江汉盆地西南缘中新生界油藏预测研究
|
摘要
本论文以现代沉积学、构造学、经典层序地层学理论及国内外断陷盆地构造坡折带含油气区勘探经验为指导,对江汉盆地西南缘进行了整体解剖,探讨了断裂构造带储集砂体成因模式、分布规律和油气成藏规律,取得的主要成果有:
(1)江汉盆地西南缘构造运动控制了二级层序的发育,由构造、气候、物源制约的基准面旋回变化控制了该区三级层序结构。通过研究,建立了浅水断陷湖盆层序充填格架和发育模式。首次提出采穴-复兴场断阶带是追踪早期北北东、北西向两组断裂面发育而成,以万城-复兴场断层等北北东向同沉积断层及其衍生断层组成的扫帚状断裂带形成由采穴-复兴场-谢凤桥、八宝组成的富油断裂构造带。
(2)阐明了该区带下第三系新沟咀组、上白垩系渔洋组发育河流-三角洲沉积体系、浊积扇-半深湖相沉积体系等岩相类型。首次阐述了本区断裂坡折带砂体成因模式和分布规律,结果表明:物源来自西北方向,在采穴高断阶主要发育冲积扇-辫状河砂砾岩体;复兴场断块发育曲流河-三角洲沉积砂体,谢凤桥以西地区主要发育浊积扇砂体。
(3)断裂构造带发育断层-岩性型复合油气藏。油源来自谢凤桥下降盘玫瑰桥洼陷的新沟咀组下段和沙市组上段,属异源侧向阶梯状成藏模式,即新沟咀组下段和沙市组上段的油源沿谢凤桥断层侧向运移至断阶带白垩系河道砂岩中由构造等值线和断层封闭形成新生古储型油藏。
(4)通过钻井测井资料的高分辨率层序地层学对比分析,在白垩系渔洋组划分出六个中期旋回和十七个短期旋回,在沉积微相分析的基础上,分析总结了在基准面旋回各个阶段沉积演化规律。
(5)探索了一套在构造断裂带适用的地质、地球物理技术相结合的油藏预测方法技术。运用神经网络波形分析技术,定性识别砂岩扇体及发育规模;以高分辨率层序地层学相控砂层对比技术为核心,选用约束稀疏脉冲波阻抗反演
Based on the theory of modern sedimentary , tectonics , classical sequence stratigraphy and successful experiences of Oil & Gas exploration in the structural slope-break zone ,this paper goes deep into studying completely sedimentary system and model in south-western part of JiangLing Basin, indicates the distribution of some sandy bodies and purposes pool-forming mechanism of fault block zone . There are some conclusions and views as follows.
(1) In south-western part of JiangLing Basin, tectonic evolution controlled the 2-order sequences, and affected by tectonic, climate and sedimentary supplements, changes of the base level cycle control the 3-order sequences. It is the first time to found up the sequence stratigraphic framework in studying area and deposit pattern based on the fault subsidence lacustrine basin. This paper put forward that Cai xue-Fu xingchang fault block zone ,which was called broom-like fault zone, cut by NNE fault , NW fault and their derived one , form a oil-rich fault block zone .
(2) In this paper, the author illustrated the depositional system and model in studying area, and distinguished 14 kinds of lithofacies and 3 kinds of depositional system which were the alluvial fan and fluvial-delta system, turbidity fan- half deep lacustrine system. It is the first time to expound the genetic pattern and distributing rule of the fault block zone. In this area, the sediment supplements are from nearly north, the alluvial fan-braided fluvial sandy bodies distribute around the Cai xue fault block; the meandering stream-delta sandy bodies are developed in Fu xingchang area; the turbidity fan bodies mainly distribute up the western Xie fengqiao area.
(3) The fault block zone developed fault-lithological pool whose hydrocarbon source belong to EX1—ES2 in the Mei Guiqiao depression. The pool , called other-fountain side-direction ladder-shape one,mean that by Xie Fengqiao fault, the cruade oil was migrated to the channel belt sandstones in Fu Xingchang fault block, and then formed New-Generation-Old-Storage reservoirs.
(4) With the synthetic sequence analysis of well logging data and core data ,the highly resolution sequence architecture is build in Fu Xingchang fault block in Jiang
Ling depression. They are divided into six middle-term cycles and seventeen short-term cycles in Cretaceous Yu Yang formation. Based on the analysis of sedimentary microfacies, this paper summarized the sedimentary evolvement and distribution pattern during the periods of each base level cycle. (5) This paper goes research to some technical problem about isochronal sequence stratigraphy ,the prediction of the subtle reservoirs etc, and then based on the high resolution sequence stratigraphy microfacies correlation and armed with advanced geophysical interpretation and processing , preliminarily establishes a set of reservoir prediction techniques .Using the Neural network wave shape classification to qualitatily identify sandy bodies shape and distribution, adopting the constrained sparse pulse impedence inversion combined with the multiplex seismic parameter attribute extraction and analysis ,such as absorption coefficient, instantaneous frequency, and reflecting telescope, to trace and forcast reservoirs, a north-eastern reservoir belt of K2y3 was predicted in the middle of Fu Xingchang No.1 fault block,and three beneficial reservoirs of K2y4 were predicted in north ,middle,and south-eastern studying area. Through all those work, the exploration was preferablyguided,and the larger economic benefit and social benefit was acquired.
(1)江汉盆地西南缘构造运动控制了二级层序的发育,由构造、气候、物源制约的基准面旋回变化控制了该区三级层序结构。通过研究,建立了浅水断陷湖盆层序充填格架和发育模式。首次提出采穴-复兴场断阶带是追踪早期北北东、北西向两组断裂面发育而成,以万城-复兴场断层等北北东向同沉积断层及其衍生断层组成的扫帚状断裂带形成由采穴-复兴场-谢凤桥、八宝组成的富油断裂构造带。
(2)阐明了该区带下第三系新沟咀组、上白垩系渔洋组发育河流-三角洲沉积体系、浊积扇-半深湖相沉积体系等岩相类型。首次阐述了本区断裂坡折带砂体成因模式和分布规律,结果表明:物源来自西北方向,在采穴高断阶主要发育冲积扇-辫状河砂砾岩体;复兴场断块发育曲流河-三角洲沉积砂体,谢凤桥以西地区主要发育浊积扇砂体。
(3)断裂构造带发育断层-岩性型复合油气藏。油源来自谢凤桥下降盘玫瑰桥洼陷的新沟咀组下段和沙市组上段,属异源侧向阶梯状成藏模式,即新沟咀组下段和沙市组上段的油源沿谢凤桥断层侧向运移至断阶带白垩系河道砂岩中由构造等值线和断层封闭形成新生古储型油藏。
(4)通过钻井测井资料的高分辨率层序地层学对比分析,在白垩系渔洋组划分出六个中期旋回和十七个短期旋回,在沉积微相分析的基础上,分析总结了在基准面旋回各个阶段沉积演化规律。
(5)探索了一套在构造断裂带适用的地质、地球物理技术相结合的油藏预测方法技术。运用神经网络波形分析技术,定性识别砂岩扇体及发育规模;以高分辨率层序地层学相控砂层对比技术为核心,选用约束稀疏脉冲波阻抗反演
Based on the theory of modern sedimentary , tectonics , classical sequence stratigraphy and successful experiences of Oil & Gas exploration in the structural slope-break zone ,this paper goes deep into studying completely sedimentary system and model in south-western part of JiangLing Basin, indicates the distribution of some sandy bodies and purposes pool-forming mechanism of fault block zone . There are some conclusions and views as follows.
