塔里木盆地北部志留系顶面不整合中陆相原油的成藏历史与油气富集机制

塔里木盆地志留系发育厚层沥青砂,显示优越的含油气性.继塔中地区志留系原油勘探取得突破之后,塔北地区志留系砂岩风化壳型储层也发现了工业油藏.根据原油的甾、萜烷和噻吩类生物标记化合物的分布特征,结合原油的物理化学性质以及族组分稳定碳同位素特征分析,明确了塔北西部英买35井区志留系风化壳原油来源于库车凹陷三叠系黄山街组湖相烃源岩,与塔北东部同发育在志留系风化壳剥蚀尖灭线附近的哈得18C井海相原油形成鲜明对比.通过志留系砂岩流体包裹体均一温度测试,结合地层埋藏史研究成果,推断英买35井区志留系砂岩主要成藏时间为距今5 ～ 8Ma的晚喜山期.结合库车凹陷两套陆相烃源岩的生烃演化重构了该区域湖相原油的成藏过程,表明康村组沉积后白垩系卡普沙良群与志留系风化壳是湖相油气向台盆区输导的重要通道,预示着湖相原油运移充注的范围十分广泛.成藏机理分析表明,志留系风化壳的构造幅度和面积控制了油气的充注范围,直接盖层的封盖条件控制了风化壳储层的含油气性.塔北地区东、西部志留系风化壳的暴露时间和地层组合关系的差异,是东部形成海相含油气系统,而西部发育海、陆相油藏垂向上叠置,互不交叉的复式含油气系统的重要原因.     

塔中地区奥陶系储层烃包裹体特征及成藏分析

利用新发明的不同期次烃包裹体组份提取仪器"多功能烃包裹体取样机",分别提取了塔中地区5期烃包裹体组份,并成功地分析出组份生物标志化合物,论证了5期烃包裹体油气的来源:第Ⅰ期烃包裹体来源于满加尔坳陷的寒武系海相碳酸盐岩烃源岩、第Ⅱ期烃包裹体来源于满加尔凹陷的中奥陶系烃源岩、第Ⅲ期烃包裹体来源于塔中下部寒武系海相碳酸盐岩烃源岩、第Ⅳ期烃包裹体是由寒武系海相碳酸盐岩原油分解而成、第Ⅴ期烃包裹体来源于塔中上奥陶统良里塔格组烃源岩。其形成时间分别为:早海西期约383Ma、晚海西期约240~260Ma、燕山-早喜山期早期、23Ma喜山运动二幕、喜山运动晚期到现在。塔中奥陶系储层中不是每一个圈闭都含有以上5期烃包裹体,有的圈闭只含其中的一期或二期或三期。第Ⅰ期主要是油气运移的 "足迹",仅路过奥陶系,未成藏。第II、IV、V期成藏普遍影响塔中奥陶系,是油气成藏的"历史",使奥陶系的原油具有中奥陶统油源(第II期)、上奥陶统油源(第V期)和寒武系油源(第IV期)混源特征,第Ⅱ、Ⅳ期烃包裹体大量存在是塔中Ⅰ号坡折带凝析油气高产的"标志"。 第Ⅲ期包裹体的发育可能预示在塔中东部地区中下奥陶统及寒武系形成大油藏,塔中东部地区是找原生大型油藏的重要靶区。     

