187]郑荣才,吴朝容,等.浅谈陆相盆地高分辨率层序地层研究思路[J].成都理工学院学报:2000,27(3):241-244.
[188]郑荣才,尹世民,等.基准面旋回结构与叠加样式的沉积动力学分析[J].沉积学报:2000,18(3),369-375.
[189]郑荣才,朱如凯,等.川东北类前陆盆地须家河组盆-山耦合过程中的沉积-层序特征[J].地质学报,2008,82(8):1077-1087.
[190]郑荣才,朱如凯,等.川西类前陆盆地晚三叠世须家河期构造演化及层序充填样式[J].中国地质,2008,35(2):246-254.
[191]钟大康,朱筱敏,等.塔里木盆地中部泥盆系东河砂岩成岩作用与储集性能控制因素[J].古地理学报,2003,5(3):378-390.
[192]周安朝,贾炳文,等.内蒙古大青山煤田晚古生代沉积砾岩的物源分析[J]太原理工大学学报,2000,31(5):498-504.
[193]周安朝,赵省民,等.内蒙古大青山煤田晚古生代砾岩的沉积特征[J]沉积学报,2000,18(2):253-258.
[194]周东升,刘光祥,等.深部砂岩异常孔隙的保存机制研究[J].石油实验地质,2001,26(1):40-46.
[195]朱国华.成岩作用与砂岩孔隙的演化[M].北京:石油工业出版社,1982.
[196]朱国华.碎屑岩储集层孔隙的形成、演化和预测[J].沉积学报,1992,10(3):112-123.
[197]朱世全.苏里格10-28-33井储层物性特征及主控因素研究[J].沉积与特地斯,2008,28(2):53-56.
[198]朱筱敏,刘成林,等.苏里格地区上古生界有效储层的确定[J].天然气工业,2006,26(9):1-3.
[199]朱筱敏,孙超等.鄂尔多斯盆地苏里格气田储层成岩作用与模拟[J].中国地质,2007,134(2):276-282.
[200]朱怡翔,田昌炳,等.鄂尔多斯盆地苏里格气田相对高渗砂体的成因及其岩石物理测井识别方法[J].石油实验地质,2004,26(4):389-393.
[201]竹宏权,徐宏节.鄂尔多斯盆地北部上古生界储层物性影响因素[J].成都理工大学学报(自然科学版),2005,32(2):133-137.
[202]邹才能,陶士振,等.中国低丰度大型岩性油气田形成条件和分布规律[J].地质学报,2006,80(11):1739-1751
[203]邹才能,赵文智,等.大型敞流坳陷湖盆浅水三角洲与湖盆中心砂体形成与分布[J].地质学报,2008,82(6):813-825.
[204]邹新宁,孙卫,等.苏里格气田盒8段低渗砂岩储层的预测[J].石油物探,2005,44(6):621-623.
[2] Bloch,S.,Lander,R.H.&Bonnell,L. Anomalously high porosity and permeability in deeply buried sandstone reservoirs:Origin and predictability. American Association of Petroleum GeologistsBulletin:2002,86,301-328.
[3] Bloch,S.Secondary porosity in sandstones:Significance,origin,relationship to subaerial unconformities,and effect on predrill reservoir quality prediction. In:Reservoir Quality Assessment and Prediction in Clastic Rocks (Ed. M. D. Wilson)[J].Short Course 30,Society of Sedimentary Geologist,Tulsa,OK,1994,136-159.
[4] Boles,J.R.Secondary porosity reactions in the Stevens Sandstones,San Joaquin Valley California. In:Clastic Diagenesis(Eds D. A. McDonald&R. C. Surdam) Memoir 37[J].American Association ofPetroleum Geologists,Tulsa,OK,1984,217-225.
[5] Cross T.A.,Applications of high-resolution sequence stratigraphy in petroleum exploration and pnouetion short course Notes[J]. Canadian Society of Petroleum geologists,1993,290.
[6] Dickinson W R , Beard L S , Brakenridge G R,et al.Provenance of North AmericanPhanerozoic sandstones in relation to tectonic setting[J].GSA Bull,1983,94:225-235.
[7] Dickinson W R.Interpreting provenance relations from detrital modes of sandstones.In:Zuffa G G,ed.Provenance of Arenites[J]. Dordrecht,Reidel Publishing Co,1985.333-361.
