鄂尔多斯盆地庆阳-镇原地区长8原油地球化学特征研究

文章以庆阳-镇原地区中生界三叠系延长组长8油藏原油和长7暗色泥岩为研究对象,借助岩石热解、烃源岩有机质镜鉴、色谱-质谱等分析测试手段,开展长8油藏原油地球化学特征、长7烃源岩综合评价和油源对比研究.结果表明:庆阳-镇原地区长8原油物性较好,低碳数正构烷烃在原油中占优势,其原油母质构成既有陆生植物,又有低等水生生物,而且低等水生生物对于原油的贡献相对较大.原油中Ts/Tm值处于适中水平,已达到成熟原油的标准.对庆阳-镇原地区的油源进行对比分析,表明长8原油主要来自于长7烃源岩.

鄂尔多斯盆地陕北地区长8致密砂岩流体包裹体特征与石油成藏

【研究目的】鄂尔多斯盆地陕北地区延长组长8含油分布范围广,是下步勘探重要的目标领域,但其石油烃类演化和油藏分布的关系尚不清楚。【研究方法】基于流体包裹体产状特征、成分及均一性分析结果,综合地质与地球化学方法,探讨了鄂尔多斯盆地陕北地区长8致密砂岩储层内石油的来源及成藏特征,揭示了长8油藏形成时间以及与油气成藏的关系。【研究结果】长8砂岩储层中的流体包裹体以气液烃包裹体、气液两相盐水包裹体为主,主要分布于细砂岩的石英加大边或裂隙中,可分为早、晚两期,与气液烃包裹体伴生的盐水包裹体均一温度主要存在85~105℃和115~135℃两个峰值区间,分布连续,油气为连续充注;成藏演化史表明,长8石油主要充注时期为110~135 Ma,在晚侏罗世发生早期充注,在早白垩世发生大规模充注。在区域上主要发育长7烃源岩,在最大生排烃阶段烃源岩Ro值接近1.0%,达到生烃门限,大量生烃,长9烃源岩在志丹地区局部分布。【结论】结合包裹体特征与烃类形成的关系,陕北地区长8油藏受烃源岩、储层及充注动力等因素控制,石油充注程度不一,发育平面上分布不均匀的岩性油藏,区域上具有“双源供烃、差异聚集”的成藏特点。

鄂尔多斯盆地中生界石油地质条件、资源潜力及勘探方向

鄂尔多斯盆地中生界油气资源丰富,三叠系延长组和侏罗系延安组是主力含油层系。在鄂尔多斯盆地石油地质条件研究的基础上,提出沉积相、输导体系、异常压力和构造为中生界成藏的主要控制因素,建立了三叠系延长组大型岩性油藏模式和侏罗系古地貌控藏模式,并结合盆地勘探成果,精细评价了鄂尔多斯盆地石油地质资源量,预测了油气资源的空间分布。结果表明:鄂尔多斯盆地石油地质资源量约为146.50×10^8t,其中常规油资源量为116.50×10^8t,致密油资源量为30.00×10^8t;按层系分,三叠系石油资源量为137.20×10^8t,侏罗系石油资源量为9.30×10^8t。盆地剩余资源量为96.93×10^8t,姬塬、陇东和志靖-安塞等地区,是长庆油田的规模储量区,仍然是未来勘探的主要区域。延长组长6、长8油层组和侏罗系是下一步勘探的重点层系;延长组下部的长9、长10油层组为新的目标层系;长7油层组致密油具有较大的勘探潜力。

河控三角洲生长的动力和沉积模式

分析河口动力特征,进而揭示其控制下的三角洲前缘挟沙河流床沙载荷(推移质)搬运和沉积机制,是合理构建河控三角洲生长沉积模式的前提。运用流体力学的湍流理论从微观动力过程角度分析失去河床约束条件下依靠惯性作用流动的河水入湖过程中河、湖两类水体的相互作用机制及流动规律,结合水槽物理模拟及前人开展的数值模拟,并借鉴河流泥沙动力学理论成果,构建了受流体力学及河流泥沙动力学约束的河控三角洲生长的动力和沉积模式。结果表明:湍流的特点决定了两类水体界面处存在强烈的质量、动量、动能传递。河水入湖过程既不是圆形(轴对称)射流,也不是平面(二维)射流,而是矩形(三维)射流,流速沿程会以负指数快速衰减。河口是挟沙河流流速衰减的终点,其控制下的三角洲前缘是挟沙河流床沙载荷沉积的终点。三角洲平原砂体生长过程,是三角洲平原动力、沉积、地貌相互作用的过程,生长的动力和沉积模式可以概括为:河流末端水体流速沿程衰减→挟沙能力降低→泥沙沉积→河床抬高→堤岸决口→河流分叉→水体流速沿程衰减→挟沙能力降低→泥沙沉积。分流河道砂体构成三角洲平原的骨架砂体,地貌控制下河流的频繁摆动是三角洲平原砂体生长的重要机制。河控三角洲沉积的主体为平原环境,而非前缘环境。