塔中地区油气运聚特征

塔中地区主要受塔中Ⅰ号、Ⅱ号及Ⅲ号三条大断层控制 ,形成巨型复式背斜 ,隆起高部位地层遭受了强烈的风化剥蚀。背斜之上 ,断裂和局部构造发育。可划分出两个主要成藏期 :第Ⅰ成藏期为寒武系—下奥陶统烃源岩成熟生烃运移期 ,生排烃高峰为志留纪 ;第Ⅱ成藏期为中—上奥陶统烃源岩在燕山期—喜马拉雅期成熟生烃运聚。第Ⅰ成藏期形成的油藏有两个特征 :在塔中Ⅰ号断裂带、北部斜坡带油气注入奥陶系及志留系圈闭中 ,形成原生油气藏 ;构造高部位 (如中央断垒带 )的油气藏在后期构造运动中遭受破坏。第Ⅱ成藏期形成的油藏可分为两类 :对早期油藏的再次充注 ;聚集形成新油藏。塔中地区的油气运移通道主要有断裂和不整合面 ,油气的分布也主要受断裂和不整合面所控制。塔中Ⅰ号构造带和北部斜坡带是较为有利的勘探区带     

塔中地区油气运聚特征

塔中地区主要受塔中Ⅰ号、Ⅱ号及Ⅲ号三条大断层控制,形成巨型复式背斜,隆起高部位地层遭受了强烈的风化剥蚀.背斜之上,断裂和局部构造发育.可划分出两个主要成藏期:第Ⅰ成藏期为寒武系-下奥陶统烃源岩成熟生烃运移期,生排烃高峰为志留纪;第Ⅱ成藏期为中-上奥陶统烃源岩在燕山期-喜马拉雅期成熟生烃运聚.第Ⅰ成藏期形成的油藏有两个特征:在塔中Ⅰ号断裂带、北部斜坡带油气注入奥陶系及志留系圈闭中,形成原生油气藏;构造高部位(如中央断垒带)的油气藏在后期构造运动中遭受破坏.第Ⅱ成藏期形成的油藏可分为两类:对早期油藏的再次充注;聚集形成新油藏.塔中地区的油气运移通道主要有断裂和不整合面,油气的分布也主要受断裂和不整合面所控制.塔中Ⅰ号构造带和北部斜坡带是较为有利的勘探区带.     

油气运聚地化分析技术在塔里木盆地台盆区的应用

塔里木盆地台盆区因多期的构造运动使油气藏经历了多次破坏、多次调整的复杂演化历史,应用储层包裹体特征与盆地模拟分析技术确定油气注入时间,应用中性含氮化合物分布判别油气运移方向,应用具有时代意义的生物标志化合物确定烃源岩的准确时代等方法,再结合构造演化史,较好地解决了确定塔里木盆地轮南油气区和哈得逊油田油气分布规律和油气运移路径的问题。研究表明,轮南地区主要有三期油气运移期,后两期(发生于侏罗纪之后)的油气主要通过裂隙与不整合面由满加尔凹陷和草湖凹陷向轮南低隆高部位运移,轮南地区下部的烃源岩所生成的油气则通过裂隙运移到上部储层中成藏。油气大规模注入三叠系储层的时问为15～10Ma,三叠系原油在横向上从吉拉克地区向桑塔木断垒带和轮南断垒带方向运移注入,垂向上为由断裂从 T_Ⅲ油组向 T_Ⅰ油组注入。哈得逊油田东河砂岩油藏的寒武系—下奥陶统烃源岩生成的油数量有限,后期注入的中—上奥陶统生成的油的推进前端应在哈得逊东南部附近。     

塔里木盆地塔北隆起碳酸盐岩油气成藏特点

塔北隆起自早古生代以来经历了长期的挤压隆升剥蚀过程,结合寒武系膏盐的塑性上拱,形成了两种基本的碳酸盐岩圈闭类型,即风化壳潜山和内幕背斜圈闭。塔北隆起南临古生代满加尔凹陷、北临中新生代库车坳陷,具有捕获南北两侧海陆两相油气来源的条件,经历了海西期、燕山期和喜马拉雅山期3期成藏。储集空间主要靠溶蚀孔洞和裂缝。石炭系中—上泥岩段和白垩系卡普沙良群泥岩两套区域性盖层对碳酸盐岩风化壳潜山油气聚集起着至关重要的作用。不整合面和断裂是控制塔北隆起油气成藏的两个最关键的因素,不整合面既控制着岩溶储层的发育分布又是油气侧向运移的优势通道;断裂活动形成破碎带、裂缝带进而改善储层性能,同时断裂也是油气垂向运移的优势通道。     

