海洋油气渗漏烃蚀变带的地球物理检测及在中国海区的应用   总被引：6，自引：0，他引：6       下载免费PDF全文

郝天珧  朱振海  张明华  黄晓霞  宋海斌  江为为 《地球物理学报》2001,44(2):245-254

针对海洋油气渗漏可以在近地表沉积层中引起的一系列烃蚀变效应，本文讨论了利用不同手段，分层次进行检测的几种方法.利用烃蚀变带所产生的磁异常现象，在平面上圈定油气渗漏的分布范围，进而寻找海底油气藏.同时，钻井岩芯岩屑的磁性质测量结果可以从剖面上预测下伏岩层的含油气性.最终利用X射线衍射方法(XRD)对典型层位岩石样品的物相测量，进行烃蚀变矿物组合分析并通过镜下鉴定作进一步的综合判断.对渤海海域烃蚀变效应的磁法检测研究结果与遥感及其他方法的研究结果有很好的一致性.对南海3口钻井岩芯岩屑的磁性测量结果表明：两口有油气前景而另一口没有异常.这与实际结果十分一致，同时表明该方法在海区同样可以具有良好效果.  相似文献   

中国南方古油藏与油气评价   总被引：10，自引：4，他引：10  

王守德  郑冰 《海相油气地质》1997,2(1):44-50

从早古生代至中、新生代，中国南部确实形成过相当数量和相当规模的油气藏。而后经较高的演化和多期次的构造运动，最终成为古油藏。如麻江、瓮安、泰山、米仓山、天井山、中和、龙街及小古山等古油藏。它展示了分布于中国南方各地质时期及各种地质条件下，油气藏形成、发展的全过程及其规律，充分揭示了油气藏的成藏、发展条件及破坏因素。因而运用其成藏规律，可以为油气远景评价、勘探部署做出重要的决策。  相似文献   

应用流体包裹体研究致密砂岩储层多期油气充注历史——以鄂尔多斯盆地镇泾地区延长组长8段砂岩为例          下载免费PDF全文

杨鹏  张立宽  曹斌风  胡才志  邱桂强  马立元  尹伟  李超  雷裕红 《地质科学》2016,(3):946-960

本文以鄂尔多斯盆地西南缘镇泾地区延长组长8段致密砂岩储层为例,利用流体包裹体岩相学、微束荧光光谱及显微测温等分析方法, 厘定油气充注期次和时间,同时结合储层成岩演化,探讨储层致密化与油气成藏过程。研究表明,储层孔隙沥青呈黄色和蓝白色荧光, 并以蓝白色为主;石油包裹体呈黄色、黄绿色及蓝白色荧光,并以后两者居多。与黄色荧光石油包裹体同期的盐水包裹体均一温度主峰为 80℃～90℃; 而与黄绿色和蓝白色荧光石油包裹体同期的盐水包裹体均一温度主峰分别为105℃～115℃和110℃～120℃。研究区储层主要经历了3期烃类充注：第一期发生在早白垩世早期（138～130Ma）,表现为少量的低熟油充注;第二期发生在早白垩世晚期（124～105Ma）,为关键成藏期,与大规模成熟油充注相关; 第三期发生在晚白垩世（85～73Ma）,古油藏发生调整,再次成藏。储层早成岩阶段以机械压实、薄膜状绿泥石、高岭石及微晶方解石胶结为主,在中高孔渗条件下发生了早期石油充注;随着继续压实,石英加大、孔隙填充绿泥石、高岭石及亮晶方解石胶结发育,储层逐渐致密化 晚期石油在低渗致密储层内的运聚成藏主要受早期烃类充注路径控制。  相似文献   

羌塘盆地昂达尔错白云岩古油藏地质特征及成藏条件     

彭清华  杜佰伟  谢尚克  郑博 《海相油气地质》2016,(3):48-54

昂达尔错白云岩古油藏位于羌塘盆地南羌塘坳陷,是羌塘盆地规模最大的古油藏带,对该区油气勘探具有重要意义。依据铸体薄片、储层物性、沥青族组分分析,剖析了白云岩古油藏地质特征。分析结果表明,昂达尔错古油藏的储集体可归类为低孔—低渗型到中孔—中渗型储层,为较好储层类型;其石油族组分呈现饱和烃含量低、非烃+沥青质含量高的特征,为芳香沥青型、芳香环烷型石油。划分出两套生储盖组合,其中的下侏罗统曲色组—中侏罗统布曲组组合为较好的生储盖组合类型,具有较好的勘探远景。认为古油藏在晚侏罗世成藏,在喜马拉雅期遭受逆冲破坏。  相似文献   