鄂尔多斯盆地平凉北地区M53井烃源岩地球化学特征与长8段油层油源

综合应用有机地球化学和有机岩石学的测试手段和研究方法,对鄂尔多斯盆地西南缘平凉北地区M53井三叠系延长组长7段暗色泥岩进行了定量评价,开展了M53井延长组长8段含油砂岩和邻井长8段原油分子地球化学特征分析和精细对比研究。首次揭示了平凉北地区长7段暗色泥岩地质地球化学特征和油源贡献。结果表明,M53井及邻近区域长7段泥岩有机质丰度参数中等-高、类型以Ⅰ型和Ⅱ1型为主,且接近热平衡成熟阶段,沉积水体呈淡水-微咸水,与盆地本部长7段富有机质泥页岩地质和地球化学特征相近,具备较好生烃能力。M53井延长组长8段含油砂岩抽提物和邻井长8段原油生物标志化合物中正构烷烃碳数呈单峰态,规则甾类化合物C29含量相对较高,烃类生源母质中含陆源高等植物且形成于弱还原-弱氧化环境,原油成熟度相对较高。长8段原油和含油砂岩抽提物生物标志化合物参数、碳同位素参数与M53井及邻近地区长7段烃源岩特征相近,即长8段烃类来源于本区长7段烃源岩。平凉北地区发育较好的烃源岩,该区具备良好的资源潜力和勘探前景。

鄂尔多斯盆地陕北地区延长组长6原油地球化学特征及油源分析

通过对原油、含油砂岩、露头剖面样品、钻井泥岩分子地球化学特征和碳同位素的分析表明:鄂尔多斯盆地陕北地区长6原油为轻质原油,具有低密度、低黏度、低凝固点的特征;原油和含油砂岩抽提物族组成中,饱和烃含量所占比重大,饱芳比高、原油碳同位素轻,小于-32‰;原油正构烷烃碳数分布型式为前峰型单峰态,正构烷烃保存完整,主峰碳为nC_(13)~nC_(22),原油具明显奇偶优势比,轻质组分占优势,植烷优势明显;原油规则甾烷呈"V"和"L"型分布,β胡萝卜烷含量很低,ααα20RC_(27)甾烷相对含量高于ααα20RC_(29)甾烷;伽马蜡烷含量低,孕甾烷及规则甾烷相对较高,硫芴含量较高,三芳甾烷和甲基三芳甾烷丰度较高,反映了原油的母源形成于盐度不高的沉积环境,有机质母源以浮游水生生物及高等植物的输入为主;原油饱和烃中,甾、萜烷的αααC_(29)甾烷20S/(20S+20R),αααC_(31)甾烷20S/(20S+20R)等参数均处于热演化平均状态,甲基菲指数表明原油处于成熟阶段。通过对延长组长9、长7段烃源岩与长6原油、含油岩心抽提物,甾、萜类化合物特征对比分析表明,长6原油与长9烃源岩的生物标志化合物存在较大差别,二者对比性较差,不具备相关性,没有亲缘关系;长6与长7烃源岩的对比性较好,因此认为长6原油主要来源于长7段烃源岩。

Mechanism of Silurian Hydrocarbon Pool Formation in the Tarim Basin

There are three formation stages of Silurian hydrocarbon pools in the Tarim Basin. The widely distributed asphaltic sandstones in the Tazhong （central Tarim） and Tabei （northern Tarim） areas are the results of destruction of hydrocarbon pools formed in the first-stage, and the asphaltic sandstones around the Awati Sag were formed in the second-stage. The hydrocarbon migration characteristics reflected by the residual dry asphalts could represent the migration characteristics of hydrocarbons in the Silurian paleo-pools, while the present movable oil in the Silurian reservoirs is related to the iater-stage （the third-stage） hydrocarbon accumulation.

Evidence of Oil Sources and Migration in Triassic-Jurassic Reservoirs in the South Tianhuan Depression of the Ordos Basin, China Based on Analysis of Biomarkers and Nitrogen-Bearing Compounds

The Ordos Basin is an important intracontinental sedimentary basin in western China for its abundant Mesozoic crude oil resources. The southern part of the Tianhuan Depression is located in the southwestern marginal area of this Basin, in which the Jurassic and Triassic Chang-3 are the main oil-bearing strata. Currently, no consensus has been reached regarding oil source and oil migration in the area, and an assessment of oil accumulation patterns is thus challenging. In this paper, the oil source, migration direction, charging site and migration pathways are investigated through analysis of pyrrolic nitrogen compounds and hydrocarbon biomarkers. Oil source correlations show that the oils trapped in the Jurassic and Chang-3 reservoirs were derived from the Triassic Chang-7 source rocks. The Jurassic and Chang-3 crude oils both underwent distinct vertical migration from deep to shallow strata, indicating that the oils generated by Chang-7 source rocks may have migrated upward to the shallower Chang-3 and Jurassic strata under abnormally high pressures, to accumulate along the sand bodies of the ancient rivers and the unconformity surface. The charging direction of the Jurassic and Chang-3 crude oils is primarily derived from Mubo, Chenhao, and Shangliyuan, which are located northeast of the southern Tianhuan Depression, with oils moving toward the west, southwest, and south. The results show that an integration of biomarker and nitrogen-bearing compound analyses can provide useful information about oil source, migration, and accumulation.