[8] Galloway W E. Genetic stratigraphic sequences in basin analysis 1:architecture and genesis of flooding-surface bounded depositional units[J]. AAPG,1989,73:125-142.
[9] Ganil M R,,Bhat tacharya J P. Basic building blocks andprocess variability of a Cretaceous delta:internal faciesarchitecture reveals a more dynamic interaction of river,wave,and tidal processes than is indicated by external shape.Journal of Sedimentary Research,2007,77 (4):284-302.
[10] Hoy R G,Ridgway K D.Sedimentology and sequencestratigraphy of fan-delta and river-delta deposystems , Pennsylvanian Minturn Formation[J].Colorado.AAPG Bulletin,2003,87:1169-1191.
[11] Johnson J G , Klapper G , Sandberg C A. Devonian eustatic fluctuation in Eurameria[J]. Geological Socitery of America bulletin,1982,96:567-87.
[12] Keumsuk L l,McMechan G A,Gani M Ro,Bhattacharya J P,ZengX X,Howell C D. 3-D architecture and sequencest ratigraphic evolution of a forced regressive top-truncated mixed-influenced delta,Cretaceous Wall Creek sandstone,Wyoming,U.S.A.Journal of Sedimentary Research,2007,77(4):284-302.
[13] Lemons D R , Chan M A. Facies architecture and sequencest ratigraphy of fine-grained lacust rine deltas along the eastern margin of late Pleistocene Lake Bonneville,northern Utah and Southern [J].Idaho.AAPG Bulletin,1999,83:635-665.
[14] Plint A G. Sequence stratigraphy and paleogeography of a Cenomanian deltaic complex : the Dunvegan and lower Kaskapau formations in subsurface and outcrop,Alberta and British Columbia,Canada[J].Bulletin of Canadian Petroleum Geology,2000.48(1):43-79.
[15] Postma G.An analysis of the variation in delta architecture[J].Terra Nova,1990,2(2):124-130.
[16] Vail P.R. Seismic Stratigraphy Interpretation Using Sequece Stratigraphy.Part 1:Seismic Stratigraphy interpretation Proceduce. In:Bally A W,ed.Atlas of Seismic Stratigraphy[J]. AAPG,Studies in Geology,1987,27:1-10.
[17]白全明,樊长栓,等.辫状河道砂体模拟—苏里格苏6井区为例[J].石油天然气学报,2005,27(5):580-582.
[18]包洪平,贾亚妮,等.苏里格气田二叠系砂岩储层工业性分类评价[J].天然气工业,2005,25(4):14-15.
[19]包世海,张秀平,等.苏里格庙地区AVO气层类型及检测结果[J].油气井测试,2003,12(6):30-32.
[20]长庆油田石油地质志编写组.中国石油地质志(卷12)[M].北京:石油工业出版社,1992.
[21]陈安清,陈洪德,等.鄂尔多斯东北部山西组-下石盒子组砂岩特征及物源分析[J].成都理工大学学报(自然科学版),2007,34(3):305-311.
[22]陈纯芳,赵澄林,等.板桥和歧北四陷沙河街组深层碎屑岩储层物性特征及其影响因素[J].石油大学学报(自然科学版),2002,26(1):4-7.
[23]陈凤喜,刘海峰,等.变差函数在辫状河沉积砂岩储层规模预测中的应用[J].重庆科技学院学报(自然科学版),2008,10(1):9-11.
[24]陈凤喜,刘海峰,等.变差函数在辫状河沉积砂岩储层规模预测中的应用[J].重庆科技学院学报(自然科学版),2008,10(1):9-11.
[25]陈凤喜,卢涛,等.苏里格气田辫状河沉积相研究及其在地质建模中的应用[J].石油地质与工程,2008,22(2):21-24.
[26]陈洪德,侯中健,等.鄂尔多斯盆地晚古生代沉积层序地层学与盆地构造演化研究[J].矿物岩石,2001,21(3):16-22.
[27]陈洪德,张锦泉,等.鄂尔多斯盆地晚古生代沉积相研究.成都理工学院研究报告[R].2000.
[28]陈丽华,赵澄林.碎屑岩天然气储集层次生孔隙三种成因机理[J].石油勘探与开发,1999,26(5):77-79.
[29]陈衍景,杨忠芳,等.REE沉积物微量元素示踪物源区和地壳成分的方法和现状[J]地质地球化学,1996,(3):7-9.