(1) In south-western part of JiangLing Basin, tectonic evolution controlled the 2-order sequences, and affected by tectonic, climate and sedimentary supplements, changes of the base level cycle control the 3-order sequences. It is the first time to found up the sequence stratigraphic framework in studying area and deposit pattern based on the fault subsidence lacustrine basin. This paper put forward that Cai xue-Fu xingchang fault block zone ,which was called broom-like fault zone, cut by NNE fault , NW fault and their derived one , form a oil-rich fault block zone .
(2) In this paper, the author illustrated the depositional system and model in studying area, and distinguished 14 kinds of lithofacies and 3 kinds of depositional system which were the alluvial fan and fluvial-delta system, turbidity fan- half deep lacustrine system. It is the first time to expound the genetic pattern and distributing rule of the fault block zone. In this area, the sediment supplements are from nearly north, the alluvial fan-braided fluvial sandy bodies distribute around the Cai xue fault block; the meandering stream-delta sandy bodies are developed in Fu xingchang area; the turbidity fan bodies mainly distribute up the western Xie fengqiao area.
(3) The fault block zone developed fault-lithological pool whose hydrocarbon source belong to EX1—ES2 in the Mei Guiqiao depression. The pool , called other-fountain side-direction ladder-shape one,mean that by Xie Fengqiao fault, the cruade oil was migrated to the channel belt sandstones in Fu Xingchang fault block, and then formed New-Generation-Old-Storage reservoirs.
(4) With the synthetic sequence analysis of well logging data and core data ,the highly resolution sequence architecture is build in Fu Xingchang fault block in Jiang
Ling depression. They are divided into six middle-term cycles and seventeen short-term cycles in Cretaceous Yu Yang formation. Based on the analysis of sedimentary microfacies, this paper summarized the sedimentary evolvement and distribution pattern during the periods of each base level cycle. (5) This paper goes research to some technical problem about isochronal sequence stratigraphy ,the prediction of the subtle reservoirs etc, and then based on the high resolution sequence stratigraphy microfacies correlation and armed with advanced geophysical interpretation and processing , preliminarily establishes a set of reservoir prediction techniques .Using the Neural network wave shape classification to qualitatily identify sandy bodies shape and distribution, adopting the constrained sparse pulse impedence inversion combined with the multiplex seismic parameter attribute extraction and analysis ,such as absorption coefficient, instantaneous frequency, and reflecting telescope, to trace and forcast reservoirs, a north-eastern reservoir belt of K2y3 was predicted in the middle of Fu Xingchang No.1 fault block,and three beneficial reservoirs of K2y4 were predicted in north ,middle,and south-eastern studying area. Through all those work, the exploration was preferablyguided,and the larger economic benefit and social benefit was acquired.
引文
[1]. 韩定坤,肖秋苟,高尚海等. 湖北江汉盆地西南缘油气勘查项目“九五”阶段总结报告(96-2000). 中南局规划院,2001.12.
[2]. 陈孔全等. 江陵凹陷西南缘新生古储型油气藏成藏条件. 天然气工业,2004;24(2):33-36.
[3]. 邓四新. 江汉盆地西南部油气成藏条件分析. 中南局研究院,1999.10.
[4]. 刘中戎等. 2003 年圈闭成果报告及 2004 年待钻圈闭. 中南局规划院,2003.8.
[5]. 陈正辅等. 江汉盆地西南缘烃源岩特征及鄂深 4 井成藏机制分析. 实验地质研究所,1999.7.
[6]. 刘中戎等. 江汉盆地西南缘砂岩储层预测与综合评价报告. 中南石油局,2002.3.
[7]. 王红强. 谢凤桥油田油藏动态特征研究. 中南石油局,2002.11.
[8]. 王燮培,费琪,张家骅. 石油构造分析[M]. 中国地质大学出版社,1990.
[9]. 金之钧, 张一伟. 油气成藏条件及主要控制因素. 石油工业出版社,2002.
[10]. 四普. 湖北松滋县鄂深 4 井完井地质报告. 1998.5.
[11]. 四普. 江汉盆地江陵凹陷南岗Ⅱ号断鼻鄂深 5 井完井地质报告. 1999.5.
[12]. 四普. 江汉盆地江陵凹陷谢凤桥构造鄂深 6 井完井地质报告. 2000.3.
[13]. 四普. 江汉盆地江陵凹陷八宝Ⅲ号构造鄂深 7 井完井地质报告. 2000.4.
[14]. 四普. 鄂深 8 井完井地质报告. 2001.3.
[15]. 四普. 江汉盆地江陵凹陷南部次凹带南岗Ⅰ号鼻状构造鄂深九井完井地质报告. 2002.4.
[16]. 中南局录井. 江汉盆地江陵凹陷南部次凹带复兴场Ⅰ号断块鄂深 10 井完井地质报告. 2002.10.
[17]. 中南局录井. 江汉盆地江陵凹陷万城—采穴断凸带采穴构造鄂深 11 井完井地质报告. 2002.1.
[18]. 中南局. 江陵凹陷南部次凹带谢凤桥断背斜鄂深 4 井完井测试报告. 1998.10.
[19]. 江汉测井. 江陵凹陷南部次凹带谢凤桥断背斜鄂深 14 井地层测试资料解释成果报告. 2002.2.
[20]. 江汉测井. 江陵凹陷南部次凹带谢凤桥断背斜构造鄂深14井完井测试报告. 2002.3.
[21]. 江汉油田. 鄂深 8 井试油成果报告. 2000.12.