Characteristics of Oil Sources from the Chepaizi Swell,Junggar Basin,China

So far there has been no common opinion on oil source of the Chepaizi swell in the Junggar Basin. Therefore, it is difficult to determine the pathway system and trend of hydrocarbon migration, and this resulted in difficulties in study of oil-gas accumulation patterns. In this paper, study of nitrogen compounds distribution in oils from Chepaizi was carried out in order to classify source rocks of oils stored in different reservoirs in the study area. Then, migration characteristics of oils from the same source were investigated by using nitrogen compounds parameters. The results of nitrogen compounds in a group of oil/oil sand samples from the same source indicate that the oils trapped in the Chepaizi swell experienced an obvious vertical migration. With increasing migration distance, amounts and indices of carbazoles have a regular changing pattern （in a fine linear relationship）. By using nitrogen compounds techniques, the analyzed oil/oil sand samples of Chepaizi can be classified into two groups. One is the samples stored in reservoir beds of the Cretaceous and Tertiary, and these oils came from mainly Jurassic source rock with a small amount of Cretaceous rock; the other is those stored in the Jurassic, Permian and Carboniferous beds, and they originated from the Permian source. In addition, a sample of oil from an upper Jurassic reservoir （Well Ka 6）, which was generated from Jurassic coal source rock, has a totally different nitrogen compound distribution from those of the above-mentioned two groups of samples, which were generated from mudstone sources. Because of influence from fractionation of oil migration, amounts and ratios of nitrogen compounds with different structures and polarities change regularly with increasing migrating distance, and as a result the samples with the same source follow a good linear relationship in content and ratio, while the oil samples of different sources have obviously different nitrogen compound distribution owing to different organic matter types of their source rocks. These conclusions of oil source study are identical with those obtained by other geochemical bio-markers. Therefore, nitrogen compounds are of great significance in oil type classification and oil/source correlation.

Formation patterns of Chang 9 oil reservoir in Triassic Yanchang Formation, Ordos Basin, NW China

Based on analysis of main controlling factors of Chang 9, the source rock, driving force of migration, migration and accumulation modes, reservoir forming stages and model and enrichment law of Chang 9 reservoir were examined. The study showed that the oil of Chang 9 reservoir in the Jiyuan and Longdong(Eastern Gansu) areas came primarily from the source rock of Chang 7 Member, but the oil of Chang 9 reservoir in the Zhidan area came primarily from the source rock of Chang 9 Member. There developed lithologic-structural oil reservoirs in Gufengzhuang-Mahuangshan area in northwest Jiyuan, structural-lithologic oil reservoirs in east Jiyuan, and lithologic reservoirs in Huachi–Qingcheng area and Zhidan area. The overpressure of Chang 7 Member was the driving force of oil migration. The burial history showed that Chang 9 Member experienced two stages of reservoir forming, the reservoir formed in the Late Jurassic was smaller in charging scope and scale, and the Early Cretaceous was the period when the source rock generated oil and gas massively and the Chang 9 reservoir came into being. Along with the tectonic movements, Chang 7 bottom structure turned from high in the west and lower in the East in the sedimentary stage to high in the east and lower in the west in the hydrocarbon accumulation stage and at last to gentle western-leaning monoclinal structure at present. In Early Cretaceous, the Chang 7 bottom structure was the lowest in the west of Huanxian-Huachi-Wuqi-Dingbian areas, so the oil migrated laterally towards the higher positions around after entering the reservoir. In the main reservoir forming period, Chang 7 bottom had an ancient anticline in Mahuangshan-Hongjingzi area of west Jiyuan, controlling the oil reservoir distribution in west Jiyuan.

The distribution and geological significance of carbazole compounds in Silurian paleo-pools of the Tarim Basin, Northwest China

The results presented in this paper indicated that the carbazole-type compounds have high thermal stabil- ity and also show stability in oxidation and bio-degradation. This kind of compounds still has high concentrations and a complete distribution in the analyzed dry asphalt samples, showing that they are particularly useful in the study of hydrocarbon migration of the paleo-pools. The difference in the contents of nitrogen compounds in the Silurian dry asphalts from the Awati, Tabei and Tazhong areas is attributed to the difference in the extent of oxidation and (or) bio-degradation for the areas; the Awati and Tabei areas underwent relatively strong oxidation and bio-degradation. During the first stage of hydrocarbon pool formation in the Silurian system in the Tazhong and Tabei areas of the Tarim Basin (at the end of the Silurian period) and at the second stage in the Awati area (in Permian), the hydrocar- bons experienced a long-distance migration.