巴西深水盆地对比及油气成藏规律分析     

于璇  侯贵廷  代双河  韩宇春  谢结来 《海相油气地质》2016,(1):61-72

对巴西东部被动大陆边缘深水盆地群的构造演化和石油地质特征进行了系统性的对比分析,研究表明,盆地群经历了4个演化阶段:前裂谷阶段、同裂谷阶段、局限海过渡阶段和被动大陆边缘漂移阶段。受区域构造应力场、膏盐层、火山岩等方面的影响,各盆地表现出不同的盆地结构和构造样式,而膏盐层的发育对于油气成藏起着关键作用。这些盆地中,主要发育了三套烃源岩、三套储层和三套区域盖层,并形成了三种油气成藏类型:盐下裂谷地堑内的构造油气藏,膏盐层上下的碳酸盐岩油气藏,以及盐上的浊积岩构造—地层复合油气藏。根据成藏规律分析,并考虑各盆地的勘探现状,按勘探潜力由好到差的顺序将盆地划分为三类,指出Ⅰ、Ⅱ类潜力区应是主要勘探方向,具有广阔的油气资源前景。  相似文献   

Deep-seated faults and hydrocarbon leakage in the Snøhvit Gas Field,Hammerfest Basin,Southwestern Barents Sea     

《Marine and Petroleum Geology》2016

High-quality 3D seismic data are used to analyze the history of fault growth and hydrocarbon leakage in the Snøhvit Field, Southwestern Barents Sea. The aim of this work is to evaluate tectonic fracturing as a mechanism driving hydrocarbon leakage in the study area. An integrated approach was used which include seismic interpretation, fault modeling, displacement analysis and multiple seismic attribute analysis.The six major faults in the study area are dip-slip normal faults which are characterized by complex lateral and vertical segmentation. These faults are affected by three main episodes of fault reactivation in the Late Jurassic, Early Cretaceous and Paleocene. Fault reactivation in the study area was mainly through dip-linkage. The throw-distance plots of these representative faults also revealed along-strike linkage and multi-skewed C-type profiles. The faults evolved through polycyclic activity involving both blind propagation and syn-sedimentary activity with their maximum displacements recorded at the reservoir zone. The expansion and growth indices provided evidence for the interaction of the faults with sedimentation throughout their growth history.Soft reflections or hydrocarbon-related high-amplitude anomalies in the study area have negative amplitude, reverse polarity and are generally unconformable with structural reflectors. The interpreted fluid accumulations are spatially located at the upper tips of the major faults and gas chimneys. Four episodes of fluid migration are inferred and are linked to the three phases of fault reactivation and Neogene glaciations. Hydrocarbon leakage in the Snøhvit Gas Field is driven by tectonic fracturing, uplift, and erosion. The interpreted deep-seated faults are the main conduits for shallow hydrocarbon accumulations observed on seismic profiles.  相似文献   

Pore structure of Cambrian shales from the Sichuan Basin in China and implications to gas storage     

《Marine and Petroleum Geology》2016

The microstructure of black siliceous shale from the lower Cambrian Niutitang Formation, Sichuan Basin in China was investigated by the combination of field emission scanning electron microscope (FE-SEM) and argon ion beam milling. The nanometer-to micrometer-scale pore systems of shales are an important control on gas storage and fluid migration. In this paper, the organic porosity in shale samples within oil and gas window has been investigated, and the formation mechanism and diagenetic evolution of nanopores have been researched.FE-SEM reveals five pore types that are classified as follows: organic nanopores, pores in clay minerals, nanopores of framework minerals, intragranular pores in microfossils, and microfractures. Numerous organic nanopores are observed in shales in the gas window, whereas microfractures can be seen within the organic matter of shales in the oil window. Microfractures in oil window shales could be attributed to pressure buildup in the organic matter when incompressible liquid hydrocarbon are generated, and the orientation of microfractures is probably parallel to the bedding and strength anisotropy of the formation. Pores in clay minerals are always associated with the framework of clay flakes, and develop around rigid mineral grains because the pressure shadows of mineral grains protect pores from collapse, and the increasing of silt content would lead to an increase in pressure shadows and improve porosity. Nanopores of rock framework are probably related to dissolution by acidic fluids from hydrocarbon generation, and the dissolution-related pores promote permeability of shales. Porosity in the low-TOC, low-thermal-maturity shales contrast greatly with those of high-TOC, high-thermal-maturity shales. While the high-TOC shales contain abundant organic microporosity, the inorganic pores can contribute a lot to the porosity of the low-TOC shales.  相似文献   

Study on the Cretaceous turbidite and reservoir features in the Qingshankou Formation in northern Songliao Basin,NE China     

