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利用油包裹体微束荧光光谱判识油气充注期次 总被引:2,自引:0,他引:2
基于石油的荧光性, 通过常规荧光光谱方法, 对油包裹体的荧光光谱进行定量化描述, 利用其主峰波长、最大荧光强度及红/绿商等属性参数, 根据主峰波长与最大荧光强度、主峰波长与红/绿商的相关关系特征, 可以便捷而有效地开展油气充注期次的判识.民丰洼陷沙三段岩性油气藏储层的15块流体包裹体样品检测结果表明, 发黄色荧光的油包裹体荧光光谱结构和形态相似, 其主峰波长一致; 而发蓝白色荧光的油包裹体荧光光谱具有2种类型: 一类与黄色荧光油包裹体荧光光谱结构和形态相似, 主峰波长一致, 表现出同源特征; 另一类明显发生"蓝移", 表现出异源特征.主峰波长与最大荧光强度, 以及主峰波长与红/绿商的相关关系均表现出3种特征类型.因此, 可判定民丰洼陷沙三段岩性油气藏在其地质历史时期共经历了3期油气充注. 相似文献
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引言分子荧光是非地震找油的重要指标之一。通常采用固定波长法测土壤中的发荧光物质,此方法对发荧光物质的定性、定量分析比较困难,而且谱峰重叠严重,难以分辨,采用同步扫描技术可以使光谱简化,谱带变窄,在同时测定多种芳烃时,大大提高了分辨率。由于多环芳烃的斯多克位移在2-5urn之间,采用同步扫描时,激发波长与荧光波长差往往在3~5urn之间,这时溶剂的干扰非常严重。采用偏振技术可有效地抑制散射光的干扰,提高检测的灵敏度。2实验部分ZI方法原理许多芳香族化合物在室温和77K下具有发荧光的性质,在紫外线的照射下能够发出… 相似文献
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有机包裹体特别是石油包裹体的荧光颜色是鉴定有机包裹体和指示油气成熟度的有效手段.基于石油的荧光性, 通过荧光光谱分析方法, 对石油包裹体的荧光光谱进行定量化描述, 利用其主峰波长(λmax)、荧光强度及红绿商等属性参数, 开展油气充注期次的判识.通过偏光显微镜、荧光显微镜等技术手段, 对塔北隆起鹰山组-一间房组38个样本的石油包裹体进行了荧光颜色、显微光谱谱形和红绿商值的研究.样品中检测到黄绿色荧光、绿色荧光和蓝白色荧光3类石油包裹体, 且这3类石油包裹体的同生盐水包裹体温度具有可区分的温度范围, 对应的盐水包裹体平均温度分别是: 56.5、88.3、130.1 ℃.综合地球化学方面的研究成果, 结合主峰波长、荧光强度、红绿商以及石油包裹体同生的盐水包裹体温度等参数分析认为, 研究区储层中的原油至少来源于2个不同烃源的3期油气充注, 具有多源多期充注的成藏特征. 相似文献
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为揭示不同成因类型原油的三维全扫描荧光特征及其主控因素,对50个不同成因类型的原油的三维荧光特征进行了分析。原油样品代表了未熟—低熟至高成熟度范畴原油、淡水与咸水湖相、沼泽相成因原油、高蜡低硫与低蜡高硫油、常规油与重质油等类型。结果表明,分析原油三维荧光谱图及其定量参数有所差异。原油的荧光强度随芳烃含量增加而增加,沼泽相高蜡油荧光强度总体高于湖相原油;荧光强度随成熟度增加而降低、荧光主峰波长随成熟度增加而变短,反映芳烃总量与相对高分子量芳烃丰度具有降低趋势。稠油的荧光谱图不同于常规油,具有波长分布范围宽、主峰不明显等特征。成熟度、母源岩有机质类型与生源、次生改造等多种因素对原油的三维荧光特征有控制作用。 相似文献
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Exchange of carbon bound hydrogen has been observed when alkenes, saturated and aromatic hydrocarbons are heated at moderate temperatures on carbonaceous surfaces (activated carbon and coal). Isomerisation of alkenes and the formation of hydrogenated/dehydrogenated products from the saturated and aromatic reactants resulted. A suite of crude oils from the Carnarvon Basin (Western Australia) have been analysed with a view to comparing their relative abundances of structurally similar hydrocarbons. The consistent relationships between hydrocarbons in crude oils that are chemically related via hydrogenation/dehydrogenation reactions suggest that a hydrogen exchange process similar to that demonstrated in laboratory experiments occurs during crude oil formation in sedimentary rocks. 相似文献
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《Applied Geochemistry》1997,12(3):229-241
The fluorescence spectra of crude oils, synthesized as hydrocarbon fluid inclusions (hcfi) in NaCI crystals, have been recorded and correlated with crude oil chemical analysis. The crude oils represent a wide range in total hydrocarbons, saturate and aromatic fractions, and resin-asphaltene concentration. The fluorescence properties (Lambda max and Q) of the hydrocarbon fluid inclusions display a systematic red shift to longer wavelengths from 440 nm to 595 nm with increasing aromatic content and increasing concentration of NSO-bearing compounds. A positive correlation also exists between Lmax-Q and the thermal maturity parameters nC17/pristane and nC18/phytane. First order linear regression equations provide a method for constraining the chemical composition of natural hydrocarbon fluid inclusions. Lmax and Q correlate positively with oil density (°API), providing for an indirect method of estimating the API of a natural hydrocarbon fluid inclusion assemblage. Fluorescence spectra of non-biodegraded crude oils from the Upper Devonian Birdbear Formation, Saskatchewan, Canada, have been correlated with regionally widespread hcfi within carbonate carrier beds and reservoir rocks of the same formation. The two most dominant types of hcfi spectra match well with the fluorescence spectra from crude oils within the Birdbear Formation. A third, less common population of very-blue fluorescing hcfi (Lmax=415440 nm, Q ≤ 0.10) also occur within fractures, intercrystalfne cements or in fossil overgrowths. The Lmax-Q-API-chemical correlations establised for the synthetic hcfi suggests that the °API of these inclusions is probably > 45° and the saturate/aromatic ratio ranges from 3.2 to 5.1. Spectra from hcfi within quartz overgrowths and cements, fractures and carbonate cements from sandstone reservoirs in the Jeanne d'Arc Basin offshore Newfoundland, compared with fluorescence spectra of crude oils suggests that some of the reservoirs may have been filled by a relatively low maturity oil and then a higher maturity oil. This is reflected in the intermediate spectra of the crude oils relative to the spectra of two separate hcfi events. Other reservoirs appear to have been charged with a relatively high gravity oil which was later biodegraded. This is marked by a blue region spectra for the hcfi compared with a red-shifted spectra for the crude oil (°API = 19). The API of the original unaltered oil which charged the reservoir is estimated to be between 32 and 38° using the Lmax-Q-API relationship established for the synthetic hcfi. 相似文献
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红外,紫外及荧光分析在有机包裹体研究中的应用 总被引:1,自引:0,他引:1
本文利用红外,紫外及荧光分析方法,对岩石中吸附有机质和包裹体有机质进行了分析研究,红外分析结果表明,生油岩中的包裹体有机质有明显的石油峰,并且与吸附有机质的峰形有较大差别,紫外分析结果也表明,生油岩中两种有机质的光谱性质不一致,而非生油岩则相反,生油岩荧光光谱特征为:荧光强度大(〉40),λmax在450nm左右,光谱位于蓝绿光区,演化程度属高成熟原油阶段,这些可作为评价生油潜力,演化程度的方法及 相似文献
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详细研究了吉林伊通地堑下第三系生油岩和原油中的芳烃生物标志物,包括常规的多环芳烃,以及丰富的来源于高等植物的芳香二萜和芳构化的五环三萜。目前,原油中芳构化五环三萜类生物类生物标志物国内外均尚报道极少。还详细讨论了利用原油中最新发现的芳构化五环三萜在解决本区生物输入,油源对比以及石油成因等方面的重要意义。 相似文献
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冀中坳陷苏桥-文安地区混源油定量识别模式研究--典型原油混合实验及混源油识别模式 总被引:6,自引:1,他引:6
通过典型原油混合实验及其产物的地球化学剖析,揭示当煤成油和下第三系原油混合时,随着下第三系原油的增加,C19三环萜烷,C24四环萜烷,C30重排藿烷,C29甾烷和重排甾烷逐渐变小;而姥鲛烷和植烷,伽马蜡烷和C27甾烷含量则逐渐增加。利用饱和烃生物标志物和芳烃化合物绝对浓度的变化规律,建立了冀中坳陷苏桥-文安地区混源油定量识别模式图版。根据混源油识别的模式,判断苏49井的混源油是由10%的下第三系原油和90%的煤成油混合而成;相反文1021井混源油则是由90%的下第三系原油和10%的煤成油混合而成。 相似文献
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吐哈盆地原油和烃源岩单烃碳同位素组成特征及油源对比探讨 总被引:5,自引:0,他引:5
本文测定了吐哈盆地原油和部分烃源岩的单烃碳同位素组成,利用单烃碳同位素组成及其分布模式和样品生物标志物的分布和组合特征研究沉积环境和母质输入特征,进行原油成因类型划分和油源对比探索。吐哈盆地原油可划分为三类:一类是典型沼泽相-湖沼相煤成油,如台北凹陷各油田侏罗系原油;二类是湖相原油,如托参1井三叠系原油;三类是浅湖相原油,如胜金口油田中侏罗统原油。油源对比认为目前吐哈盆地侏罗系产出的原油由中下侏罗统煤系地层有机质生成,而托克逊凹陷三叠系原油由上二叠统湖相泥岩生成。 相似文献
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含油流体包裹体:地球化学分析与地质应用 总被引:1,自引:2,他引:1
SimonCGEORGE HerbertVOLK ManzurAHMED 《岩石学报》2004,20(6):1319-1332
利用含油流体包裹体可以获得与原油和源区常规分析同等质量的可靠地球化学数据。细致而又小心谨慎地对待各测试步骤(如样品清洗、背景空白等)是成功进行包裹体油气成分分析的基础。从技术上来说,每一分析步骤都具有挑战性,但如果我们能按步骤循序渐进,就不仅能够分析那些含有大量石油包裹体的样品(如当今或古油藏样品),而且可以测试含极少量石油包裹体的样品(如迁移路径或极古老岩石样品)。包裹体中可被测试的碳氢化合物多种多样,包括低分子量的碳氢化合物、n-链烷、类异戊二烯、生物标志物、芳香族碳氢化合物等。流体包裹体内石油成分分析在地质上有广泛应用,比如可以更好地重建储集区石油重注史、确定盆地中以前未知的活性源岩。在储集区内由生物降解造成的石油再造和(或)水洗作用经常被抹去,流体包襄体分析则可以解释储集区复杂成油阶段,当然更可以去除钻孔泥浆添加剂或其他污染物的影响。此外,也可以获知地球早期生物圈碳氢化合物的组成及多样性,以及在勘探区或盆地进行二次迁移路径填图。 相似文献
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Junping Huang Xiangbo Li Qilin Chen Zhanlong Yang Yanrong Wan Lihua Wei Liwen Long Xiaoguang Liu 《中国地球化学学报》2012,31(3):327-339
In the lower parts of oil reservoirs Chang 9 and Chang 10 of the Yanchang Formation are oil-bearing layers newly found in oil exploration in the Ordos Basin.Based on GC,GC-MS analyses of saturated hydrocarbons from crude oils and source rocks,reservoir fluid inclusions and BasinMod,the origin of crude oils,accumulation period and accumulation models are discussed in combination with other petroleum geology data in this paper.The result shows that(1) there are two different types of crude oils in oil reservoir Chang 9 in the Longdong and Jiyuan regions:crude oils of typeⅠ(Well D86,Well A44,Well A75,Well B227,Well X62 and Well Z150) are mainly de-rived from the Chang 7 source rocks(including mudstones and shales) and distributed in the Jiyuan and Longdong regions;those of typeⅡ(Well Z14 and Well Y427),are distributed in the Longdong region,which are derived from the Chang 9 source rocks.Crude oils from oil reservoir Chang 10 in the Shanbei region are mainly derived from the Chang-9 source rocks;(2) there are two phases of hydrocarbon filling in oil reservoir Chang 9 in the Jiyuan and Longdong regions and oil reservoir Chang 10 in the Shanbei region:The first phase started at the early stage of J2z.The process of hydrocarbon filling was discontinuous in the Late Jurassic,because of the tectonic-thermal event in the Ordos Basin.The second phase was the main accumulation period,and hydrocarbons began to accumulate from the late stage of J2a to the middle-late of K1,mainly at the middle-late stage of K1;(3) there exist two types of accu-mulation models in oil reservoirs Chang 9 and Chang 10 of the Yanchang Formation:source rocks of the reservoirs in oil reservoir Chang 9 in the Jiyuan region and oil reservoir Chang 10 in the Shanbei region,the mixed type of reservoirs on the lateral side of source rocks and source rocks of the reservoirs in oil reservoir Chang 9 in the Long-dong region. 相似文献