[22]. 江汉油田. 鄂深 8 井系统试井测试解释报告. 2001.4.
[23]. 江汉油田. 鄂深 10 井试油施工总结. 2001.12.
[24]. 中南局. 江汉盆地江陵凹陷南部次凹带采穴构造鄂深 11 井地层测试成果报告. 2002.9.
[25]. 杨长清等. 江陵凹陷形成演化与勘探潜力. 天然气工业,2003,23(6):51-54.
[26]. 王平, 李纪辅, 李幼琼. 复杂断块油田详探与开发. 石油工业出版社. 1994:24-26.
[27]. 鲁兵力,罗笃清,王凯. 滨北地区浅层断裂特征、形成机制及其对圈闭的控制作用. 1998,22(3):5-8.
[28]. 卢明国,王典敷,林畅松. 江陵凹陷层序地层充填与油气勘探[J]. 江汉石油学院学报,2003,25(1):19-20.
[29]. 杨长清,陈孔全,程志强,詹海军. 江陵凹陷形成演化与勘探潜力. 天然气工业,2003,23(6):51-54.
[30]. 蒂索 B P,威尔特 D H. 石油的形成和分布. 石油工业出版社,1989,50-52.
[31]. 汤良杰,金之钧. 负反转断裂主反转期和反转强度分析. 石油大学学报(自然科学版),1999,23(6):1-5.
[32]. 吴智平,李伟,郑德顺. 沾化凹陷中、新生代断裂发育及其形成机制分析. 高校地质学报,2004, 10(3):405-416.
[33]. 李春光. 中国东部盆地油气藏同生断层的定量研究. 油气地质与采收率, 2003,10(4):1-4.
[34]. 李阳. 复杂断块油藏构造表征[M]. 石油工业出版社,2001.
[35]. 赵密福,刘泽容,信荃麟等. 惠民凹陷临南地区断层活动特征及控油作用.石油勘探与开发, 2000, 27(6): 9-11.
[36]. 朱志澄. 构造地质学. 中国地质大学出版社,1999.
[37]. 胡见义,黄第藩等. 中国陆相石油地质理论基础. 石油工业出版社,1991.
[38]. 陈荣书. 石油及天然气地质学. 中国地质大学出版社,1994.
[39]. B .P. 蒂索,D.H. 威尔特. 石油形成和分布(第二版). 徐永元等译. 石油工业出版社,1989.
[40]. 江汉油田石油地质志编写组. 中国石油地质志(卷九)江汉油田. 石油工业出版社,1971.
[41]. 江汉石油管理局勘探开发研究院 江陵凹陷第三—白垩系微体化石组特征,江汉油田(内部资料),1971
[42]. 江汉石油管理局勘探开发研究院 江汉盆地地层对比和沉积类型的划分,江汉油田(内部资料),1971
[43]. 江汉石油管理局勘探开发研究院 江汉盆地下第三系沉积特征,江汉油田(内部资料),1975
[44]. 江汉石油管理局勘探开发研究院 江汉盆地白垩系生油条件研究小结,江汉油田(内 部资料),1977
[45]. 江汉石油管理局勘探开发研究院 江汉盆地边缘与井下白垩系地层对比,江汉油田(内部资料),1977
[46]. 江汉石油管理局勘探开发研究院 江汉盆地下第三系地层划分及对比,江汉油田(内部资料),1979
[47]. 江汉石油管理局勘探开发研究院 江汉盆地江陵凹陷新沟嘴下段三角洲沉积特征,江汉油田(内部资料),1980
[48]. 江汉石油管理局勘探开发研究院,江汉盆地钻井地层数据手册;(内部资料)1988;12
[49]. 中国石化股份有限公司江汉油田分公司勘探开发处 江陵凹陷荆沙组 沙市组构造特征研究(内部资料) 1999;12
[50]. 中国石化新星公司中南石油局;江汉盆地西南缘油气评价勘探项目“九五”段总结报告(内部资料) 2001.12
[51]. 陈长江、卢明国等 江陵凹陷勘探潜力评价及部署,中国石化股份有限公司江汉油田分公司(内部资料) 2003.4
[52]. 邓四新 韩定坤等 江汉盆地西南部油气成藏条件分析 中国新星石油公司中南石油局 (内部资料) 1999.10
[53]. 朱玲,2001,谢凤桥油田储层特征及分析,中扬子油气勘查,2001,N043P24-30
[54]. 费琪等编著 成油体系分析与模拟 石油工业出版社 1997.10
[55]. 丁贵明 张一伟等 油气勘探工程 石油工业出版社 1997.10
[56]. 丁贵明等,油气勘探工程,北京,石油工业出版社,1997
[57]. 陆基孟等,地震勘探原理,东营,石油大学出版社,1993,8
[58]. 龙胜祥等,含油气盆地分析与资源评价,北京,地质出版社,1999,2
[59]. 朱裕生,矿产资源评价方法学导论,北京,地质出版社,1984
[60]. 邱建中,含油气盆地早期油气资源区域评价,石油学报弟三期,1984
[61]. 牛敏荃,石油物探新技术调研成果,北京:石油工业出版社,1996,9
[62]. 李铃等,用地震相干数据体进行断层自动解释,石油地球物理勘探,33(增刊),1998
[63]. 李庆忠,走向精确勘探的道路,北京石油工业出版社,1993
[64]. 谢泰俊等,江汉盆地盐构造及其对油气的控制作用,石油勘探与开发第 6 期,1983
[65]. 龚再生,含油气盆地早期油气资源评价方法-局部圈闭评价,石油学报第三期,1983
[66]. 徐怀大等. 地震地层学解释基础. 武汉: 中国地质大学出版社, 1992
[67]. 樊太亮, 徐怀大等. 新疆塔里木盆地北部应用层序地层学. 北京: 地质出版 社, 1997
[68]. 徐怀大、樊太亮、韩革华等,新疆塔里木盆地层序地层特征,北京:地质出版社,1997
[69]. 郭彦如,于均民,樊太亮,查干凹陷下白垩统层序地层格架与演化,石油与天然气地质,2002,Vol 23(2):166—169
[70]. 樊太亮,李庆谋,沉积基准面变化分析技术及应用,石油天然气地质,1997,Vol 18(2):108—113
[71]. 徐怀大,层序地层学理论用于我国断陷盆地分析中的问题,北京,石油与天然气地质,Vol 12(1),
[72]. 徐怀大等,从地震地层学到层序地层学—油气盆地的定性化与定量化描述,北京,石油工业出版社,王嗣敏,刘招君, 陆相盆地层序地层形成机制分析—以松辽盆地为例[J],长春科技大学学报,2000,30(2):137—142
[73]. 解习农,李思田, 陆相盆地层序地层学研究特点[J],地质科技情报,1993 ,12(1):22—26
[74]. 王训练,史晓颖,从第 31 届国际地质大会看地层学研究进展,地质科技情报,2002,Vol 21(3)
[75]. 刘振,吴因业,层序地层框架与油气勘探,北京:石油工业出版社,19991997
[76]. 徐怀大,寻找非构造油气藏的新思路[J],勘探家,1996,1(1):43—47
[77]. 樊太亮,塔里木盆地北部古生代密集段分布型式与海平面变化关系,地球科学—中国地质科学院院报,1998,Vol 03
[78]. 樊太亮,郭齐军,吴贤顺,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,现代地质,1999,Vol 01
[79]. 邓宏文, 美国层序地层学研究中的新学派—高分辨率层序地层学,1995,16(2):石油与天然气地质,90—97