准噶尔盆地乌伦古坳陷石油地质特征及勘探方向

准噶尔盆地北部乌伦古坳陷地层主要由石炭系、三叠系、侏罗系及白垩系组成.研究区分别在三叠系、侏罗系、石炭系发育3套烃源岩.石炭系火山岩储层和侏罗系碎屑岩储层为本区主要勘探目的层,白垩系和三叠系发育的厚层泥岩为本区两套区域性盖层.三叠、侏罗系烃源岩于侏罗系末期开始排烃,石炭系烃源岩于三叠纪末进入生烃门限.断层和不整合面共同构成该区油气运移的主要通道,边缘深大断裂带附近及石炭系不整合面附近,是油气勘探的主要方向.     

塔中地区油气运聚特征

塔中地区主要受塔中Ⅰ号、Ⅱ号及Ⅲ号三条大断层控制，形成巨型复式背斜，隆起高部位地层遭受了强烈的风化剥蚀。背斜之上，断裂和局部构造发育。可划分出两个主要成藏期：第1成藏期为寒武系—下奥陶统烃源岩成熟生烃运移期，生排烃高峰为志留纪；第Ⅱ成藏期为中—上奥陶统烃源岩在燕山期—喜马拉雅期成熟生烃运聚。第1成藏期形成的油藏有两个特征；在塔中Ⅰ号断裂带、北部斜坡带油气注入奥陶系及志留系圈闭中，形成原生油气藏Ⅰ构造高部位(如中央断垒带)的油气藏在后期构造运动中遭受破坏。第Ⅱ成藏期形成的油藏可分为两类：对早期油藏的再次充注；聚集形成新油藏。塔中地区的油气运移通道主要有断裂和不整合面，油气的分布也主要受断裂和不整合面所控制。塔中Ⅰ号构造带和北部斜坡带是较为有利的勘探区带。     

一个典型的寒武系油藏:塔里木盆地塔中62井油藏成因分析

塔里木盆地志留系沥青砂岩广泛发育,主要原因是来源于寒武系的原油在进入志留系储层后区域性的抬升剥蚀使油藏遭到严重破坏,但到目前为止,究竟是寒武系烃源岩还是中上奥陶统烃源岩或是两者都对现今的志留系沥青砂岩中的有机质有贡献还不清楚.对塔中62井原油的化学组成和油源的分析表明,其甾萜类组成具有寒武系烃源岩的组成特征,反映该油藏原油主要来源于寒武系.另一方面,塔中62井砂岩透镜体被泥岩圈闭,油藏具有较好的保存条件,且后期中上奥陶统生成的烃类难以充注进入油藏.塔中62井志留系油藏破坏作用较弱、保存较好,是塔里木盆地在志留系发现的第一例来源于寒武系的油藏.     

塔里木盆地塔中低凸起奥陶纪油气成藏体系

国外含油气系统的概念和方法在国内的含油气盆地研究中的应用存在着局限, 应用油气成藏体系的理论方法对塔中低凸起奥陶系油气成藏过程进行了分析.塔中低凸起奥陶纪油气成藏体系的源岩为寒武系及下奥陶统烃源岩; 满加尔坳陷中的砂体和不整合面是油气侧向运移的输导体, 同时深部断裂是油气垂向运移的输导体; 圈闭类型主要为古隆起背景上的地层型圈闭和构造型圈闭.塔中Ⅰ号断裂构造带是最为有利的油气聚集区, 塔中北坡次之, 中央断垒带最差.塔中Ⅰ号断裂带依然是下一步勘探的重中之重.      

Petroleum Migration Direction of the Silurian Paleo-pools in the Tarim Basin, Northwest China

The results obtained in this paper indicate that carbazole-type compounds have high thermal stability and also show stability in oxidation and bio-degradation. This kind of compounds still has a high concentration and complete distribution in the analyzed dry asphalt samples, showing that they are particularly useful in studying petroleum migration of paleo-pool. During the basin＇s first-stage of oil-gas pool formation in the Silurian in Tazhong and Tabei areas of Tarim Basin （at the end of Silurian period） and the second-stage in the Awati area （in Permian）, the petroleum experienced a long-distance migration. During the formation of the Silurian paleo-pools in Tazhong Uplift at the end of Silurian, the petroleum mainly came from the lower and middle Cambrian source rocks in the Manjiaer sag. The petroleum migrated towards the southwest-south entering the Silurian reservoir beds in Tazhong first. Then, it further migrated within Silurian from northwest to southeast along the highs of the Structural Belts to the region of the Silurian pinchout boundary in Tazhong. In Tabei Uplift, during the first-stage of pool formation, the petroleum was also from the lower and middle Cambrian source rocks in the Manjiaer sag. It migrated northwest entering the Silurian reservoir beds in the Tabei Uplift firstly, and then the migration continued in the same direction within the Silurian reservoirs and finally the petroleum was trapped in higher positions. During the second-stage pool formation in the Silurian beds in the areas around Awati sag, the petroleum mainly came from the lower-middle Cambrian source rocks in the Awati sag. The petroleum migrated from the generation center to Silurian reservoirs in all directions around the sag through major paths, and the petroleum was finally trapped in higher locations.     

塔里木盆地哈拉哈塘地区碳酸盐岩油气地质特征与富集成藏研究

塔里木盆地塔北隆起哈拉哈塘地区奥陶系由于现今构造位置低,埋深在6500~8000m,长期以来一直将其作为塔北隆起的一个次级凹陷单元,并认为是一个海相油气的生烃凹陷,制约了哈拉哈塘的油气勘探。本文通过对哈拉哈塘构造解析和沉降演化过程恢复,发现哈拉哈塘地区是从石炭纪才开始转为负向构造单元,加里东-早海西期,它属于轮南大型古潜山的西斜坡部位;奥陶系鹰山组-一间房组碳酸盐岩经历了多期岩溶的叠加改造,风化岩溶缝洞体储层发育。通过最新钻井资料及油气地球化学分析数据,证实哈拉哈塘奥陶系沉积时期不是生烃凹陷,不发育烃源岩,哈拉哈塘及其以北地区的油气是来自南部满西地区的中、上奥陶统烃源岩。油气藏解剖表明,哈拉哈塘地区在晚海西期成藏;三叠系沉积前北部构造抬升,导致奥陶系油藏遭受局部破坏和降解。自三叠纪沉积以来,奥陶系油藏一直处于持续深埋过程,盖层不断加厚,油藏基本保持了晚海西期成藏时的形态,因此,哈拉哈塘地区是一个古老的油气系统。油气成藏条件分析表明,哈拉哈塘地区油气成藏条件优越,生储盖条件配置良好,奥陶系碳酸盐岩岩溶储层广泛分布,并处在油气向古隆起高部位运移的有利路径上,具有大面积、准层状富集油气的特征。     

塔北、塔中地区碳酸盐岩及其原油中的二苯并噻吩类化合物

塔里木盆地塔北、塔中地区四口井(库南1井,轮南46井,塔中12井和塔参1井)寒武-奥陶系12个碳酸盐岩烃源岩(泥灰岩,泥质灰岩和云岩)岩芯样品抽提物芳烃组分中的二苯并噻吩类化合物组成和丰度变化特征可分为三种类型:Ⅰ二苯并噻吩、甲基二苯并噻吩型;Ⅱ二苯并噻吩、甲基二苯并噻吩、二甲基二苯并噻吩+三甲基芴混合物型;Ⅲ二苯并噻吩、甲基二苯并噻吩、二甲基二苯并噻吩和三甲基二苯并噻吩型。研究的塔北、塔中隆起11个海相油二苯并噻吩类化合物分布类型均为二苯并噻吩、甲基二苯并噻吩、二甲基二苯并噻吩和三甲基二苯并噻吩型,和海相烃源岩二苯并噻吩类化合物第Ⅲ种分布类型完全相同。据此推断:塔北隆起8个海相油可能主要来源于塔北轮南地区下奥陶统;塔中隆起3个海相油可能来源于塔中地区中-上奥陶统。     

塔里木盆地塔中隆起志留系油气聚集控制因素

塔中隆起志留系中沥青及可动油气显示十分丰富。油气聚集的基本特征是多油气源、多成藏期、多油气藏类型、多油气产状。纵向上志留系油气分布受盖层控制,沥青和稠油分布在塔塔埃尔塔格组下段红色泥岩段以下,而现今可动油则集中分布在柯坪塔格组上二亚段灰色泥岩之下。平面上,志留系油气聚集受构造背景控制,继承性发育的古隆起决定各个时期油气运移指向,塔中地区油气基本上是自北西向南东方向运移。潮坪相沉积决定了薄砂层单个砂体规模不大,一系列砂体靠断层沟通。塔中地区志留系形成了油气丰度不高、在空间上叠置连片、大面积分布、受多种圈闭类型控制的油气聚集特征。     

Tectonic fracture and its significance in hydrocarbon migration and accumulation: a case study on middle and lower Ordovician in Tabei Uplift of Tarim Basin,NW China

Middle and lower Ordovician carbonate rock in the Tabei Uplift of the Tarim Basin forms important fractured reservoir beds. Core and log data indicate that tectonic fractures, as the main fractures in the Tabei Uplift, could be mainly classified into two types: oblique fractures and approximately vertical fractures. The fractures are mainly NNW‐trending and NNE‐trending, coincident with the large faults nearby. Fracture abundance was also controlled by lithology, and faults nearby played a significant role. Cores, thin sections and tests show that these carbonate rocks have as much as 2.5% fracture porosity and as much as 150 md fracture permeability. Based on the intersection of fractures in cores, together with fluid inclusion temperature data, and the timing of faulting from seismic profiles, tectonic fractures were considered to be mainly formed in three periods: the late Silurian when the first‐stage oblique fractures were formed, the late Permian when approximately vertical fractures were formed, and the late Tertiary when the second‐stage oblique fractures were formed. Lower Cambrian source rocks started to enter the stage of generous hydrocarbon generation and expulsion in the Silurian. Ordovician source rocks started to enter the stage of generous hydrocarbon generation and expulsion in the Permian and enter the over‐mature stage in the late Tertiary when light oil was generated. Timing of tectonic fractures formation and burial history analysis suggest that fractures formation might coincide with oil accumulation when fractures provided the pathway and storage space for the low permeability and low porosity reservoir beds caused by previous compaction and cementation. Considering the presence of a large amount of fracture‐developed dolomite in the deeper Ordovician Penglaiba Formation, the undrilled Penglaiba Formation should be paid more attention. Copyright © 2015 John Wiley & Sons, Ltd.     

North-south Differentiation of the Hydrocarbon Accumulation Pattern of Carbonate Reservoirs in the Yingmaili Low Uplift, Tarim Basin,Northwest China

By analyzing the characteristics of development, structural evolution and reservoir beds of the residual carbonate strata, this study shows that the residual carbonate strata in the Yingmaili low uplift are favorable oil and gas accumulation series in the Tabei （northern Tarim uplift） uplift. There are different patterns of hydrocarbon accumulation on the northern and southern slopes of the Yingmaili low uplift. The north-south differentiation of oil reservoirs were caused by different lithologies of the residual carbonate strata and the key constraints on the development of the reservoir beds. The Mesozoic terrestrial organic matter in the Kuqa depression and the Palaeozoic marine organic matter in the Manjiaer sag of the Northern depression are the major hydrocarbon source rocks for the northern slope and southern slope respectively. The hydrocarbon accumulation on the northern and southern slopes is controlled by differences in maturity and thermal evolution history of these two kinds of organic matter. On the southern slope, the oil accumulation formed in the early stage was destroyed completely, and the period from the late Hercynian to the Himalayian is the most important time for hydrocarbon accumulation. However, the time of hydrocarbon accumulation on the northern slope began 5 Ma B.P. Carbonate inner buried anticlines reservoirs are present on the southern slope, while weathered crust and paleo-buried hill karst carbonate reservoirs are present on the northern slope. The northern and southern slopes had different controlling factors of hydrocarbon accumulation respectively. Fracture growth in the reservoir beds is the most important controlling factor on the southern slope; while hydrocarbon accumulation on the northern slope is controlled by weathered crust and cap rock.     

Accumulation and Reformation of Silurian Reservoir in the Northern Tarim Basin

Silurian sandstone in Tarim Basin has good reservoir properties and active oil and gas shows, especially thick widely-distributed bituminous sandstone. Currently, the Silurian was found containing both bitumen and conventional reservoirs, with petroleum originating from terrestrial and marine source rocks. The diversity of their distribution was the result of "three sources, three stages" accumulation and adjustment processes. "Three sources" refers to two sets of marine rocks in Cambrian and Middle-Upper Ordovician, and a set of terrestrial rock formed in Triassic in the Kuqa depression. "Three stages" represents three stages of accumulation, adjustment and reformation occurring in Late Caledonian, Late Hercynian and Late Himalayan, respectively. The study suggests that the Silurian bitumen is remnants of oil generated from Cambrian and Ordovician source rocks and accumulated in the sandstone reservoir during Late Caledonian-Early Hercynian and Late Hercynian stages, and then damaged by the subsequent two stages of tectonic uplift movements in Early Hercynian and Pre-Triassic. The authors presumed that the primary paleo-reservoirs formed during these two stages might be preserved in the Silurian in the southern deep part of the Tabei area. Except for the Yingmaili area where the Triassic terrestrial oil was from the Kuqa Depression during Late Himalayan Stage, all movable oil reservoirs originated from marine sources. They were secondary accumulations from underlying Ordovician after structure reverse during the Yanshan-Himalayan stage. Oil/gas shows mixed-source characteristics, and was mainly from Middle-Upper Ordovician. The complexity and diversity of the Silurian marine primary properties were just defined by these three stages of oil-gas charging and tectonic movements in the Tabei area.     

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 stability 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 hydrocarbons experienced a long-distance migration.     

黔中隆起及其周缘地区“下组合”油气地质特征

黔中隆起及其周缘地区包括滇黔北部坳陷、黔中隆起、滇东隆起、黔西南坳陷、黔南坳陷和武陵坳陷等六个一级构造单元。“下组合”包括震旦系、寒武系、奥陶系和志留系,具有丰富的油气资源和较好的油气成藏条件。两套区域性海相烃源岩,包括下寒武统牛蹄塘组碳质页岩和上奥陶统五峰组—下志留统龙马溪组石灰岩和碳质页岩,Ro值普遍在2%以上,主体处于高成熟晚期—过成熟早期。上震旦统陡山沱组发育地区性黑色页岩和碳质灰岩等烃源岩。主力储层包括上震旦统灯影组、中—上寒武统、下奥陶统桐梓组—红花园组及下志留统石牛栏组。区域盖层发育于下寒武统下部和下志留统下部,皆以泥质岩为主。各区块海相“下组合”纵向生储盖组合发育情况有所差异,黔中隆起区和黔南坳陷有两套组合,滇黔北部坳陷则有四套组合。以下寒武统牛蹄塘组为烃源岩、上震旦统灯影组白云岩为储层、下寒武统泥岩为盖层的生储盖组合,是黔中隆起及其周缘地区“下组合”勘探的主要目的层系。