非地震勘探方法在隐伏构造研究中的应用
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摘要
地震勘探方法是油气勘探开发中最主要的方法,但它有成本高,周期长,受某些地质条件和工作条件的影响等缺点。本文应用非地震勘探方法,以石亭江地区为例,进行隐伏构造研究,发现了隐伏断层,以之对地震资料从新认识与解释。体现非地震勘探方法在油气勘探中具有重要意义。对石亭江地区隐伏构造进行研究中,首次应用遥感、地球化学、地气法、测氡法,发现北西—南东向的走滑断层,在左行走滑断层尾部的左叠覆区形成萌芽阶段的菱形断陷。以非地震方法研究成果为指导,对地震剖面重新解释,在深部发现隐伏断层的踪迹。隐伏断层切穿工区蓬莱镇组的泥页岩盖层,油气保存条件受到一定程度的破坏。中浅层的天然气沿断裂渗漏到地表,是地表土壤中形成有机地球化学异常的原因。
(1) 遥感地质解线性构造与隐伏断层的存在有关。
(2) 土壤地球化学元素Hg、As、B、Bi、Sb和水地球化学K、F、Na、H_2SiO_3的含量异常大都沿着隐伏断层呈串珠状分布,或者出现在隐伏断层的交汇处。
(3) 在隐伏断层的上方出现了氡和地气异常。首次把地气法应用在河滩地区,有效的勘查到河滩卵石层下的隐伏断层,扩大了地气的应用范围。
(4) 运用原子力显微镜,证明了地气携带钠米颗粒向上运移,可能在地表土壤中积累形成地球化学异常的部分增量,为化探找矿和构造研究提供了依据。
(5) 非地震勘探方法不仅经济、快速、准确查明浅表层断裂,而且对地震资料解释也具有重要的参考价值。
Seismic exploration is the main way among the ways to explore petroleum. But it has high costs, long period and is being affected by some geology and working conditions and other defects. This thesis applied non-seismic methods, taking Shitingjiang area as example, to study concealed structure and find concealed fault. Through it, seismic datum got new interpretation. It shows the significance of non-seismic in petroleum exploration.
It is the first time to study concealed tectonism by remote sensing、 geochemistry、geogas、radiometric Rn in Shitingjiang area. And discover WN-ES concealed fault. And form germinative lozeng fault depression in the end of left folded area of left lateral strike-slip fault. Under the guidance of non-seismic study production, seismic profile got new interpretation. And by it, the track of concealed fault in deep was found. Drape of mud and shale of J_3P was pierced by concealed fault and it destroys petroleum reserved condition to some extent. The nature gas which lie supergene strata leak to surface along concealed fault is the reason why it formed geochemical abnormity in surface soil.
(1) Remote sensing geology interpretation linearity structure has some relation with existence of concealed fault.
(2) Most of the abnormal distribution of Geochemical elements are along concealed fault or appear at fault crossing .This geochemical elements contain Hg、 As、B、 Bi、 Sb in soil and K、F、Na、H_2SiO_3 in water.
(3) There is abnormal distribution of radiometric Rn over the concealed fault. It is the first time to use geogas in bottomland, and having explored concealed fault covered by screes, enlarged application field of geogas.
(4) By using AFM, it is proved that nanoparticle migrate upwards when it is carried by geogas, and probably form part increment of geochemical abnormity in
(1) 遥感地质解线性构造与隐伏断层的存在有关。
(2) 土壤地球化学元素Hg、As、B、Bi、Sb和水地球化学K、F、Na、H_2SiO_3的含量异常大都沿着隐伏断层呈串珠状分布,或者出现在隐伏断层的交汇处。
(3) 在隐伏断层的上方出现了氡和地气异常。首次把地气法应用在河滩地区,有效的勘查到河滩卵石层下的隐伏断层,扩大了地气的应用范围。
(4) 运用原子力显微镜,证明了地气携带钠米颗粒向上运移,可能在地表土壤中积累形成地球化学异常的部分增量,为化探找矿和构造研究提供了依据。
(5) 非地震勘探方法不仅经济、快速、准确查明浅表层断裂,而且对地震资料解释也具有重要的参考价值。
Seismic exploration is the main way among the ways to explore petroleum. But it has high costs, long period and is being affected by some geology and working conditions and other defects. This thesis applied non-seismic methods, taking Shitingjiang area as example, to study concealed structure and find concealed fault. Through it, seismic datum got new interpretation. It shows the significance of non-seismic in petroleum exploration.