[30]从连铸,姜波,等.苏里格盒8段储气藏伤害微观机理研究[J].中国矿业大学学报,2006,35(5):808-812.
[31]邓宏文,郭建宇,等.陆相断陷盆地的构造层序地层分析[J].地学前缘,2008,28(3):1-7.
[32]邓宏文,王红亮,等.层序地层地层基准面的识别、对比技术及应用[J].石油与天然气地质,1996,17(3):17-84.
[33]邓宏文,王红亮,等.沉积物体积分配原理一高分辨率层序底层学的基础[J].地学前缘,2000,7(4):305-313.
[34]邓宏文,王红亮,等.高分辨率层序地层在河流相储层分析中的应用[J].石油与天然气地质,1997,18(2):90-95.
[35]邓宏文,王红亮,等.古地貌对陆相裂谷盆地层序充填特征的控制[J].石油与天然气地质,2001,22(4):293-297.
[36]邓宏文,王红亮,等.河流相层序地层构成模式探讨[J].沉积学报,2004,22(3):373-379.
[37]邓宏文,吴海波,等.河流相层序地层划分方法[J].石油与天然气地质,2007,28(5):621-627.
[38]邓宏文.美国层序地层研究中的新学派一高分辨率层序地层学[J].石油与天然气地质,1995,16(2):89-97.
[39]丁晓琪,张哨楠,等.鄂尔多斯盆地北部上古生界致密砂岩储层特征及其成因探讨[J].石油天然气地质,2007,28(4):491-496.
[40]杜新江,任春玲.利用“同相轴下拉”地震反射特征预测苏里格气田气层[J].石油与天然气学报,2008,30(2):466-467.
[41]杜远生,颜佳新,等.造山带沉积地质学研究的新进展[J].地质科技情报,1995,14(1):21-35.
[42]樊太亮,郭齐军.鄂尔多斯盆地北部上古生界层序地层特征与储层发育规律[J].现代地质,1999,13(1):32-36.
[43]樊太亮,李卫东.层序地层应用于陆相油藏预测的成功实例[J].石油学报,1999,20(2):12-17.
[44]樊太亮,吕延仓,等.层序地层体制中的陆相储层发育规律[J].地学前缘,2007,(4):315-321.
[45]樊太亮,徐怀大,等.新疆塔里木盆地北部应用层序地层学[M].北京:地质出版社,1996.
[46]冯增昭.沉积岩石学(上下册)[M].北京:石油工业出版社,1992.
[47]付金华,席胜利,等.鄂尔多斯盆地上古生界低渗岩性油气藏综合勘探技术[J].石油科学(英文版),2004,1(2):111-118.
[48]付锁堂,田景春,等.鄂尔多斯盆地晚古生代三角洲沉积体系平面展布特征[J].成都理工大学学报(自然科学版),2003,30(3)236-241.
[49]高勇,张连雪.板桥-北大港地区深层碎屑岩储集层特征及影响因素研究[J].石油勘探与开发,2001,28(2):36-39.
[50]龚再升,李思田,等.南海北部大陆边缘盆地分析与油气聚集[M].北京:科学出版社,1997.
[51]郭建林.苏里格气田相对高产富集储层分布规律研究[D].北京:中国地质大学,2008.
[52]郭晓龙,欧阳永林,等.鄂尔多斯盆地苏里格气田地震转换波解释[J].天然气地球科学,2005,16(5):650-653.
[53]郭亚斌,肖文霞,等.苏里格气田多波地震资料解释方法及应用效果[J].石油天然气学报,2005,27(5):738-740.
[54]郭英海,李壮福,等.苏里格地区盒8-山1段砂体分布特征研究[R].2008.
[55]郭英海,李壮福,等.伊金霍洛旗地区盒8-山1段砂体分布特征研究[R].2008.
[56]郭英海,刘焕杰.陕甘宁地区晚古生代沉积体系[J].古地理学报,2000,2(1):19-30.
[57]郭忠铭,于忠平.河套弧形地堑系构造特征和演化机制及其油气勘探[J]石油勘探与开发,1990,(3):11-19.
[58]韩晓东,楼章华,等.松辽盆地湖泊浅水三角洲沉积动力学研究[J].矿物学报,2000,20 (3):305-310.
[59]韩新刚,陈军斌,等.苏里格气田地质随机建模研究[J].西安石油大学学报(自然科学版),2004:19(3):10-13.