[80]. 邓宏文,王洪亮,李照韶,层序地层基准面识别、对比技术及应用,石油与天然气地质,1999,17(3):177—184
[81]. 邓宏文,王洪亮,钟宁宁,沉积物体积分配原理—高分辨率层序地层学理论基础[J]。地学前缘,2000,7(4)305—313
[82]. 朱筱敏,层序地层学原理及应用,北京,石油工业出版社,1998
[83]. 魏魁生,叶淑芬,郭占谦等, 松辽盆地白垩系非海相地层层序模式[J],沉积学报,1996,14(4);50—58
[84]. 陈开远,孙爱霞,杜宁平,成油体系中的层序地层学,石油与天然气地质,1998,19(3):221—226
[85]. 薛良清,陆相盆地中的层序、体系域与隐蔽油气藏,石油与天然气地质,2002,Vol 23(2):115~117
[86]. 薛良清,成因层序地层学的回顾与展望,沉积学报,2000,Vol 18(03)
[87]. 朱筱敏,康安,张琴等,准噶尔盆地东北侏罗系含煤岩系层序地层和隐蔽圈闭,石油与天然气地质,2002,Vol 23(2):121~126
[88]. 袁选俊,谯汉生,渤海湾盆地富油气凹陷隐蔽圈闭油气勘探,石油与天然气地质,2002,Vol 23(2):130~133
[89]. 杨香华,陈开远,石万忠等,东濮凹陷盐湖层序结构与隐蔽油气藏,石油与天然气地质,2002,Vol 23(2):139~142
[90]. 姜秀芳,宗国洪,郭玉新等,断裂坡折带低位扇成因及成藏特征,石油与天然气地质,2002,Vol 23(2):143~144
[91]. 张年富,齐学峰,王英民等,准噶尔盆地侏罗系三层序底界上下砂体预测与有利区评价,石油与天然气地质,2002,Vol 23(2):145~149
[92]. 李群,松辽盆地南部隐蔽圈闭及有利地区预测,石油与天然气地质,2002,Vol 23(2):159—161
[93]. 曹颖辉,池英柳,薛良清,沉积基准面在层序划分及油气藏预测中的应用,石油与天然气地质,2002,Vol 23(2):154—158
[94]. 薛良清,论沉积层序级别的划分[J],石油勘探与开发,1998,25(3):10—14
[95]. 池英柳,张万选,张厚福等,陆相断陷盆地层序成因初探[J],勘探家,1996,17(3):19—25
[96]. 冯有良,李思田,东营凹陷沙河街组三段层序低位域砂体特征,地质评论, 2001,47(3):279—286
[97]. 薛良清,层序地层学在湖相盆地中的应用探讨[J],石油勘探与开发,1990,Vol 17(6):29—34
[98]. 李思田,林畅松,解习农等,大型陆相盆地层序地层学研究—以鄂尔多斯盆地中生代盆地为例[J],地学前缘,1995,2(4):133—136
[99]. 姜秀芳,宗国洪,郭玉新等,断裂坡折带低位扇成因及成藏特征,石油与天然气地质,2002,Vol 23(2):143—145
[100]. 胡受权,泌阳断陷湖盆陆相层序划分及其沉积体系配置,西南石油学报 20 P.42—48 1998。
[101]. 覃建雄,曾允孚等,碳酸盐斜坡沉积层序地层研究,石油实验地质,1999,Vol 02
[102]. 许广明,徐怀大,孔祥言,高分辨率层序地层学在油藏数值模拟中的应用,石油与天然气地质,1999,Vol 02
[103]. 朱创业,陕甘宁盆地下奥陶统马家沟组层序地层与天然气的关系,岩相古地理,1999,Vol 05
[104]. 丁孝忠,刘训,傅德荣等,塔里木板块西北缘石炭纪层序地层及海平面变化探讨, 中国区域地质,2000,Vol 01
[105]. 郑葆英,杨铁汾等,鄂尔多斯盆地中部石炭系层序地层分析,西安工程学院学报,2000,Vol,01
[106]. 杨飞,魏福军,彭大钧等,白云坳陷北坡特殊层序地层样式,石油与天然气地质,2000,Vol 03
[107]. 赵国连,层序地层学研究现状,沉积与特提斯地质,2000,Vol 03
[108]. 熊继辉,贾承造,王毅等,层序地层学及其在塔里木盆地石炭系研究中的应用,北京:石油工业出版社,1996,
[109]. 池秋鄂,龚福华,层序地层学基础与应用,北京:石油工业出版社,2001
[110]. 吴因业,邵文斌,含油气盆地层序解释技术与应用,北京:石油工业出版社,2000
[111]. 陈文学,姜在兴,鲜本忠等,层序地层学与隐蔽圈闭预测—以河南泌阳坳陷为例,北京:石油工业出版社
[112]. 武法东,周平等,东海陆架盆地西湖凹陷第三系层序地层与沉积体系分析,北京:地质出版社,2000
[113]. 冯有良,李思田,解习农,陆相断陷盆地层序形成动力学及层序地层模式,地学前缘,2000,Vol 7(3):119—132
[114]. 李良,鄂北塔巴庙地区山西组层序地层研究与圈闭识别,天然气工业,2001,Vol 21(增刊):10—13
[115]. 王家毫,王华,周海民等,断陷湖盆基底非线性沉降与Ⅱ型层序的形成—以冀东油田南堡凹陷为例,石油与天然气地质,2001,Vol 22(3):203—206
[116]. 威尔格斯,HK 等, 层序地层学原理—海平面变化综合分析,徐怀大等译。北京,石油工业出版社, 1993,47—256。
[117]. Bahorich M and farmer S.1995.3D Seismic discontinuity for faults and stratigraphic features:The coherence cube. The Leading Edge,14(10)
[118]. P.Lawrence,S,Aramco,Dhahran and S.Arabia ,Seismic attributes in the characterization of small-scale reservoir in Abqaiq Field,The Leading Edge 1998,17(4)
[119]. Quincy Chen and Steve Sidney, Seismic attribute technology for reservoir forecasting and monitoring . The Leading Edge,1997,16(5)
[120]. Catherine Lewis,Seismic attributes for reservoir monitoring :A feasibility study using forward modeling . The Leading Edge,1997,16(5)
[121]. Aitken J F, Howell J A. High resolution sequence stratigraphy : innovations, applications and future prospects[A]. Howell J A, Aitken J F, eds. High Resolution Sequence stratigraphy: Innovations and Applications[C]. Geological Society Special Publication, 1996, 104: 1~9.