It is the first time to study concealed tectonism by remote sensing、 geochemistry、geogas、radiometric Rn in Shitingjiang area. And discover WN-ES concealed fault. And form germinative lozeng fault depression in the end of left folded area of left lateral strike-slip fault. Under the guidance of non-seismic study production, seismic profile got new interpretation. And by it, the track of concealed fault in deep was found. Drape of mud and shale of J_3P was pierced by concealed fault and it destroys petroleum reserved condition to some extent. The nature gas which lie supergene strata leak to surface along concealed fault is the reason why it formed geochemical abnormity in surface soil.
(1) Remote sensing geology interpretation linearity structure has some relation with existence of concealed fault.
(2) Most of the abnormal distribution of Geochemical elements are along concealed fault or appear at fault crossing .This geochemical elements contain Hg、 As、B、 Bi、 Sb in soil and K、F、Na、H_2SiO_3 in water.
(3) There is abnormal distribution of radiometric Rn over the concealed fault. It is the first time to use geogas in bottomland, and having explored concealed fault covered by screes, enlarged application field of geogas.
(4) By using AFM, it is proved that nanoparticle migrate upwards when it is carried by geogas, and probably form part increment of geochemical abnormity in
引文
[1] 陈华慧.遥感地质学[M].地质出版社,1984.
[2] 李永颐.遥感地质学fM.重庆大学出版社,1990.
[3] 郭德方.油气资源遥感[M].浙江大学出版社,1995.
[4] 孙成权,张欣利.遥感技术在油气勘探中的应用[M].遥感技术与应用,1992,7(2):32-38.
[5] 韩玲,吴汉宁.TM与ETM影像融合用于地质构造解译[J].应用技术,2004.2:35-37.
[6] 王桂宏,张友炭,岳兵,叶勇.柴达木盆地第四系气田构造遥感信息提取[J]:石油勘探与开发:1998,25(4):7-9.
[7] 隋志龙,李德威,黄春霞.断裂构造的遥感研究方法综述[J]。地理学与国土研究:2002,18(8),34-37.
[8] 周东岱,叶水盛,王世称.基于GIS遥感区域构造的空间信息集成研究[J].地球科学——中国地质大学学报:2002,27(1):55-58.
[9] 胡明星,郭达志,盛业华.借助地理信息系统从卫星遥感资料提取区域构造应力场方向[J].中国矿业:1998,7(4):38-42.
[10] 陈庆涛,杨武年,易显志,泼国梁.卫星遥感TM图像在川东地地貌解译研究中的应用[J],成都理工学报; 2000,27(3):318-323.
[11] 丁树柏,王文志.卫星遥感在石油勘查中的应用及其前景[J].中国航天:1991年7月;:7-10
[12] 雷莉萍,何晓云,胡德永,陈志军.遥感地质线性体与化探信息数字复合处理提取金矿控矿构造信息[J].遥感技术与应用:1993,8(2):19-24.
[13] 徐振宇,房桂祥.遥感技术在基岩山区找水中的应用[J].地下水:1995,17(3):119-12.
[14] 刘燕君,冯钟葵、宋丹.卫星TM6波段对油气藏的指示意义[J].环境遥感,1994,9(1):38-44.
[15] 刘燕君,金丽芳,程承旗。遥感图像上的油气晕[J].环境遥感,1992,7(1):59-64。
[16] 历青,张红.重磁、遥感在地质构造解释中的应用[J].国外地质勘探技术,1999,(6):6-10.
[17] 叶和飞.卫星遥感技术在中国陆上油气勘探的应用[J].中国航天,1995,(1):5-10.
[18] 黄熏德,吴郁彦.地球化学找矿[M],地质出版社.1984.
[19] 王崇云.地球化学找矿基础[M].地质出版社.1987.
[20] 黄薰德,吴郁彦.地球化学找矿[M].地质出版社.1986.
[21] 谢学锦,邵跃,王学求.走向21世纪矿产勘查地球化学[M].地质出版社.1999.
[22] 彭头平,彭冰霞,李晓用等.土壤地球化学找矿实验性研究[J].大地构造与成矿学,2002,26(4):442—447.
[23] 张炳熹.面向21世纪的应用地球化学——谢学锦院士从事地球化学研究50周年[M].北京:地质出版社,2002.