[60]何东博,贾爱林,等.苏里格气田储集层成岩作用及有效储集层成因[J].石油勘探与开发,2004,31(3):69-71.
[61]何东博.苏里格气田复杂储层控制因素和有效储层预测[D].北京:中国地质大学,2005.
[62]何顺利、兰朝利,等.苏里格气田储层的新型辫状河沉积模式[J].石油学报,2005,26(6):25-29.
[63]何晓菊,郭亚斌,等.鄂尔多斯盆地苏里格庙地区上古生界砂岩储层预测技术和效果[J].石油地球物理勘探,2002,37(增刊):9-13.
[64]何义中,陈洪德,等.鄂尔多斯盆地中部石炭—二叠系两类三角洲沉积机理探讨[J].石油与天然气地质,2002,22(1):68-71.
[65]何自新,杨华,等.苏里格特大型气田发现及综合勘探技术[R].2006.
[66]何自新、付金华,等.苏里格大气田成藏地质特征[J].石油学报,2003,24(2):6-12.
[67]和钟烨,刘招君,等.柴达木盆地北缘大煤沟剖面重矿物分析及其地质意义[J].世界地质,2001,20(3):279-284.
[68]胡光明.鄂尔多斯盆地苏里格地区二叠系河流相砂体展布规律[J].油气地质与采收率,2004,11(1):4-7.
[69]胡江奈,张哨南,等.鄂尔多斯盆地北部下石盒子组-山西组成岩作用与储层的关系[J].成都理工学院学报,2001,28(2):169-173.
[70]胡骁,牛树根.内蒙古狼山-渣尔泰山中元古界的构造变形与演化[J].中国区域地质,1992,(1):75-82.
[71]黄思静,侯中键.地下孔隙度和渗透率在空间和时间上的变化及影响因素[J].沉积学报,2001,19(2):224-230.
[72]黄思静,谢连文,等.中国三叠系陆相砂岩中自生绿泥石的形成机制及其与储层孔隙保存的关系[J].成都理工大学学报(自然科学版),2004,31(3):273-280.
[73]黄思静,张萌,等.砂岩孔隙成因对孔隙度/渗透率关系的控制作用-以鄂尔多斯盆地陇东地区三叠系延长组为例[J].成都理工大学学报(自然科学版),2002,31(6):628-653.
[74]惠宽平,张哨南,等.鄂尔多斯盆地北部下石盒子组-山西组储层岩石学和成岩作用[J].成都理工学院学报,2002,29(3):272-278.
[75]纪友亮,张世奇,等.层序地层学原理及层序成因机制模式[M].北京:地质出版社,1998.
[76]姜在兴.沉积学[M].北京:石油工业出版社,2003.
[77]解国爱,张庆龙,等.鄂尔多斯盆地两种不同成因古隆起的特征及其在油气勘探中的意义[J]地质通报,2005,24(4):373-377.
[78]康玉柱.中国塔单木盆地石油地质特征及资源评价[M].北京地质出版社,1996.
[79]兰朝利,何顺利,等.基于密度-孔隙度-自然伽玛的储层多参数反演—以苏里格气田为例[J].西安石油大学学报(自然科学版),2008,23(1):37-39.
[80]兰朝利,何顺利,等.利用岩心或露头的交错层组厚度预测辫状河河带宽度—以鄂尔多斯盆地苏里格气田为例[J].油气地质与采收率,2005,12(2):16-19.
[81]李海燕,彭仕宓,等.苏里格气田低渗透储层成岩储集相特征[J].石油学报,2007,28(3):100-104.
[82]李会军,吴泰然,等.苏里格气田优质储层的控制因素[J].天然气工业,2004,24(8):12-14.
[83]李洁,陈洪德,等.鄂尔多斯盆地东北部下石盒子组盒8段辫状河三角洲沉积特征[J].沉积与特提斯地质,2008,28(1):27-32.
[84]李朋武,高锐,等.华北与西伯利亚地块碰撞时代的古地磁分析[J]地球学报,2007,28(3):234-252.
[85]李文厚,魏红红,等.苏里格庙气田碎屑岩储集层特征与天然气富集规律[J]石油与天然气地质,2002,23(4):387-392.
[86]李文厚,魏红红等.苏里格庙地区二叠系储层特征及有利相带预测[J].西北大学学报(自然科学版),2002,32(4):335-340.
[87]李增学,魏久传,等.鲁西河控浅水三角洲沉积体系及煤聚集规律[J].煤田地质与勘探,1995,23 (2):7-12.