[122]. Allen, P.A. and Allen, J.R., 1990. Basin Analysis – principles and applications. Blackwell Science, Oxford, 451 pages.
[123]. Vail P. R. Sequence Stratigraphy Interpretation using Sequence Stratigraphy: AAPG, 1987, 27/1—10
[124]. Galloway W. E. 1998, Genetic Stratigraphic, Sequence in Basin Analysis: AAPG, 73(2): 125—142
[125]. Van Wagoner JC et al., Siliciclastic Sequence Stratigraphy in well logs, cores and outcrops: Concepts for high-resolution correlation of time and facies: AAPG, Methods in Exploration Series. No.7, 1990, 55: 1-240
[126]. Vail P. R., Mitchum R M, 1977, Seismic Stratigraphy and global changes in sea level, Part 1: overview [A]. In: Payton C. E. Seismic Stratigraphy-application to hydrocarbon exploration[C]. AAPG Memoir, 26: 51-212
[127]. Posamentier, H.W. and Allen, G.P., 1993. Variability of the sequence stratigraphic model: effects of local basin factors. Sedimentary Geology, 86, 91-109.
[128]. Posamentier, H.W. and Allen, G.P., 1993. Siliciclastic sequence stratigraphic patterns in foreland ramp-type basins. Geology, 21, 455-488.
[129]. Vail, P.R., et al., 1977. Seismic stratigraphy and global changes of sea-level, Part 3 Relative changes of sea-level from coastal onlap. In, Payton, C.E. (ed.), Seismic stratigraphy, Applications to hydrocarbon exploration. AAPG. Memoir, 26, 63-81.
[130]. Emery, D. and Myers, K.J., 1996. Sequence stratigraphy. Blackwell Science, Oxford, 297 pages.
[131]. Mulholland, J.W., January, 1998, Sequence stratigraphy: Basic elements, concepts, and terminology: The Leading Edge,
[132]. Mulholland, J.W., June 1998, Sequence architecture: The Leading Edge, P. 767
[133]. Roksandic, M. M., February, 1994, The role of seismic stratigraphys in interpretation: The Leading Edge, P. 118
[134]. Friedman, G. M., J. E. Sanders, September 2000, Comments about the Relationships Between New Ideas and Geologic Terms in Stratigraphy and Sequence Stratigraphy with suggested Modifications: AAPG Bulletin, V. 84, No. 9, P.1274-1280
[135]. Brown, L. F., Jr., and W. L. Fisher, 1980, Seismic stratigraphic interpretation and Petroleum Exploration: AAPG Continuing Education Course Note Series, 16, 181 P
[136]. Nadon, G. C., J. A. (Toni) Simo, R. H., Dott, Jr., and C. W. Byers, July 2000, High-Resolution sequence stratigraphic analysis of the St. Peter sandstone and Glenwood formation (Middle Ordivocian), Michigan basin, U.S.A: AAPG Bulletin, V. 84, No. 7, P. 975-996
[137]. Gerald M. Friedman and John E. Sanders, September 2000, Comments about the relationships between new ideas and geologic terms in stratigraphy and sequence stratigraphy with suggested modifications: AAPG Bulletin, V. 84, No. 9, P. 1274-1280
[138]. Pinous, O. V., Y. N. Karogodin, S. V. Ershov, and D. L. Sahagian, June 1999, Sequence stratigraphy, facies, and sea level change of the Hauterivian productive complex, Priobskoe oil field (West Siberia): AAPG Bulletin, V. 83, No. 6, P. 972-989
[139]. Shanmugam, G., R. B. Bloch, J. E. Damuth, and R. J. Hodgkinson, April 1997, Basin-floor fans in the North Sea: Sequence stratigraphic models vs. sedimentary facies: reply: AAPG Bulletin, V. 81, No, 4, P. 666-672
[140]. Liangmiao (scott) Ye and Dennis Kerr, August 2000, Sequence Stratigraphy of the Middle Pennsylvanian Bartlesville sandstone, Northeastern Oklahoman: A case of an underfilled incised valley: AAPG Bulletin, V. 84, No. 8, P. 1185-1204
[141]. Robertson H. C., July 1998, Visualizing exploration targets through carbonate sequence stratigraphy: The Leading Edge, P. 891
[2]. 陈孔全等. 江陵凹陷西南缘新生古储型油气藏成藏条件. 天然气工业,2004;24(2):33-36.
[3]. 邓四新. 江汉盆地西南部油气成藏条件分析. 中南局研究院,1999.10.
[4]. 刘中戎等. 2003 年圈闭成果报告及 2004 年待钻圈闭. 中南局规划院,2003.8.
[5]. 陈正辅等. 江汉盆地西南缘烃源岩特征及鄂深 4 井成藏机制分析. 实验地质研究所,1999.7.
[6]. 刘中戎等. 江汉盆地西南缘砂岩储层预测与综合评价报告. 中南石油局,2002.3.
[7]. 王红强. 谢凤桥油田油藏动态特征研究. 中南石油局,2002.11.
[8]. 王燮培,费琪,张家骅. 石油构造分析[M]. 中国地质大学出版社,1990.
[9]. 金之钧, 张一伟. 油气成藏条件及主要控制因素. 石油工业出版社,2002.
[10]. 四普. 湖北松滋县鄂深 4 井完井地质报告. 1998.5.
[11]. 四普. 江汉盆地江陵凹陷南岗Ⅱ号断鼻鄂深 5 井完井地质报告. 1999.5.