《Marine and Petroleum Geology》2016

Based on analysis of well and drilling data, cores, sediment grains and 3D seismic data, four types of turbidites–slope fan, channelized, laminated and sublacustrine fan turbidite–are identified in Members 1 and 2 of the Qingshankou Formation in northern Songliao Basin. The slope fan turbidite is located in Members 1 and 2 of the Qingshankou Formation. It is dominated by silt and fine sand and is distributed in an SN-trending ribbon zone along the slope break at delta front in the western part of the basin. The channelized turbidite is located at the bottom of Member 1 of the Qingshankou Formation. It is dominated by silt and fine sand and is distributed in an SN-trending strip-shaped zone along the Qijia-Gulong sag, with funnel-shaped sublacustrine fans at the end. The laminated turbidite body is located in Member 2 of the Qingshankou Formation. It is dominated by siltstone and argillaceous siltstone and is distributed continuously in a tongue-shaped zone along the northern delta front towards the lacustrine region, with belt-like distributaries at the central part and sublacustrine fans at the end. Low-permeability and low-yield lithologic reservoirs are formed near the delta front within the slope fan turbidite and channelized turbidite. There are “sweet spots” in local regions, where reservoir reform techniques are required to attain high industrial yields. Laminated turbidite and sublacustrine fans can form unconventional and continuous reservoirs that generally have no natural productivity; industrial production is impossible until horizontal drilling and multistage volume fracturing are employed. Therefore, the research results are important to the exploration of unconventional oil and gas reservoirs in northern Songliao Basin.  相似文献   

Impact of high water pressure on oil generation and maturation in Kimmeridge Clay and Monterey source rocks: Implications for petroleum retention and gas generation in shale gas systems     

《Marine and Petroleum Geology》2016

This study presents results for pyrolysis experiments conducted on immature Type II and IIs source rocks (Kimmeridge Clay, Dorset UK, and Monterey shale, California, USA respectively) to investigate the impact of high water pressure on source rock maturation and petroleum (oil and gas) generation. Using a 25 ml Hastalloy vessel, the source rocks were pyrolysed at low (180 and 245 bar) and high (500, 700 and 900 bar) water pressure hydrous conditions at 350 °C and 380 °C for between 6 and 24 h. For the Kimmeridge Clay (KCF) at 350 °C, Rock Eval HI of the pyrolysed rock residues were 30–44 mg/g higher between 6 h and 12 h at 900 bar than at 180 bar. Also at 350 °C for 24 h the gas, expelled oil, and vitrinite reflectance (VR) were all reduced by 46%, 61%, and 0.25% Ro respectively at 900 bar compared with 180 bar. At 380 °C the retardation effect of pressure on the KCF was less significant for gas generation. However, oil yield and VR were reduced by 47% and 0.3% Ro respectively, and Rock Eval HI was also higher by 28 mg/g at 900 bar compared with 245 bar at 12 h. The huge decrease in gas and oil yields and the VR observed with an increase in water pressure at 350 °C for 24 h and 380 °C for 12 h (maximum oil generation) were also observed for all other times and temperatures investigated for the KCF and the Monterey shale. This shows that high water pressure significantly retards petroleum generation and source rock maturation. The retardation of oil generation and expulsion resulted in significant amounts of bitumen and oil being retained in the rocks pyrolysed at high pressures, suggesting that pressure is a possible mechanism for retaining petroleum (bitumen and oil) in source rocks. This retention of petroleum within the rock provides a mechanism for oil-prone source rocks to become potential shale gas reservoirs. The implications from this study are that in geological basins, pressure, temperature and time will all exert significant control on the extent of petroleum generation and source rock maturation for Type II source rocks, and that the petroleum retained in the rocks at high pressures may explain in part why oil-prone source rocks contain the most prolific shale gas resources.  相似文献   

北美东部被动大陆边缘盆地的分段性与油气勘探          下载免费PDF全文

聂国权李小盼  何登发 《地质科学》2021,56(1):321-339

北美东部被动大陆边缘是世界上最古老的完整被动大陆边缘之一,是研究被动大陆边缘发育演化的天然实验室。本文在大量国外研究成果的基础上,应用盆地构造解析方法,深入研究了北美东部被动大陆边缘盆地群的地质结构和构造演化特征,并揭示了盆地群的油气地质规律。研究认为,北美东部盆地群沉积充填和不整合面发育具有明显的分段性和差异性。以区域不整合面为界,不同段盆地可划分为不同的构造层:南段盆地可划分为两套构造层;中段南部盆地可划分为3套构造层;中段北部盆地可划分为4套构造层;而北段盆地可划分为5套构造层。盆地群整体经历了陆内裂谷—陆间裂谷—被动大陆边缘的演化过程,但不同段盆地的构造演化具有明显的分段性和迁移性:晚三叠世沉降中心位于南段盆地;早侏罗世初期迁移至中段盆地,南段大陆开始裂解;中侏罗世逐渐迁移至北段盆地,中段大陆开始裂解;早白垩世晚期,北段大陆开始裂解。受持续的抬升剥蚀及大西洋岩浆活动省的联合作用,南段盆地和中段大多数盆地缺乏油气保存条件;斯科舍盆地和大浅滩盆地是主要的含油气盆地,以上侏罗统烃源岩为主,主要发育断层—背斜圈闭和盐体刺穿圈闭,整体表现为“自生自储”和“下生上储”的特征。  相似文献