[88]林畅松,刘景彦,等.高精度层序地层分析:建立沉积相和储层规模的等时地层格架田[J].现代地质,2002,16(3):276-281.
[89]林畅松,刘景彦,等.构造活动盆地的层序地层与构造地层分析—以中国中、新生代构造活动湖盆分析为例[J].地学前缘,2005,12(4):365-374.
[90]林畅松,张燕梅,等.高精度层序地层学和储层预测[J].地学前缘一中国地质大学(北京),2000,7(3):111-117.
[91]林畅松.沉积盆地的构造地层分析—以中国构造运动盆地研究为例[J].现代地质,2006,20(2):185-194.
[92]林雄,徐小蓉,等.鄂尔多斯盆地北部山西期-下石盒子期盆地演化与天然气富集规律[J].成都理工大学学报(自然科学版),2005,32(2):138-141.
[93]刘宝珺,张锦泉.沉积成岩作用[M].北京:科学出版社,1992.
[94]刘宝珺.岩相古地理基础和工作方法[M].北京:地质出版社,1985.
[95]刘宝珺主编,沉积岩石学[M].北京:地质出版社,1980.
[96]刘成林、朱筱敏,等.苏里格气田储层成岩序列与孔隙演化[J].天然气工业,2005,25(11):1-3.
[97]刘林玉,陈刚,等.碎屑岩储集层溶蚀型次生孔隙发育的影响因素分析[J].沉积学报,1998,16(2):97-101.
[98]刘锐蛾,黄月明,等.鄂尔多斯盆地北部晚古生代物源区分析及其地质意义[J].矿物岩石,2003,23(23):82-86.
[99]刘锐蛾,李文厚,等.苏里格庙地区盒8段高渗储层成岩相研究[J].西北大学学报(自然科学版),2002,32(6):667-671.
[100]刘锐蛾,孙粉锦,等.鄂尔多斯盆地北部上古生界储集岩的化学分类及储集性能评价[J].天然气地球科学,2003,14(3):193-199.
[101]刘少峰,柯爱蓉,等.鄂尔多斯西南缘前陆盆地沉积物物源分析及其构造意义[J].沉积学报,1997,15(1):156-159.
[102]刘圣志,李景明,等.鄂尔多斯盆地苏里格气田成藏机理研究[J].天然气工业,2005,25(3):4-6.
[103]楼章华,兰翔,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例[J].地质学报,1999,73(1):83-92.
[104]罗利,朱心万,等.苏5、桃7区块不同粒度碎屑岩测井识别方法[J].天然气工业,2007,27(12):36-38.
[105]罗孝俊,杨卫东,等.pH值对长石溶解度及次生孔隙发育的影响[J].矿物岩石地球化学通报,2001,20(2):103-107.
[106]孟元林,姜文亚,等.储层孔隙度预测与孔隙演化史模拟方法探讨—以辽河凹陷双清地区为例[J].沉积学报,2008,26(5):780-788.
[107]孟元林,修洪文,等.用泥岩热解资料预测储层次生孔隙发育带[J].天然气工业,2008,28(10):41-44.
[108]南珺祥、解丽琴,等,鄂尔多斯苏里格气田二叠系低孔低渗储层成因[J].西北大学学报(自然科学版),2005,35(2):207-211.
[109]欧阳永林,杨池银,等.用常规及近、远道叠加剖面识别气层[J].天然气地球科学,2003,14(4):287-290.
[110]潘仁芳,赵玉华,等.苏里格庙气田盒8段砂岩AVO正演模型研究[J].天然气工业,2002,22(5):7-10.
[111]彭澎,翟明国,等.华北陆块前寒武纪两次重大地质事件的特征和性质[J].地球科学进展,2002,17(6):818-825.
[112]钱峥,赵澄林,等.济阳坳陷深层天然气致密砂岩储集空间成因[J].石油大学学报(自然科学版),1992,18(6):21-25.
[113]谯汉生,方朝亮,等.中国东部深层石油地质[M].北京:石油工业出版社,2002.
[114]秦通社.利苏里格气田气层伤害的微观机理[J].新疆石油天然气,2007,3(2):7-12.
[115]邱隆伟,姜在兴,等.一种新的储层孔隙类型一石英溶解次生孔隙[J].沉积学报:2002,20(4):621-627.