[12]. 四普. 江汉盆地江陵凹陷谢凤桥构造鄂深 6 井完井地质报告. 2000.3.
[13]. 四普. 江汉盆地江陵凹陷八宝Ⅲ号构造鄂深 7 井完井地质报告. 2000.4.
[14]. 四普. 鄂深 8 井完井地质报告. 2001.3.
[15]. 四普. 江汉盆地江陵凹陷南部次凹带南岗Ⅰ号鼻状构造鄂深九井完井地质报告. 2002.4.
[16]. 中南局录井. 江汉盆地江陵凹陷南部次凹带复兴场Ⅰ号断块鄂深 10 井完井地质报告. 2002.10.
[17]. 中南局录井. 江汉盆地江陵凹陷万城—采穴断凸带采穴构造鄂深 11 井完井地质报告. 2002.1.
[18]. 中南局. 江陵凹陷南部次凹带谢凤桥断背斜鄂深 4 井完井测试报告. 1998.10.
[19]. 江汉测井. 江陵凹陷南部次凹带谢凤桥断背斜鄂深 14 井地层测试资料解释成果报告. 2002.2.
[20]. 江汉测井. 江陵凹陷南部次凹带谢凤桥断背斜构造鄂深14井完井测试报告. 2002.3.
[21]. 江汉油田. 鄂深 8 井试油成果报告. 2000.12.
[22]. 江汉油田. 鄂深 8 井系统试井测试解释报告. 2001.4.
[23]. 江汉油田. 鄂深 10 井试油施工总结. 2001.12.
[24]. 中南局. 江汉盆地江陵凹陷南部次凹带采穴构造鄂深 11 井地层测试成果报告. 2002.9.
[25]. 杨长清等. 江陵凹陷形成演化与勘探潜力. 天然气工业,2003,23(6):51-54.
[26]. 王平, 李纪辅, 李幼琼. 复杂断块油田详探与开发. 石油工业出版社. 1994:24-26.
[27]. 鲁兵力,罗笃清,王凯. 滨北地区浅层断裂特征、形成机制及其对圈闭的控制作用. 1998,22(3):5-8.
[28]. 卢明国,王典敷,林畅松. 江陵凹陷层序地层充填与油气勘探[J]. 江汉石油学院学报,2003,25(1):19-20.
[29]. 杨长清,陈孔全,程志强,詹海军. 江陵凹陷形成演化与勘探潜力. 天然气工业,2003,23(6):51-54.
[30]. 蒂索 B P,威尔特 D H. 石油的形成和分布. 石油工业出版社,1989,50-52.
[31]. 汤良杰,金之钧. 负反转断裂主反转期和反转强度分析. 石油大学学报(自然科学版),1999,23(6):1-5.
[32]. 吴智平,李伟,郑德顺. 沾化凹陷中、新生代断裂发育及其形成机制分析. 高校地质学报,2004, 10(3):405-416.
[33]. 李春光. 中国东部盆地油气藏同生断层的定量研究. 油气地质与采收率, 2003,10(4):1-4.
[34]. 李阳. 复杂断块油藏构造表征[M]. 石油工业出版社,2001.
[35]. 赵密福,刘泽容,信荃麟等. 惠民凹陷临南地区断层活动特征及控油作用.石油勘探与开发, 2000, 27(6): 9-11.
[36]. 朱志澄. 构造地质学. 中国地质大学出版社,1999.
[37]. 胡见义,黄第藩等. 中国陆相石油地质理论基础. 石油工业出版社,1991.
[38]. 陈荣书. 石油及天然气地质学. 中国地质大学出版社,1994.
[39]. B .P. 蒂索,D.H. 威尔特. 石油形成和分布(第二版). 徐永元等译. 石油工业出版社,1989.
[40]. 江汉油田石油地质志编写组. 中国石油地质志(卷九)江汉油田. 石油工业出版社,1971.
[41]. 江汉石油管理局勘探开发研究院 江陵凹陷第三—白垩系微体化石组特征,江汉油田(内部资料),1971
[42]. 江汉石油管理局勘探开发研究院 江汉盆地地层对比和沉积类型的划分,江汉油田(内部资料),1971
[43]. 江汉石油管理局勘探开发研究院 江汉盆地下第三系沉积特征,江汉油田(内部资料),1975
[44]. 江汉石油管理局勘探开发研究院 江汉盆地白垩系生油条件研究小结,江汉油田(内 部资料),1977
[45]. 江汉石油管理局勘探开发研究院 江汉盆地边缘与井下白垩系地层对比,江汉油田(内部资料),1977
[46]. 江汉石油管理局勘探开发研究院 江汉盆地下第三系地层划分及对比,江汉油田(内部资料),1979
[47]. 江汉石油管理局勘探开发研究院 江汉盆地江陵凹陷新沟嘴下段三角洲沉积特征,江汉油田(内部资料),1980
[48]. 江汉石油管理局勘探开发研究院,江汉盆地钻井地层数据手册;(内部资料)1988;12
[49]. 中国石化股份有限公司江汉油田分公司勘探开发处 江陵凹陷荆沙组 沙市组构造特征研究(内部资料) 1999;12
[50]. 中国石化新星公司中南石油局;江汉盆地西南缘油气评价勘探项目“九五”段总结报告(内部资料) 2001.12
[51]. 陈长江、卢明国等 江陵凹陷勘探潜力评价及部署,中国石化股份有限公司江汉油田分公司(内部资料) 2003.4
[52]. 邓四新 韩定坤等 江汉盆地西南部油气成藏条件分析 中国新星石油公司中南石油局 (内部资料) 1999.10
[53]. 朱玲,2001,谢凤桥油田储层特征及分析,中扬子油气勘查,2001,N043P24-30
[54]. 费琪等编著 成油体系分析与模拟 石油工业出版社 1997.10
[55]. 丁贵明 张一伟等 油气勘探工程 石油工业出版社 1997.10
[56]. 丁贵明等,油气勘探工程,北京,石油工业出版社,1997
[57]. 陆基孟等,地震勘探原理,东营,石油大学出版社,1993,8
[58]. 龙胜祥等,含油气盆地分析与资源评价,北京,地质出版社,1999,2
[59]. 朱裕生,矿产资源评价方法学导论,北京,地质出版社,1984
[60]. 邱建中,含油气盆地早期油气资源区域评价,石油学报弟三期,1984
[61]. 牛敏荃,石油物探新技术调研成果,北京:石油工业出版社,1996,9
[62]. 李铃等,用地震相干数据体进行断层自动解释,石油地球物理勘探,33(增刊),1998
[63]. 李庆忠,走向精确勘探的道路,北京石油工业出版社,1993
[64]. 谢泰俊等,江汉盆地盐构造及其对油气的控制作用,石油勘探与开发第 6 期,1983
[65]. 龚再生,含油气盆地早期油气资源评价方法-局部圈闭评价,石油学报第三期,1983
[66]. 徐怀大等. 地震地层学解释基础. 武汉: 中国地质大学出版社, 1992
[67]. 樊太亮, 徐怀大等. 新疆塔里木盆地北部应用层序地层学. 北京: 地质出版 社, 1997
[68]. 徐怀大、樊太亮、韩革华等,新疆塔里木盆地层序地层特征,北京:地质出版社,1997
[69]. 郭彦如,于均民,樊太亮,查干凹陷下白垩统层序地层格架与演化,石油与天然气地质,2002,Vol 23(2):166—169
[70]. 樊太亮,李庆谋,沉积基准面变化分析技术及应用,石油天然气地质,1997,Vol 18(2):108—113
[71]. 徐怀大,层序地层学理论用于我国断陷盆地分析中的问题,北京,石油与天然气地质,Vol 12(1),
[72]. 徐怀大等,从地震地层学到层序地层学—油气盆地的定性化与定量化描述,北京,石油工业出版社,王嗣敏,刘招君, 陆相盆地层序地层形成机制分析—以松辽盆地为例[J],长春科技大学学报,2000,30(2):137—142
[73]. 解习农,李思田, 陆相盆地层序地层学研究特点[J],地质科技情报,1993 ,12(1):22—26
[74]. 王训练,史晓颖,从第 31 届国际地质大会看地层学研究进展,地质科技情报,2002,Vol 21(3)
[75]. 刘振,吴因业,层序地层框架与油气勘探,北京:石油工业出版社,19991997
[76]. 徐怀大,寻找非构造油气藏的新思路[J],勘探家,1996,1(1):43—47
[77]. 樊太亮,塔里木盆地北部古生代密集段分布型式与海平面变化关系,地球科学—中国地质科学院院报,1998,Vol 03
