鄂尔多斯盆地上三叠统延长组原油地球化学特征及油源分析

分析了鄂尔多斯盆地延长组原油的生物标志化合物组成特征,并对其进行油源对比,探讨了其成因。研究表明,鄂尔多斯盆地上三叠统延长组原油属于同一成因类型;原油有机母质为菌藻类和高等植物的混源型,原油形成于弱还原和淡水或微咸水环境,为成熟原油。油源对比表明,鄂尔多斯盆地上三叠统延长组原油主要来自长7油层组烃源岩。     

塔里木盆地塔北地区具有寒武系特征原油的分布及其成因

塔里木盆地塔北地区油气资源十分丰富,油气成因复杂。海相原油主要来自于寒武系或奥陶系烃源岩,或者二者混源。其中,对混源油定性研究多、定量研究少。随着勘探的深入和精细,需要定量回答油气的混源比例。本文根据不同端元油的人工混源配比实验,发现生物标志化合物具有随混源比例变化的特征,建立了混源比例与生标参数之间的关系式,并对塔北地区混源油中寒武系原油比例做了定量计算,进而研究了其分布规律与成因机制。研究认为,塔北地区原油主要来自于中、上奥陶统烃源岩,寒武系烃源岩有少量贡献。从空间分布上来看,具有从西到东、从浅至深,混源油中寒武系烃源岩来源的原油比例具有逐渐增高的特点,高比例寒武系来源原油的混源油主要分布在轮南低凸起的桑塔木断垒带东侧和轮东断裂周围,明显受烃源岩分布、输导体系和成藏过程等因素控制,该研究对进一步认识塔北地区油气生成、运移、聚集规律,以及指导油气勘探都具有重要意义。     

混源油研究综述

判识混源油并确定来自不同油源的原油贡献比例,是油源对比及油气运聚研究的重要内容之一,也是划分含油气系统或油气成藏体系的重要依据.阐述了混源油的含义、混合类型及其研究意义,并从混源油的判识和油源贡献比例的定量确定两个方面论述了混源油的研究内容、方法及其研究进展,指出了当前混源油不同油源原油贡献比例的分析和定量计算中存在的不足.     

塔河油田混源油地球化学及多元数理统计学对比研究

       混源油的定量判识是当前石油地质地球化学研究的热点与难点。以塔里木盆地塔河油田奥陶系中聚集的混源油为典型研究实例,通过地质地球化学与数理统计学相结合的方法,探索了定量研究混源油的方法,取得良好效果。原油地球化学研究结果表明,塔河油田原油普遍混源,并表现出多期充注特征,早期充注原油遭受了生物降解,因此目前原油中的轻烃、链状烃、规则甾烷等生物标志物主要反映的是后期充注原油的特征,不能很好地指示早期充注原油。据此,选择受生物降解影响相对较小的三环萜烷和藿烷定量数据,采用多元数理统计学交替最小二乘算法进行了原油成因研究,综合分析后认为现今混源油中可划分出4个端元,其中端元1和2可能主要代表了中上奥陶统烃源岩的贡献,而端元3和4则可能主要代表了寒武系烃源岩的贡献。塔河主体区以寒武系原油聚集为主,而外围地区则以中上奥陶统原油聚集为主,并且在整个塔河油田,总体上以寒武系原油的贡献比例相对最高。这一综合对比研究表明,多元数理统计学方法在混源油的比例计算、端元分析等方面具有重要作用,是对传统地球地球化方法研究的有效补充,值得推广应用,此外,研究认识还为区域油气勘探提供了新的参考信息。     

塔中隆起原油特征与成因类型

塔里木盆地塔中隆起油气性质多样、分布与成因复杂, 为揭示油气的特征与成因, 对塔中及外围104个原油样品进行了精细地球化学研究.依据单体烃碳同位素、特征生物标志物分析, 将塔中原油分为4种类型: (1) 寒武系成因原油, 具有较重正构烷烃单体烃碳同位素(-29.6‰~-29.1‰)、甲藻甾烷较发育及C₂₇、C₂₈、C₂₉规则甾烷呈反“L”型或线型分布等特征; (2) 中、上奥陶统成因原油, 具有较轻的正构烷烃单体烃同位素(-34‰~-35.6‰)、甲藻甾烷等不太发育与C₂₇、C₂₈、C₂₉规则甾烷呈“V”型分布等特征; (3) 富含含硫芳烃-二苯并噻吩原油, 主要分布于塔中4井区; (4) 混源油, 单体烃碳同位素特征界于Ⅰ、Ⅱ类原油之间, 是塔中最为主要的原油类型.油-油对比与油气性质分析表明, 塔中地区至少有两套主力烃源岩供烃.塔中部分原油生物标志物显示寒武系-下奥陶统成因特征, 而单体烃碳同位素却与中上奥陶统成因原油更为接近, 这种不同馏分的不一致现象系不同成因原油混源的结果, 反映单一应用生物标志物指标有其局限性.塔中油气性质具有分带、分块、分层特征, 反映叠合盆地多源、多期成藏、储层非均质性等多种特性.      

塔里木盆地英买力地区原油地球化学特征与族群划分

塔里木盆地英买力地区油气成因复杂,采用多馏分、多组分化学成分分析及单体烃碳同位素分析途径,对该区海相、陆相油进行精细分析。结果表明,英买力油田主要有两大类油组,分别是南部YM2井区的海相油(I类)和北部YM7井区的陆相油(Ⅱ类),各自具有典型的海相油与陆相油的特征。进一步分析表明,两大油组内部仍有分异。将第二油组进一步分为两亚类,以中、古生界产层为主的正常黑油和重质油为一类(Ⅱa),以古近系为主的凝析油为另一类(Ⅱb)。两亚类原油正构烷烃单体烃同位素稍有差异,芳烃组成与分布具有显著差异。较之于Ⅱa原油,Ⅱb原油富含联苯系列与氧芴系列、不同类型芳烃系列中以低分子量同系物占绝对优势,其正构烷烃单体烃碳同位素更重,与相邻的羊塔克地区原油表现出一定的相似性,表明两者之间有一定的成因联系,前者可能为混源油,由位于库车坳陷中拜城凹陷提供两种陆相烃源岩。英买力地区陆相油并非以往确认的一种成因类型,可能至少由两套性质迥异的中生界烃源岩供烃。英买力地区第一类海相油(I类)尽管生物标志物特征相近,但分析原油的单体烃碳同位素具有显著差异,同样存在油气混源的可能。英买力地区海、陆相原油特征与成因的深入剖析,对于该区精细油源确认、油气成藏机制乃至油气资源评价具有重要意义。     

塔里木盆地海相油气源与混源成藏模式

塔里木盆地油气源长期争论不休.采用单体烃同位素、包裹体成分与年代指示生物标志物等途径, 对塔里木盆地塔中、轮南典型油气藏进行了油气成因与混源成藏模式的研究.结果表明, 塔中、轮南绝大部分原油生物标志物与中上奥陶统烃源岩相似, 仅少部分原油显现与寒武系—下奥陶统烃源岩相近的特征, 但正构烷烃单体烃碳同位素分析表明, 原油绝大部分实质仍为混源油.塔中包裹烃成分分析进一步证实了原油的混源特性.利用同位素进行的混源定量结果表明, 塔中原油中寒武系—下奥陶统成因原油的混入量约为11%~100%(均值45%); 轮南地区约为11%~70%(均值36%), 表明寒武系—下奥陶统、中上奥陶统均为塔里木盆地的主力烃源岩.油气运移地化指标与地质条件的综合研究认为, 塔中地区断层是油气运移的重要通道, 塔中I号断层与斜交的走滑断层的交汇点是油气的主要注入点; 轮南地区侧向运移特征较明显.研究区存在调整型、多期充注型与原生型多种混源成藏模式.塔里木海相油气的普遍混源表明深层仍有油气勘探潜能.揭示海相混源油气成藏机制是指导塔里木海相油气勘探的关键.      

准噶尔盆地玛东斜坡区百口泉组–下乌尔禾组混源油地球化学特征及定量判识

混源油的定量判识是当前石油地质地球化学研究的热点与难点.本次研究以准噶尔盆地玛东斜坡区百口泉组–下乌尔禾组的混源油为典型研究实例,通过有机地球化学与化学计量学相结合的方法,对研究区混源油进行了定量研究,取得良好效果.原油地球化学研究结果表明,研究区原油混源现象普遍存在.综合分析后认为,现今混源油中可划分出3个端元,其中端元A和B可能主要代表了二叠系风城组早期和晚期烃源岩的贡献,并以晚期充注原油为主,而端元C差异较大,可能为二叠系下乌尔禾组烃源岩生烃或风城组不同岩相、不同沉积环境的烃源岩生烃.研究区以风城组生烃聚集为主,虽然晚期生烃占比不高,但对油气运聚成藏却起到非常关键的作用.这一综合对比研究表明,化学计量学方法在混源油的比例计算、端元分析等方面具有重要作用,是对传统地球化学方法研究的有效补充,值得推广应用.此外,研究认识还为区域油气勘探提供了新的参考信息.     

控制内蒙古二连盆地达尔其油田石油富集度的关键因素——不同油源原油的混合作用

在对3套烃源岩的质量和成熟度描述基础上,通过对原油物理性质、族组成和生物标志化合物参数的研究,在达尔其油田内划分出成熟度有明显差异的低熟油和成熟油。油源对比结果认为它们分别由都红木组一段低熟烃源岩和阿尔善组二段成熟烃源岩所生。推测成熟度参数介于低熟和成熟之间的原油为混源油。通过原油混合试验和油砂连续抽提试验证实了混源油的推测。通过油藏剖面中不同性质油层的分布特征研究,结合断层发育史与油气运移关系分析认为不同油源原油的混合是控制该油田石油富集度较高的关键因素。此外,还分析了控制混源的断层组合特征。     

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

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。     

Group classification of mixed oils in central Junggar Basin,Northwest China and their migration

The produced oils in central Junggar Basin are commonly mixed in origin. In this paper, in order to reveal this complexity and thereby provide valuable clues to the study of oil source and formation mechanism, genetic groups of the mixed oils were classified and their migration/accumulation was investigated. Based on the artificial oil mixing experiments, some representative biomarkers of the mixed oils showed varying tendencies according to mixing ratios of the oils. Hence, these biomarkers are useful for determining the origin of the mixed oils. According to the criteria, oils in the area were divided into four basic groups, i.e., the Lower Permian Fengcheng oil, the Middle Permian Lower Wuerhe oil, the Jurassic source derived oil, and the mixed oil (including the Lower and Middle Permian mixed oil and the Permian and Jurassic mixed oil). Oil migration and accumulation were discussed in combination with the geological background.     

珠Ⅰ坳陷油源对比及恩平组烃源岩的相对贡献

恩平组烃源岩成藏贡献研究对于拓展珠Ⅰ坳陷勘探新领域以及发现新的储量具有重要的应用价值, 目前相关研究较少.在油源对比的基础上, 将生标绝对含量与端元油配比实验相结合, 研究了珠Ⅰ坳陷恩平组烃源岩对单井油样的相对贡献.油源对比结果指示, 研究区原油可分为3类: 第1类源自始新统文昌组中深湖相烃源岩, 主要分布在惠陆低凸起、番禺4洼、流花凸起等地区; 第2类源自始新统-渐新统恩平组湖沼相烃源岩, 仅分布在惠州凹陷北部; 第3类为混源油, 发现于惠州凹陷南部和恩平凹陷.甾萜类绝对含量等7个指标建立的混源比例图版适用于计算油样中前两类烃源岩的相对贡献.计算结果表明, 文昌组烃源岩是珠Ⅰ坳陷的主力烃源岩, 恩平组烃源岩仅对惠州凹陷和恩平凹陷中的部分油样存在贡献.      

东营凹陷北部陡坡带稠油成藏机理与油气运聚特征

东营凹陷北部陡坡带的王庄—宁海地区发现了大量稠油 ,但原油的成因及其成藏机理仍不甚了解 .在以往原油成因与油源调查基础上 ,利用非烃含氮化合物及包裹体均一化温度对该区进行油气运移方向与相对距离、成藏时间与期次的分析 .结果表明 ,东营凹陷北部带原油具有由南而北的运移分馏效应 ,反映北部陡坡带原油来自南部的利津洼陷 ;王庄—宁海地区原油总体具有由东而西的运移分馏效应 ,其东、西两侧各有一主要油气注气点 .王庄—宁海原油烃类与非烃组成与分布特征揭示该区油气具有混合聚集特征 .包裹体测试反映王庄—宁海地区油藏主要为晚期成藏 ,距今小于 5Ma ;而靠近生油中心地带包裹体具有早期成藏的记录 (± 36Ma) .     

三肇凹陷扶杨油层断裂密集带样式及有利成藏部位

从三肇凹陷扶杨油层断裂密集带组合特征入手,结合油气分布规律,分析断裂密集带对油气优势运移方向控制作用,分源内和源外探讨断裂密集带中有利成藏部位.研究表明:三肇凹陷扶杨油层主要发育4种断裂密集带样式,即反向-地堑-反向断阶、地垒-地堑-反向断阶、反向-地堑-顺向断阶和地垒-地堑-顺向断阶等;当断裂密集带走向与地层倾向呈小角度相交时,其走向指示油气平面优势运移方向;源内断裂密集带中地垒和反向断阶是油气聚集优势部位;源外断裂密集带走向与地层倾向呈小角度相交时,地堑两侧反向断阶和地垒是油气优先聚集部位,其次为断裂密集带中部地堑,若呈大角度相交则断裂密集带靠近生烃凹陷一侧的反向断阶和地垒优先聚集油气.      

The occurrence of ultra-deep heavy oils in the Tabei Uplift of the Tarim Basin,NW China

Deeply buried heavy oils from the Tabei Uplift of the Tarim Basin have been investigated for their source origin, charge and accumulation time, biodegradation, mixing and thermal cracking using biomarkers, carbon isotopic compositions of individual alkanes, fluid inclusion homogenization temperatures and authigenic illite K–Ar radiometric ages. Oil-source correlation suggests that these oils mainly originated from Middle–Upper Ordovician source rocks. Burial history, coupled with fluid inclusion temperatures and K–Ar radiometric ages, suggests that these oils were generated and accumulated in the Late Permian. Biodegradation is the main control on the formation of these heavy oils when they were elevated to shallow depths during the late Hercynian orogeny. A pronounced unresolved complex mixture (UCM) in the gas chromatograms together with the presence of both 25-norhopanes and demethylated tricyclic terpanes in the oils are obvious evidence of biodegradation. The mixing of biodegraded oil with non-biodegraded oil components was indicated by the coexistence of n-alkanes with demethylated terpanes. Such mixing is most likely from the same phase of generation, but with accumulation at slightly different burial depths, as evidenced by overall similar oil maturities regardless of biodegradation level and/or amount of n-alkanes. Although these Ordovician carbonate reservoirs are currently buried to over 6000 m with reservoir temperatures above 160 °C, no significant secondary hydrocarbon generation from source rocks or thermal cracking of reservoired heavy oil occur in the study area. This is because the deep burial occurred only within the last 5 Ma of the Neogene, and there has not been enough heating time for additional reactions within the Middle–Upper Ordovician source rocks and reservoired heavy oils.     

Petroleum Origins and Accumulation Patterns in the Weixinan Sag in the Beibu Gulf Basin, Using Subsag B as an Example

Crude oil has been discovered in the Paleogene and Neogene units of the Weixinan Sag in the Beibu Gulf Basin. To determine the source and accumulation mode of this crude oil, 12 crude oil samples and 27 source rock samples were collected and an extensive organic geochemical analysis was conducted on them. Based on the geological conditions and the analytical results, the types, origins and accumulation patterns of crude oil in the study area were elucidated. Except for a shallowly-buried and biodegraded crude oil deposit in Neogene rocks, the crude oil samples in the study area were normal. All of the crude oils were derived from lacustrine source rocks. According to biomarker compositions, the crude oils could be divided into two families, A and B, distinctions that were reinforced by differences in carbon isotope composition and spatial distribution. Oil-source correlation analysis based on biomarkers revealed that Family A oils were derived from the mature oil shale at the bottom of the second member of the Liushagang Formation, while the Family B oils formed in the mature shale of the Liushagang Formation. The Family A oils, generated by oil shale, mainly migrated laterally along sand bodies and were then redistributed in adjacent reservoirs above and below the oil shale layer, as well as in shallow layers at high structural positions, occupying a wide distribution range. The Family B oils were generated by other shale units before migrating vertically along faults to form reservoirs nearby, resulting in a narrow distribution range.     

Reservoir geochemistry of the Tazhong oilfield in the Tarim Basin, China, Part I. Geochemical characteristics and genetic classification of crude oils

1 Introduction Since the 1990’s of the 20th century, oil & gas geochemists have shifted their research focus on hydrocarbon source rocks in the past to that on reservoir rocks and oil reservoirs at present; their research field has been expanded from oil & gas exploration to the assessment of oil reservoirs and production & management. Therefore, reservoir geochemistry as a branch disciplinary of organic geochemistry is now attracting great concern of many oil & gas explorers and oilfield en…     

鄂尔多斯盆地董志——正宁地区原油地球化学特征与成因

鄂尔多斯盆地董志—正宁地区是该盆地中生界油气勘探新区,对该地区原油的地球化学进行研究,了解原油的成因,可以为该地区石油勘探和开发提供科学依据。本研究首次对采集于董志—正宁地区原油和鄂尔多斯盆地烃源岩的烃类生物标志化合物进行了系统的分析,研究了它们的地球化学特征。原油中各类烃类生物标志化合物分布和组成特征指示了原油形成于...     

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

Abstract: 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.     

准噶尔盆地车排子隆起西南部原油地球化学特征及油源分析

车排子隆起毗邻昌吉凹陷和四棵树凹陷,油源丰富,构造条件良好,具备比较有利的油气聚集条件。近年来已在车排子隆起的侏罗系、白垩系、古近系和新近系获高产工业油气流。分析了车排子隆起西南部原油（或油砂抽提物）的地球化学特征,并对其油源作初步分析。结果表明研究区具有两类地球化学性质存在明显差别的原油。第一类原油遭受了不同程度的生物降解,并存在二次充注现象,推测早期充注原油来自昌吉凹陷二叠系,并遭受了不同程度的生物降解,后期混入了来自侏罗系烃源岩生成的原油。第二类原油具有侏罗系煤系烃源岩与白垩系湖相泥质烃源岩混源的特点,这类原油的碳同位素组成、正构烷烃分布特征和姥植比等均表现出煤成油的特征,但甾、萜烷烃类化合物组成与白垩系烃源岩接近,推测是由于侏罗系煤成油在向上运移成藏过程中,受到成熟度相对较低、生物标志物相对丰富的白垩系烃源岩的浸析作用所致。