[116]邱隆伟,赵伟,等.碱性成岩作用及其在济阳凹陷中的应用展望[J].油气地质与采收率,2007,14(2):10-15.
[117]裘亦楠,薛叔浩,等.油气储层评价技术[M].北京:石油工业出版社,1997.
[118]裘亦楠,薛叔浩,等.中国陆相油气储集层[M].北京:石油工业出版社,1997.
[119]邵济安,藏绍先.造山带的伸展构造与软流圈隆起-以兴蒙造山带为例[J].科学通报,1994,39(6):533-537.
[120]邵济安,唐克东,等.那丹哈达地体的构造特征及演化[J].中国科学B辑,1991,(7):744-751.
[121]邵维志.利用测井资料评价低孔隙度低渗透率气层产能方法研究[J].测井技术,2007,31(6):541-545.
[122]沈玉林,郭英海,等.鄂尔多斯盆地苏里格庙地区二叠系山西组及下石盒子组盒八段沉积相[J].古地理学报,2006,8(1):53-62.
[123]史基安,王琪.影响碎屑岩天然气储层物性的主要控制因素[J].沉积学报,1995,13(2):128-138.
[124]史松群,赵玉华.苏里格气田盒8砂岩储层的气储特征[J].中国石油勘探,2003,8(2):29-33.
[125]寿建峰,朱国华.砂岩储层孔隙保存的定量预测研究[J].地质科学,1998,32(2):224-249.
[126]寿建峰.碎屑岩储层控制因素及钻前定量地质预测[J].海相油气地质,1999,1:21-26.
[127]孙吉原,单冬梅,等.松辽盆地头台地区扶杨油层砂岩次生孔隙特征及其控制因素[J].大庆石油学院学报,2001,25(4):11-14.
[128]孙永传,李忠,等.中国东部含油气断陷盆地的成岩作用[M].北京:科学出版社,1996.
[129]汤锡元,郭忠铭,等.鄂尔多斯盆地西部逆冲推覆构造带特征及其演化与油气勘探[J].地球科学与环境学报,1988,9(1):2-10.
[130]唐俊伟,贾爱林,等.苏里格庙低渗强非均质性气田开发技术对策探讨[J].石油勘探与开发,2006,3(1):107-110.
[131]唐克东.中朝板块北侧褶皱带构造演化及成矿规律[M].北京:北京大学出版社,1992.
[132]田克勤,于志海,等.渤海湾盆地下第三系深层油气地质与勘探[M].北京:石油工业出版社,2000.
[133]田冷,李杰,等.储层流动单元划分方法在苏里格气田的应用[J].天然气工业,2005,25(10):44-46.
[134]王长江,令狐松,等.苏里格庙地区盒8段和山1段沉积微相特征[J].重庆科技学院学报(自然科学版),2005,7(3):1-5.
[135]王大兴,史松群,等.苏里格庙储层预测技术及效果[J].中国石油勘探,2001,6(3):32-43.
[136]王国灿.沉积物源区剥蚀历史分析的一种新途径—碎屑锆石和磷灰石裂变径迹热年代学[J].地质科技情报,2002,21(4):35-40.
[137]王洪建,邹新宁,等.储层预测技术在苏里格气田开发评价中的应用[J].煤田地质与勘探,2006,34(3):75-78.
[138]王树寅.苏里格地区上古生界气田沉积特征测井分析[J].测井技术,2006,30(2):146-148.
[139]王同和.晋陕地区构造演化与油气聚集[J].华北地质矿产杂志,1990,10(3):283-398.
[140]王维斌,朱心万,等.苏里格气田桃7区块盒8段、山1段储层特征[J].天然气工业,2007,27(12):22-24.
[141]王勇,徐晓荣,等.苏里格气田苏6井区上古生界沉积相特征研究[J].西北大学学报(自然科学版),2007,37(2):266-272.
[142]王瑜.晚古生代末-中生代内蒙古-燕山地区造山过程中岩浆热事件与构造演化[J].现代地质,1996,10(1):66-75.
[143]王振奇,何贞铭,等.鄂尔多斯盆地葫芦河地区三叠系延长组低渗致密砂岩储层特征研究[J].江汉石油学院学报,1998,20(2):27-33.
[144]王正江,张锦泉,等.鄂尔多斯盆地晚古生代陆源碎屑沉积源区分析[J].成都理工学院学报,2001,28(1):7-12.