[78]. 樊太亮,郭齐军,吴贤顺,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,现代地质,1999,Vol 01
[79]. 邓宏文, 美国层序地层学研究中的新学派—高分辨率层序地层学,1995,16(2):石油与天然气地质,90—97
[80]. 邓宏文,王洪亮,李照韶,层序地层基准面识别、对比技术及应用,石油与天然气地质,1999,17(3):177—184
[81]. 邓宏文,王洪亮,钟宁宁,沉积物体积分配原理—高分辨率层序地层学理论基础[J]。地学前缘,2000,7(4)305—313
[82]. 朱筱敏,层序地层学原理及应用,北京,石油工业出版社,1998
[83]. 魏魁生,叶淑芬,郭占谦等, 松辽盆地白垩系非海相地层层序模式[J],沉积学报,1996,14(4);50—58
[84]. 陈开远,孙爱霞,杜宁平,成油体系中的层序地层学,石油与天然气地质,1998,19(3):221—226
[85]. 薛良清,陆相盆地中的层序、体系域与隐蔽油气藏,石油与天然气地质,2002,Vol 23(2):115~117
[86]. 薛良清,成因层序地层学的回顾与展望,沉积学报,2000,Vol 18(03)
[87]. 朱筱敏,康安,张琴等,准噶尔盆地东北侏罗系含煤岩系层序地层和隐蔽圈闭,石油与天然气地质,2002,Vol 23(2):121~126
[88]. 袁选俊,谯汉生,渤海湾盆地富油气凹陷隐蔽圈闭油气勘探,石油与天然气地质,2002,Vol 23(2):130~133
[89]. 杨香华,陈开远,石万忠等,东濮凹陷盐湖层序结构与隐蔽油气藏,石油与天然气地质,2002,Vol 23(2):139~142
[90]. 姜秀芳,宗国洪,郭玉新等,断裂坡折带低位扇成因及成藏特征,石油与天然气地质,2002,Vol 23(2):143~144
[91]. 张年富,齐学峰,王英民等,准噶尔盆地侏罗系三层序底界上下砂体预测与有利区评价,石油与天然气地质,2002,Vol 23(2):145~149
[92]. 李群,松辽盆地南部隐蔽圈闭及有利地区预测,石油与天然气地质,2002,Vol 23(2):159—161
[93]. 曹颖辉,池英柳,薛良清,沉积基准面在层序划分及油气藏预测中的应用,石油与天然气地质,2002,Vol 23(2):154—158
[94]. 薛良清,论沉积层序级别的划分[J],石油勘探与开发,1998,25(3):10—14
[95]. 池英柳,张万选,张厚福等,陆相断陷盆地层序成因初探[J],勘探家,1996,17(3):19—25
[96]. 冯有良,李思田,东营凹陷沙河街组三段层序低位域砂体特征,地质评论, 2001,47(3):279—286
[97]. 薛良清,层序地层学在湖相盆地中的应用探讨[J],石油勘探与开发,1990,Vol 17(6):29—34
[98]. 李思田,林畅松,解习农等,大型陆相盆地层序地层学研究—以鄂尔多斯盆地中生代盆地为例[J],地学前缘,1995,2(4):133—136
[99]. 姜秀芳,宗国洪,郭玉新等,断裂坡折带低位扇成因及成藏特征,石油与天然气地质,2002,Vol 23(2):143—145
[100]. 胡受权,泌阳断陷湖盆陆相层序划分及其沉积体系配置,西南石油学报 20 P.42—48 1998。
[101]. 覃建雄,曾允孚等,碳酸盐斜坡沉积层序地层研究,石油实验地质,1999,Vol 02
[102]. 许广明,徐怀大,孔祥言,高分辨率层序地层学在油藏数值模拟中的应用,石油与天然气地质,1999,Vol 02
[103]. 朱创业,陕甘宁盆地下奥陶统马家沟组层序地层与天然气的关系,岩相古地理,1999,Vol 05
[104]. 丁孝忠,刘训,傅德荣等,塔里木板块西北缘石炭纪层序地层及海平面变化探讨, 中国区域地质,2000,Vol 01
[105]. 郑葆英,杨铁汾等,鄂尔多斯盆地中部石炭系层序地层分析,西安工程学院学报,2000,Vol,01
[106]. 杨飞,魏福军,彭大钧等,白云坳陷北坡特殊层序地层样式,石油与天然气地质,2000,Vol 03
[107]. 赵国连,层序地层学研究现状,沉积与特提斯地质,2000,Vol 03
[108]. 熊继辉,贾承造,王毅等,层序地层学及其在塔里木盆地石炭系研究中的应用,北京:石油工业出版社,1996,
[109]. 池秋鄂,龚福华,层序地层学基础与应用,北京:石油工业出版社,2001
[110]. 吴因业,邵文斌,含油气盆地层序解释技术与应用,北京:石油工业出版社,2000
[111]. 陈文学,姜在兴,鲜本忠等,层序地层学与隐蔽圈闭预测—以河南泌阳坳陷为例,北京:石油工业出版社
[112]. 武法东,周平等,东海陆架盆地西湖凹陷第三系层序地层与沉积体系分析,北京:地质出版社,2000
[113]. 冯有良,李思田,解习农,陆相断陷盆地层序形成动力学及层序地层模式,地学前缘,2000,Vol 7(3):119—132
[114]. 李良,鄂北塔巴庙地区山西组层序地层研究与圈闭识别,天然气工业,2001,Vol 21(增刊):10—13
[115]. 王家毫,王华,周海民等,断陷湖盆基底非线性沉降与Ⅱ型层序的形成—以冀东油田南堡凹陷为例,石油与天然气地质,2001,Vol 22(3):203—206
[116]. 威尔格斯,HK 等, 层序地层学原理—海平面变化综合分析,徐怀大等译。北京,石油工业出版社, 1993,47—256。
[117]. Bahorich M and farmer S.1995.3D Seismic discontinuity for faults and stratigraphic features:The coherence cube. The Leading Edge,14(10)
[118]. P.Lawrence,S,Aramco,Dhahran and S.Arabia ,Seismic attributes in the characterization of small-scale reservoir in Abqaiq Field,The Leading Edge 1998,17(4)
[119]. Quincy Chen and Steve Sidney, Seismic attribute technology for reservoir forecasting and monitoring . The Leading Edge,1997,16(5)
[120]. Catherine Lewis,Seismic attributes for reservoir monitoring :A feasibility study using forward modeling . The Leading Edge,1997,16(5)
[121]. Aitken J F, Howell J A. High resolution sequence stratigraphy : innovations, applications and future prospects[A]. Howell J A, Aitken J F, eds. High Resolution Sequence stratigraphy: Innovations and Applications[C]. Geological Society Special Publication, 1996, 104: 1~9.
[122]. Allen, P.A. and Allen, J.R., 1990. Basin Analysis – principles and applications. Blackwell Science, Oxford, 451 pages.
[123]. Vail P. R. Sequence Stratigraphy Interpretation using Sequence Stratigraphy: AAPG, 1987, 27/1—10