[24] 李绍强,潘成泽.东昆仑—阿尔金构造地球化学特征[J].新疆地质,2001,19(3):189-193.
[25] 杨明银,崔斌,魏世昆等.鄂东南地区东西断裂带动力学及地球化学特征[J].湖北地质,2001,15(2):3-10.
[26] 卫敬生.利用土壤吸附汞寻找隐伏断裂破碎带的应用实例[J].物探与化探,2001 25(1):78-80.
[27] 彭头平,彭冰霞,李晓勇.土壤地球化学找矿实验性研究[J].大地构造与成矿学,2002,26(4):442-447.
[28] 王和胜.化探异常筛选及查证工作方法[J].辽宁地质,1998,(4):277-284.
[29] 文冬光,沈照理,钟佐棠.地球化学模拟及其在水文地质中的应用[J].地质科技情报,??1995,14(1):99-104.
[30] 曾溅辉.地下水地球化学模拟[J].地质论评,1993,39(6):490-496.
[31] A.Giblin, R. Mazzucchelli著,刘风山译.地下水地球化学在西澳黑旗地区勘查中的应用[J].译自(Australian Journal of Earth Sciences).1997 V.44, p433—443,
[32] 王多义,杨庆景,邓美洲等,绵竹酿春池温泉新区地热地质祥查报告[M].成都理工大学.2005.
[33] 上官志冠,高清武,赵慈平.腾冲热海地区NW向活动性断裂的地球化学证据[J].地震地质,2004 26(1):46-51.
[34] 李正文,贺振华.堪查技术工程学[M].地质出版社,2003.
[35] 贾文懿,方方,苗放.核地球物理的理论与实践[M].四川大学出版社,2001.
[36] 贾文懿,方方,周蓉生等.理想条件下氡及其子体运移规律研究[J].成都理工学院学报,1999,26(1):34-37.
[37] 贾文懿,方方,周蓉生等.氡及其子体向上运移的内因与团簇现象[J].成都理工学院学报,1999,26(2):171-175.
[38] 贾文懿,唐红,葛君伟等.氡气测量及其在寻找基岩地下水、地热和工程地质中的应用[J].物探与化探,1987,11(5):21-29.
[39] 葛君伟,贾文懿.放射性方法在我国寻找油气藏中的应用进展[J].物探与化探,1992,16(4):259-266.
[40] 贾文懿.放射性勘探的科技进展[J].物探与化探,1989,13(5):381-385.
[41] 刘太平,史良骥.断层土壤氡观测方法的综合应用[J].四川地震,1998,(3):59-64.
[42] 童纯菡.元素迁移的模拟模型实验[J].核技术,2001:24(6):449-455.
[43] 张立德,牟季美.开拓原子和物质中间领域—钠米微粒与钠米固体[J].物理,1992,21(3):167-173.
[44] 解思深.超微粒子物理[J].物理,1989,19(10):577-582.
[45] 章振根.钠米科技与地学研究的思考[J].大地构造与成矿学,1995,19(1):77-82.
[46] 伍宗华,金仰芬,古平等.地气测量原理及其在地质勘查中的应用[J].物探与化探,1996,20(4)259-264.
[47] 曹建劲.地气测量研究现状及影响因素[J].湖南地质,2001,20(2)154-156.
[48] 西南石油局第二物探大队.四川省德阳市孝泉地区三维地震油气勘探成果报告2002.
[49] 西南石油局第二物探大队.四川省德阳市孝泉—新场地区浅中层地震研究成果报告1995.
[50] 徐怀大,王世风,陈开远.地震地层学解释基础[M],中国地质大学出版社,1990
[51] 刘树根,罗志立,戴苏兰等.磷灰石裂变径迹技术及其在龙门山冲断带研究中的应用[J],1993.
[52] 罗志立,刘树根,赵锡奎等.试论C型俯冲带及对中国西部造山带形成的作用[J].1993
[53] 刘树根,罗志立,曹树恒.一种新的陆内俯冲类型——龙门山型俯冲成因机制研究[J].油实验地质1991,13(4):314-324.
[54] 罗志立,赵锡奎,刘树根等:龙门山造山带的崛起和四川盆地的形成与演化[M].成都科技大学出版社,1994.
[55] 龙学明.龙门山中北段地史发展的若干问题[J].成都地质学院学报,1991,18(1):8-15.
[56] 周文.裂缝性油气储集层评价方法[M].四川科学技术出版社,1998.
[57] 夏响华,陈银节,姚俊梅等.川西及松辽南部油气微渗漏动力学模拟[J].物探与化探,2003:27(6):458-460
[58] 吴向华,程同锦,邓天龙.油气化探分析检测技术现状及发展趋势[J].天然气地球科学,2005;16(1):78-81
[59] 姜洪训.综合地质物探化探多参数直接探测油气理论方法与效果[M].陕西科学技术出版社,1994.
[60] 杨育斌,张金来,吴学明.油气地球化学勘查[M].中国地质大学出版社,1995.
[61] 刘树根,罗志立,赵锡奎等.龙门山造山带—川西前陆盆地系统形成的动力学模式冀??模拟研究[J].石油实验地质,2003,25(5):432-438.
[62] 罗志立,刘树根,雍自权等.中国陆内俯冲(C-俯冲)观点的形成和发展[J].新疆石油地质,2003,24(1):1-7.
[63] 马文璞.区域构造解析—方法理论和中国板块构造[M].地质出版社,1992.
[64] 中国地质大学构造地质学教研室,构造地质学进展[M].地震出版社,1994.
[65] 李四光.地质力学的方法与实践—地质力学概论[M].地质出版社,1999.
[66] 王多义,吴征,朱永明.景谷盆地遥感地质解译及原盆地恢复[J]。成都理工大学学报,2003,30(6):597-602。
[67] 杨诚.新场气田蓬莱镇气藏储层随机建模研究[D].成都理工大学能源学院,2005.
[68] 杨克明.非常规油气藏形成的机理及关键的开发技术-以川西凹陷上三叠统气藏为例[D].成都理工大学能源学院,2005.
[69] Aline saintot, Jacques Angelier, Jean Chorowicz. Mechanical significance of structure patterns identified by remote sensing studies: a multiscale analysis of tectonic structure in Crimea[J]. tectonophysics:313 (1999):187-218.
[70] Jagannathan Krishnamurthy, Arul Mani, Venkatakrisshnan Jayaraman. Groundwater resources development in hard rock terrain-an approach using remote sensing and GIS techniques[J].JAG, 2000 (2):204-215
[71] Crispin katongo, Christian KOeberl, Wolf Uwe Reimold. Remote sensing, field studies, petrography, and geochemistry of rocks in central Zambia: no evidence of a meteoritic impact in the area of the Lukanga Swamp[J].Journal of African Earth Sciences, 2002 (35):365-384.
[72] Yunxing Cao, Alan Davis, Ruixuin Liu. The influence of tectonic deformation on some geochemical properties of coals-a possible indicator of outburst potential[J]. International Journal of Coal Geology. 2003(53):69-79.
[73] Detlev Rettenmaier, Vlad Giurgea, Heinz Hotzl. The AIGIO dilling project(Aigion. Greece): interpretation of the litho-log in the context of regional geology and tectonics[J].Geosciense, 2004(336):415-423.
[74] Daniel Strawn, Harvey Donor, Mavrik Zavarin. Microscale investigation into the geochemistry of arsenic, selenium, and iron in soil developed in Pyritic shale materials[J]. Geoderma, 2002(108):237-257.
[75] K. Jill Hammond. James P. Evans. Geochemistry, mineralization, structure, and permeabilityof a normal-faule zone, Casino mine, Alligator Ridgedistrict, north central Nevada[J]. Journal of Structural Geology, 2003(25)717-736.
[76] varhegyi A et al. Experimental study of radon transport in water as testfor a transportation microbublle model[J], journal of applied geophsics, 1992, vol. 29.
[77] Price L C. critical overview and proposed working model of surface geochemical exploration[J]. Unconventional methods in exploration for petroleum and naturalgasⅣ. Southern Methodist Univ. press, 1986.
[78] Ma Wan-yun, Xue Meng, Zhang jun. Ultrasensitive determination of gold in geogasby laser excited atomic fluorescence spectrometry. Spectrochimica Acta PartB, 1998, (53):1421-1425.
[79] Ziyong Zhou, Shu Tao, Fulin Xu. A physical-mathematical model for the transport of heavy metals and toxic matter from point sources by geogas microbubbles. Ecological Modelling2003(161):139-149.
[80] N。Kulagin. Theory of electronic structure of rare earths and actinides in Rn~(+n)[L]clusers[J]: PhysicaB, 1998(245):52-60.
[81] AdamR. Hutter. Spatial and temporal variations of soil gas ~(220)Rn and ~(220)Rn at two sites in new jersey[J]. Enviroment Internation, 1996(22):455-469.
[82] Changyuan Qin, Constantinos Papazachos, Eleftheria Papadimitriou. Velocity field for crustal deformation in China derived from seismic moment tensor??summation ofearthquakes[J]. Tectonophysics, 2002, 359 (1) : 29-46 .
[83] LuoZhili, Liu Shugen. Comments on the citation of the term "foreland basin" in the petroliferous basins of central and westernChina—a review on the development of Chinese petroleum tectonics [J]. Geological Review, 2002. 48 (4): 398- 407.
[2] 李永颐.遥感地质学fM.重庆大学出版社,1990.
[3] 郭德方.油气资源遥感[M].浙江大学出版社,1995.
[4] 孙成权,张欣利.遥感技术在油气勘探中的应用[M].遥感技术与应用,1992,7(2):32-38.
[5] 韩玲,吴汉宁.TM与ETM影像融合用于地质构造解译[J].应用技术,2004.2:35-37.
[6] 王桂宏,张友炭,岳兵,叶勇.柴达木盆地第四系气田构造遥感信息提取[J]:石油勘探与开发:1998,25(4):7-9.
[7] 隋志龙,李德威,黄春霞.断裂构造的遥感研究方法综述[J]。地理学与国土研究:2002,18(8),34-37.
[8] 周东岱,叶水盛,王世称.基于GIS遥感区域构造的空间信息集成研究[J].地球科学——中国地质大学学报:2002,27(1):55-58.
[9] 胡明星,郭达志,盛业华.借助地理信息系统从卫星遥感资料提取区域构造应力场方向[J].中国矿业:1998,7(4):38-42.
[10] 陈庆涛,杨武年,易显志,泼国梁.卫星遥感TM图像在川东地地貌解译研究中的应用[J],成都理工学报; 2000,27(3):318-323.
[11] 丁树柏,王文志.卫星遥感在石油勘查中的应用及其前景[J].中国航天:1991年7月;:7-10
[12] 雷莉萍,何晓云,胡德永,陈志军.遥感地质线性体与化探信息数字复合处理提取金矿控矿构造信息[J].遥感技术与应用:1993,8(2):19-24.
[13] 徐振宇,房桂祥.遥感技术在基岩山区找水中的应用[J].地下水:1995,17(3):119-12.
[14] 刘燕君,冯钟葵、宋丹.卫星TM6波段对油气藏的指示意义[J].环境遥感,1994,9(1):38-44.
[15] 刘燕君,金丽芳,程承旗。遥感图像上的油气晕[J].环境遥感,1992,7(1):59-64。
[16] 历青,张红.重磁、遥感在地质构造解释中的应用[J].国外地质勘探技术,1999,(6):6-10.
[17] 叶和飞.卫星遥感技术在中国陆上油气勘探的应用[J].中国航天,1995,(1):5-10.
[18] 黄熏德,吴郁彦.地球化学找矿[M],地质出版社.1984.
[19] 王崇云.地球化学找矿基础[M].地质出版社.1987.
[20] 黄薰德,吴郁彦.地球化学找矿[M].地质出版社.1986.
[21] 谢学锦,邵跃,王学求.走向21世纪矿产勘查地球化学[M].地质出版社.1999.
[22] 彭头平,彭冰霞,李晓用等.土壤地球化学找矿实验性研究[J].大地构造与成矿学,2002,26(4):442—447.
[23] 张炳熹.面向21世纪的应用地球化学——谢学锦院士从事地球化学研究50周年[M].北京:地质出版社,2002.
[24] 李绍强,潘成泽.东昆仑—阿尔金构造地球化学特征[J].新疆地质,2001,19(3):189-193.
[25] 杨明银,崔斌,魏世昆等.鄂东南地区东西断裂带动力学及地球化学特征[J].湖北地质,2001,15(2):3-10.
[26] 卫敬生.利用土壤吸附汞寻找隐伏断裂破碎带的应用实例[J].物探与化探,2001 25(1):78-80.
[27] 彭头平,彭冰霞,李晓勇.土壤地球化学找矿实验性研究[J].大地构造与成矿学,2002,26(4):442-447.
[28] 王和胜.化探异常筛选及查证工作方法[J].辽宁地质,1998,(4):277-284.
[29] 文冬光,沈照理,钟佐棠.地球化学模拟及其在水文地质中的应用[J].地质科技情报,??1995,14(1):99-104.
[30] 曾溅辉.地下水地球化学模拟[J].地质论评,1993,39(6):490-496.
[31] A.Giblin, R. Mazzucchelli著,刘风山译.地下水地球化学在西澳黑旗地区勘查中的应用[J].译自(Australian Journal of Earth Sciences).1997 V.44, p433—443,
[32] 王多义,杨庆景,邓美洲等,绵竹酿春池温泉新区地热地质祥查报告[M].成都理工大学.2005.
[33] 上官志冠,高清武,赵慈平.腾冲热海地区NW向活动性断裂的地球化学证据[J].地震地质,2004 26(1):46-51.
[34] 李正文,贺振华.堪查技术工程学[M].地质出版社,2003.
[35] 贾文懿,方方,苗放.核地球物理的理论与实践[M].四川大学出版社,2001.
[36] 贾文懿,方方,周蓉生等.理想条件下氡及其子体运移规律研究[J].成都理工学院学报,1999,26(1):34-37.
[37] 贾文懿,方方,周蓉生等.氡及其子体向上运移的内因与团簇现象[J].成都理工学院学报,1999,26(2):171-175.
[38] 贾文懿,唐红,葛君伟等.氡气测量及其在寻找基岩地下水、地热和工程地质中的应用[J].物探与化探,1987,11(5):21-29.
[39] 葛君伟,贾文懿.放射性方法在我国寻找油气藏中的应用进展[J].物探与化探,1992,16(4):259-266.
[40] 贾文懿.放射性勘探的科技进展[J].物探与化探,1989,13(5):381-385.
[41] 刘太平,史良骥.断层土壤氡观测方法的综合应用[J].四川地震,1998,(3):59-64.
[42] 童纯菡.元素迁移的模拟模型实验[J].核技术,2001:24(6):449-455.
[43] 张立德,牟季美.开拓原子和物质中间领域—钠米微粒与钠米固体[J].物理,1992,21(3):167-173.
[44] 解思深.超微粒子物理[J].物理,1989,19(10):577-582.
[45] 章振根.钠米科技与地学研究的思考[J].大地构造与成矿学,1995,19(1):77-82.
[46] 伍宗华,金仰芬,古平等.地气测量原理及其在地质勘查中的应用[J].物探与化探,1996,20(4)259-264.
[47] 曹建劲.地气测量研究现状及影响因素[J].湖南地质,2001,20(2)154-156.
[48] 西南石油局第二物探大队.四川省德阳市孝泉地区三维地震油气勘探成果报告2002.
[49] 西南石油局第二物探大队.四川省德阳市孝泉—新场地区浅中层地震研究成果报告1995.
[50] 徐怀大,王世风,陈开远.地震地层学解释基础[M],中国地质大学出版社,1990
[51] 刘树根,罗志立,戴苏兰等.磷灰石裂变径迹技术及其在龙门山冲断带研究中的应用[J],1993.
[52] 罗志立,刘树根,赵锡奎等.试论C型俯冲带及对中国西部造山带形成的作用[J].1993
[53] 刘树根,罗志立,曹树恒.一种新的陆内俯冲类型——龙门山型俯冲成因机制研究[J].油实验地质1991,13(4):314-324.
[54] 罗志立,赵锡奎,刘树根等:龙门山造山带的崛起和四川盆地的形成与演化[M].成都科技大学出版社,1994.
[55] 龙学明.龙门山中北段地史发展的若干问题[J].成都地质学院学报,1991,18(1):8-15.
[56] 周文.裂缝性油气储集层评价方法[M].四川科学技术出版社,1998.
[57] 夏响华,陈银节,姚俊梅等.川西及松辽南部油气微渗漏动力学模拟[J].物探与化探,2003:27(6):458-460
[58] 吴向华,程同锦,邓天龙.油气化探分析检测技术现状及发展趋势[J].天然气地球科学,2005;16(1):78-81
[59] 姜洪训.综合地质物探化探多参数直接探测油气理论方法与效果[M].陕西科学技术出版社,1994.
[60] 杨育斌,张金来,吴学明.油气地球化学勘查[M].中国地质大学出版社,1995.
[61] 刘树根,罗志立,赵锡奎等.龙门山造山带—川西前陆盆地系统形成的动力学模式冀??模拟研究[J].石油实验地质,2003,25(5):432-438.
[62] 罗志立,刘树根,雍自权等.中国陆内俯冲(C-俯冲)观点的形成和发展[J].新疆石油地质,2003,24(1):1-7.
[63] 马文璞.区域构造解析—方法理论和中国板块构造[M].地质出版社,1992.
[64] 中国地质大学构造地质学教研室,构造地质学进展[M].地震出版社,1994.
[65] 李四光.地质力学的方法与实践—地质力学概论[M].地质出版社,1999.
[66] 王多义,吴征,朱永明.景谷盆地遥感地质解译及原盆地恢复[J]。成都理工大学学报,2003,30(6):597-602。
[67] 杨诚.新场气田蓬莱镇气藏储层随机建模研究[D].成都理工大学能源学院,2005.
[68] 杨克明.非常规油气藏形成的机理及关键的开发技术-以川西凹陷上三叠统气藏为例[D].成都理工大学能源学院,2005.
[69] Aline saintot, Jacques Angelier, Jean Chorowicz. Mechanical significance of structure patterns identified by remote sensing studies: a multiscale analysis of tectonic structure in Crimea[J]. tectonophysics:313 (1999):187-218.
[70] Jagannathan Krishnamurthy, Arul Mani, Venkatakrisshnan Jayaraman. Groundwater resources development in hard rock terrain-an approach using remote sensing and GIS techniques[J].JAG, 2000 (2):204-215
[71] Crispin katongo, Christian KOeberl, Wolf Uwe Reimold. Remote sensing, field studies, petrography, and geochemistry of rocks in central Zambia: no evidence of a meteoritic impact in the area of the Lukanga Swamp[J].Journal of African Earth Sciences, 2002 (35):365-384.
[72] Yunxing Cao, Alan Davis, Ruixuin Liu. The influence of tectonic deformation on some geochemical properties of coals-a possible indicator of outburst potential[J]. International Journal of Coal Geology. 2003(53):69-79.
[73] Detlev Rettenmaier, Vlad Giurgea, Heinz Hotzl. The AIGIO dilling project(Aigion. Greece): interpretation of the litho-log in the context of regional geology and tectonics[J].Geosciense, 2004(336):415-423.
[74] Daniel Strawn, Harvey Donor, Mavrik Zavarin. Microscale investigation into the geochemistry of arsenic, selenium, and iron in soil developed in Pyritic shale materials[J]. Geoderma, 2002(108):237-257.
[75] K. Jill Hammond. James P. Evans. Geochemistry, mineralization, structure, and permeabilityof a normal-faule zone, Casino mine, Alligator Ridgedistrict, north central Nevada[J]. Journal of Structural Geology, 2003(25)717-736.
[76] varhegyi A et al. Experimental study of radon transport in water as testfor a transportation microbublle model[J], journal of applied geophsics, 1992, vol. 29.
[77] Price L C. critical overview and proposed working model of surface geochemical exploration[J]. Unconventional methods in exploration for petroleum and naturalgasⅣ. Southern Methodist Univ. press, 1986.
[78] Ma Wan-yun, Xue Meng, Zhang jun. Ultrasensitive determination of gold in geogasby laser excited atomic fluorescence spectrometry. Spectrochimica Acta PartB, 1998, (53):1421-1425.
[79] Ziyong Zhou, Shu Tao, Fulin Xu. A physical-mathematical model for the transport of heavy metals and toxic matter from point sources by geogas microbubbles. Ecological Modelling2003(161):139-149.
[80] N。Kulagin. Theory of electronic structure of rare earths and actinides in Rn~(+n)[L]clusers[J]: PhysicaB, 1998(245):52-60.
[81] AdamR. Hutter. Spatial and temporal variations of soil gas ~(220)Rn and ~(220)Rn at two sites in new jersey[J]. Enviroment Internation, 1996(22):455-469.
[82] Changyuan Qin, Constantinos Papazachos, Eleftheria Papadimitriou. Velocity field for crustal deformation in China derived from seismic moment tensor??summation ofearthquakes[J]. Tectonophysics, 2002, 359 (1) : 29-46 .
[83] LuoZhili, Liu Shugen. Comments on the citation of the term "foreland basin" in the petroliferous basins of central and westernChina—a review on the development of Chinese petroleum tectonics [J]. Geological Review, 2002. 48 (4): 398- 407.