[145]王志雄,徐国盛,等.鄂尔多斯盆地苏里格庙气田上古生界盒8段地质与地球物理相应特征[J].物探化探计算技术,2004,26(1):27-32.
[146]卫生平,郭彦如,等.古隆起与大气田的关系[J].天然气地球科学,1998,9(5):1-9.
[147]魏红红,李文厚,等.苏里格庙地区二叠系储层特征及影响因素分析[J].矿物岩石,2002,22(3):42-46.
[148]魏红红,彭惠群,等.鄂尔多斯盆地中部石炭-二叠系沉积相带与砂体展布[J].沉积学报,1999,9(3):403-408.
[149]文华国,郑荣才,等.苏里格气田苏6井区下石盒子组盒8段沉积相特征[J].沉积学报,2007,25(1):90-98.
[150]吴昌华,孙敏,等.乌拉山-集宁孔兹岩锆石激光探针等离子质谱年龄—孔兹岩沉积时限的年代学研究[J].岩石学报,2006,22(11):2639-2654.
[151]吴世敏,陈汉宗,等.沉积物物源分析的现状[J].海洋科学,1999,(2):35-37.
[152]席胜利,王怀厂,等.鄂尔多斯盆地北部山西组、下石盒子组物源分析[J].天然气工业,2002,22(2):21-24.
[153]肖建新,孙粉锦,等.鄂尔多斯盆地二叠系山西组及下石盒子组8段南北物源沉积汇水区与古地理[J].古地理学报,2008,10(4):341-354.
[154]徐明华,朱心万.苏里格气田苏5区块储层地震反演预测技术[J].天然气工业,2007,27(12):33-35.
[155]徐亚军,杜远生,等.沉积物物源分析研究进展[J].地质科技情报,2007,26(3):26-32.
[156]杨仁超.储层地质学研究新进展[J].特种油气藏,2006,13(2):1-5.
[157]杨守业,李从先.REE示踪沉积物物源研究进展[J]地球科学进展,1999,14(2):164-167.
[158]杨文秀,张刘平,等.苏里格庙气田二叠系盒8段孔隙发育控制因素[J].新疆石油地质,2006,27(4):419-421.
[159]杨晓宁,陈洪德,等.碎屑岩次生孔隙形成机制[J].大庆石油学院学报,2002,18(1):4-6.
[160]杨勇,达世攀,等.苏里格气田盒8段储层孔隙结构研究[J].天然气工业,2005,25(4):50-53.
[161]叶兴树.闵桥地区阜三段高分辨率层序地层学及低阻油藏预测[D].北京:中国石油大学,2007.
[162]尹志军,余兴云,等.苏里格气田苏6井区盒8段沉积相研究[J].天然气工业,2006,26(3):26-28.
[163]应凤祥,罗平,等.中国含油气盆地碎屑岩储集层成岩作用与成岩数值模拟[M].北京:石油工业出版社,2004.
[164]于兴河,李剑峰.油气储层研究所面临的挑战与新动向[J].地学前缘,1995,2(2):213-219.
[165]袁志祥,李良,等.鄂尔多斯盆地北部天然气地质[M].四川:四川大学出版社,2000.
[166]曾允孚、夏文杰.沉积岩石学[M].北京:地质出版社,1984.
[167]曾忠,阎世信,等.苏里格气田地震预测技术效果分析及对策[J].石油勘探与开发,2003,30(6):63-67.
[168]翟爱军,邓宏文,等.鄂尔多斯盆地上古生界层序地层与储层预测[J].石油与天然气地质,1999,20(4):336-340.
[169]翟光明.中国石油地质志(卷十二)[M].北京:石油工业出版社,1992.
[170]张臣,李茂松.内蒙古苏左旗地区晚古生代构造-岩浆活动及地壳演化特征[J].高校地质学报,1997,3(1):31-39.
[171]张传凤,郭英海,等.测井曲线在沉积环境中的应用[J].西部探矿工程,126(10):145-147.
[172]张福东,田世澄.鄂尔多斯盆地北部储层物源区与高渗带的发育关系[J].地学前缘,2003,10(3):66.
[173]张丽华,潘保芝,等.应用三重模型评价火成岩储层[J].测井技术,2008,32(1):37-40.
[174]张盟勃,史松群,等.叠前反演技术在苏里格地区的应用[J].岩性油气藏,2007,19(4):91-94.