[124]. Galloway W. E. 1998, Genetic Stratigraphic, Sequence in Basin Analysis: AAPG, 73(2): 125—142
[125]. Van Wagoner JC et al., Siliciclastic Sequence Stratigraphy in well logs, cores and outcrops: Concepts for high-resolution correlation of time and facies: AAPG, Methods in Exploration Series. No.7, 1990, 55: 1-240
[126]. Vail P. R., Mitchum R M, 1977, Seismic Stratigraphy and global changes in sea level, Part 1: overview [A]. In: Payton C. E. Seismic Stratigraphy-application to hydrocarbon exploration[C]. AAPG Memoir, 26: 51-212
[127]. Posamentier, H.W. and Allen, G.P., 1993. Variability of the sequence stratigraphic model: effects of local basin factors. Sedimentary Geology, 86, 91-109.
[128]. Posamentier, H.W. and Allen, G.P., 1993. Siliciclastic sequence stratigraphic patterns in foreland ramp-type basins. Geology, 21, 455-488.
[129]. Vail, P.R., et al., 1977. Seismic stratigraphy and global changes of sea-level, Part 3 Relative changes of sea-level from coastal onlap. In, Payton, C.E. (ed.), Seismic stratigraphy, Applications to hydrocarbon exploration. AAPG. Memoir, 26, 63-81.
[130]. Emery, D. and Myers, K.J., 1996. Sequence stratigraphy. Blackwell Science, Oxford, 297 pages.
[131]. Mulholland, J.W., January, 1998, Sequence stratigraphy: Basic elements, concepts, and terminology: The Leading Edge,
[132]. Mulholland, J.W., June 1998, Sequence architecture: The Leading Edge, P. 767
[133]. Roksandic, M. M., February, 1994, The role of seismic stratigraphys in interpretation: The Leading Edge, P. 118
[134]. Friedman, G. M., J. E. Sanders, September 2000, Comments about the Relationships Between New Ideas and Geologic Terms in Stratigraphy and Sequence Stratigraphy with suggested Modifications: AAPG Bulletin, V. 84, No. 9, P.1274-1280
[135]. Brown, L. F., Jr., and W. L. Fisher, 1980, Seismic stratigraphic interpretation and Petroleum Exploration: AAPG Continuing Education Course Note Series, 16, 181 P
[136]. Nadon, G. C., J. A. (Toni) Simo, R. H., Dott, Jr., and C. W. Byers, July 2000, High-Resolution sequence stratigraphic analysis of the St. Peter sandstone and Glenwood formation (Middle Ordivocian), Michigan basin, U.S.A: AAPG Bulletin, V. 84, No. 7, P. 975-996
[137]. Gerald M. Friedman and John E. Sanders, September 2000, Comments about the relationships between new ideas and geologic terms in stratigraphy and sequence stratigraphy with suggested modifications: AAPG Bulletin, V. 84, No. 9, P. 1274-1280
[138]. Pinous, O. V., Y. N. Karogodin, S. V. Ershov, and D. L. Sahagian, June 1999, Sequence stratigraphy, facies, and sea level change of the Hauterivian productive complex, Priobskoe oil field (West Siberia): AAPG Bulletin, V. 83, No. 6, P. 972-989
[139]. Shanmugam, G., R. B. Bloch, J. E. Damuth, and R. J. Hodgkinson, April 1997, Basin-floor fans in the North Sea: Sequence stratigraphic models vs. sedimentary facies: reply: AAPG Bulletin, V. 81, No, 4, P. 666-672
[140]. Liangmiao (scott) Ye and Dennis Kerr, August 2000, Sequence Stratigraphy of the Middle Pennsylvanian Bartlesville sandstone, Northeastern Oklahoman: A case of an underfilled incised valley: AAPG Bulletin, V. 84, No. 8, P. 1185-1204
[141]. Robertson H. C., July 1998, Visualizing exploration targets through carbonate sequence stratigraphy: The Leading Edge, P. 891
© 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 |