[175]张明禄、达世攀,等.苏里格气田二叠系盒8段储集层的成岩作用及孔隙演化[J].天然气工业,2002,22(6):13-16.
[176]张生,李统锦.石英溶解动力学研究进展[J].世界地质,1996,15(4):8-13.
[177]张文才,顾岱鸿,等.苏里格气田相对低密度砂岩特征及成因[J].石油勘探与开发,2004,31(1):57-59.
[178]张玉清,王弢,等.内蒙古中部大青山北西乌兰不浪紫苏斜长麻粒岩锆石U-Pb年龄[J].中国地质,2003,30(4):394-399.
[179]赵澄林,刘孟彗,等.东淮四陷下第三系碎屑岩沉积体系与成岩作用[M].北京:石油工业出版社,1992.
[180]赵澄林.储层沉积学[M].北京:石油工业出版社,1998.
[181]赵红格等.物源分析方法及研究进展[J].沉积学报,2003,21(3):409-415.
[182]赵俊峰,魏昭冰,等.苏里格气层测井识别与评价研究[J].断块油气田,004,11(1):77-81.
[183]赵文智、汪泽成,等.鄂尔多斯盆地苏里格气田低效气藏的形成机理[J].石油学报,2005,26(5):5-9.
[184]郑荣才,彭军,等.高分辨率层序分析在油藏开发工程中的应用[J].沉积学报,2003,21(4):654-662.
[185]郑荣才,彭军,等.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):249-255.
[186]郑荣才,彭军,等.陆相盆地基准面旋回与沉积划分和研究[J].沉积学报,2001,19(20):249-255.
[187]郑荣才,吴朝容,等.浅谈陆相盆地高分辨率层序地层研究思路[J].成都理工学院学报:2000,27(3):241-244.
[188]郑荣才,尹世民,等.基准面旋回结构与叠加样式的沉积动力学分析[J].沉积学报:2000,18(3),369-375.
[189]郑荣才,朱如凯,等.川东北类前陆盆地须家河组盆-山耦合过程中的沉积-层序特征[J].地质学报,2008,82(8):1077-1087.
[190]郑荣才,朱如凯,等.川西类前陆盆地晚三叠世须家河期构造演化及层序充填样式[J].中国地质,2008,35(2):246-254.
[191]钟大康,朱筱敏,等.塔里木盆地中部泥盆系东河砂岩成岩作用与储集性能控制因素[J].古地理学报,2003,5(3):378-390.
[192]周安朝,贾炳文,等.内蒙古大青山煤田晚古生代沉积砾岩的物源分析[J]太原理工大学学报,2000,31(5):498-504.
[193]周安朝,赵省民,等.内蒙古大青山煤田晚古生代砾岩的沉积特征[J]沉积学报,2000,18(2):253-258.
[194]周东升,刘光祥,等.深部砂岩异常孔隙的保存机制研究[J].石油实验地质,2001,26(1):40-46.
[195]朱国华.成岩作用与砂岩孔隙的演化[M].北京:石油工业出版社,1982.
[196]朱国华.碎屑岩储集层孔隙的形成、演化和预测[J].沉积学报,1992,10(3):112-123.
[197]朱世全.苏里格10-28-33井储层物性特征及主控因素研究[J].沉积与特地斯,2008,28(2):53-56.
[198]朱筱敏,刘成林,等.苏里格地区上古生界有效储层的确定[J].天然气工业,2006,26(9):1-3.
[199]朱筱敏,孙超等.鄂尔多斯盆地苏里格气田储层成岩作用与模拟[J].中国地质,2007,134(2):276-282.
[200]朱怡翔,田昌炳,等.鄂尔多斯盆地苏里格气田相对高渗砂体的成因及其岩石物理测井识别方法[J].石油实验地质,2004,26(4):389-393.
[201]竹宏权,徐宏节.鄂尔多斯盆地北部上古生界储层物性影响因素[J].成都理工大学学报(自然科学版),2005,32(2):133-137.
[202]邹才能,陶士振,等.中国低丰度大型岩性油气田形成条件和分布规律[J].地质学报,2006,80(11):1739-1751
[203]邹才能,赵文智,等.大型敞流坳陷湖盆浅水三角洲与湖盆中心砂体形成与分布[J].地质学报,2008,82(6):813-825.
[204]邹新宁,孙卫,等.苏里格气田盒8段低渗砂岩储层的预测[J].石油物探,2005,44(6):621-623.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |