共查询到20条相似文献,搜索用时 15 毫秒
1.
中国中西部前陆盆地多期成藏、晚期聚气的成藏特征 总被引:15,自引:0,他引:15
中国中西部前陆盆地具有优越的天然气成藏条件,同时具有晚期成藏的特征。文中在典型气藏解剖的基础上重点讨论了川西、柴北缘和准南缘前陆盆地的成藏过程,从而指出中国中西部前陆盆地具有多期聚集、晚期聚气的成藏特征,明确指出中国中西部前陆盆地具有最主要的两大成藏期,一是燕山晚期,主要是被动陆缘或中部前陆盆地三叠系烃源岩的油气聚集期;二是喜山晚期,受新构造运动影响,主要是西部陆内前陆盆地的中、新生界烃源岩的天然气成藏期和中部周缘前陆盆地的天然气的调整期。新近纪前陆盆地的发育期控制了中国中西部前陆盆地以中生界煤系烃源岩为主的晚期天然气的聚集。 相似文献
2.
新生代挤压盆地是我国中-西部的重要油气勘探领域。根据挤压盆地的发育部位、盆地基底、充填层序、构造叠加和盆山耦合形式等条件,本文在我国中-西部识别出准(噶尔)西北缘型、四川盆地西缘型、柴(达木)北缘型和准(噶尔)南缘型等4种新生代挤压盆地,前两者发育海西晚期—印支期前陆盆地,后两者具有喜马拉雅造山期的再生前陆盆地特征。对准西北缘、四川盆地西缘、柴北缘和准南缘新生代挤压盆地的对比研究表明,它们在烃源岩、储盖组合等成藏条件上存在明显的差异,而晚期前陆发育对柴北缘型和准南缘型挤压盆地烃源岩演化具有明显的控制作用。在不同新生代挤压盆地典型油气藏解剖研究的基础上,认为燕山期及之前是准西北缘型和四川盆地西缘型挤压盆地主要的成藏期,喜马拉雅造山期则主要表现为准西北缘型挤压盆地的油气藏保存和四川盆地西缘型挤压盆地油气藏的调整和定型;喜马拉雅晚期是柴北缘型挤压盆地最主要的成藏期,而多期前陆盆地的准南缘型挤压盆地具有多期成藏的特征,但喜马拉雅晚期的油气成藏最为重要。 相似文献
3.
中国中西部小型克拉通盆地群的叠合复合性质及其含油气系统 总被引:14,自引:2,他引:12
中国中西部盆地油气资源潜力巨大,是晚古生代一早中生代一新生代大型造山带环绕的小型克拉通盆地,盆地核心为构造相对稳定的小型克拉通,边缘环绕构造活跃的前陆冲断带。与北美、欧洲等大型含油气盆地相比,中国含油气盆地规模小、构造活动性强。盆地普遍经历:(1)寒武—志留纪,各自漂离于大洋中的小型克拉通盆地;(2)泥盆—二叠纪,亚欧板块南缘地体增生;(3)三叠—古近纪,特提斯洋关闭,陆相断(坳)陷盆地;(4)新近纪以来,再生前陆盆地等四个构造演化阶段。从下而上叠合了早古生代海相克拉通盆地、晚古生代海陆交互相克拉通盆地、早中生代陆相断(坳)陷盆地和新生代再生前陆盆地四个构造层序。古生界克拉通盆地构造相对稳定,古生代发育多期不整合界面和大型古隆起;中新生代前陆盆地叠置复合在其边缘,发育成排成带的构造。中国含油气盆地的叠合-复合性质决定了其叠合-复合含油气系统的特征:具有多油气系统、多源多阶段生烃、多期成藏、多层系含油气。中国中西部盆地的油气勘探主要包括古生界小型克拉通层序和中新生代前陆层序两大领域,其中早古生代克拉通层序以古隆起及其斜坡、晚古生代克拉通层序以大面积岩性储集体、中新生代前陆盆地以大型冲断带控制着油气的成藏与富集。 相似文献
4.
5.
波斯湾油气风云与中国中西部油气开发 总被引:4,自引:3,他引:4
波斯湾盆地与中国中西部盆地同属特提斯构造域 ,有着类似的演化特征 :早期离散期形成裂谷盆地 ;中期漂移期形成克拉通盆地 ;晚期聚合期形成前陆盆地 ,构成大型叠合盆地。克拉通盆地内同期隆起有利于油气的早期运移富集 ;前陆盆地内褶皱—冲断带发育 ,裂隙常构成良好的储层形成晚期油气藏 ;构造枢纽带常构成油气富集带 ;碳酸盐—蒸发岩层序中孔隙—溶洞—裂缝构成完整的储集—渗滤体系 ,在总体上形成复合油气系统。中国中西部油气勘探新区应重视碳酸盐台地与碎屑重力流盆地之间的枢纽带。 相似文献
6.
Multiple source rock assemblages were deposited in the sedimentary provinces in South China in geologic history,and some of them were destructed by and some survived against multiple tectonic movements.Therefore,multiple sources,mixed sources,and uneven distribution of sources occurred in the marine sedimentary basins in South China during the late stage of hydrocarbon pooling.Epidiagenesis of the marine carbonate reservoirs and its modification to reservoir poroperm characteristics determined the formation and the scale of natural gas pools.The exploration practices show that the large to medium gas fields mainly occur in areas with high-quality reservoirs.Detailed study of the paleo-oil accumulations and typical oil and gas reservoirs reveals that the basins experienced multiphase superimposition and modification,leading to the distribution of the Paleozoic paleo-oil accumulations and bitumen in the peripheral areas.The phenomenon that oil and gas production concentrates in the Sichuan basin indicates that the overall sealing conditions of a basin determine the oil/gas potentials and the scale of oil and gas production.This is a critical factor controlling the accumulation and distribution of gas in the marine sequences in South China.The early oil and gas pools in the Yangtze platform left billions of bitumen in the peripheral areas due to the destruction of seals.Since the Himalayan,"late-generation and late-accumulation" gas pools represented by the gas pools in the Sichuan (四川) basin were formed in the marine sedimentary sequences in South China as a result of the change of the sealing conditions.Current gas discoveries appear to be "paleo-generation and paleo-accumulation" gas pools but actually are "late-generation and late-accumulation" gas pools.These patterns of hydrocarbon pooling clearly depict themselves in western Sichuan basin and Weiyuan (威远)gas field.It is revealed that the gas pools in the Sichuan basin were mainly formed as a result of hydrocarbon phase change (thermal cracking of oil to gas),miscible migration,and dynamic equilibration since the Himalayan.A large number of gas pools were formed in the Himalayan and the gas pools in the marine sequences are characterized by late pooling; this kind of gas fields/pools are controlled by:(1) effectiveness of modification and superimposition of the marine basins,(2) effectiveness of the source rocks,(3) effectiveness of the overall preservation conditions,and (4) effectiveness of plays. 相似文献
7.
准噶尔盆地火山岩油气勘探取得重大进展。笔者经综合研究,提出影响该区天然气藏形成的石油地质主要特征是:前陆坳陷控制了烃源岩区域展布,后碰撞火山岩是主要的储层,古生代晚期的构造优化了储层物性并形成圈闭。松喀尔苏组为前陆坳陷磨拉石建造的近端粗碎屑岩沉积,是克拉美丽造山事件后快速沉积产物,作为主要烃源岩的下石炭统滴水泉组,是与松喀尔苏组同期前陆坳陷不同位置的沉积层系,滴水泉组是前陆坳陷中央的细粒沉积层系。后碰撞火山岩覆盖在前陆坳陷沉积层系之上,分布广泛,分布范围不受古生代造山带和现今构造单元控制。二叠纪发育断陷构造,形成凹隆相间的构造格局,在构造高部位的隆起区石炭系火山岩风化壳和构造裂缝,优化改善了火山岩储层的储集性能,形成有利油气运移通道和储集空间。克拉美丽山南缘的前陆坳陷中央为有利烃源岩分布区,该范围内的构造高部位的火山岩发育区,将是准噶尔盆地东部下一步火山岩油气藏勘探的有利区域。 相似文献
8.
中国喜马拉雅构造运动的陆内变形特征与油气矿藏富集 总被引:12,自引:0,他引:12
在前人研究的基础上,结合近年来在油气勘探中不断积累的地质资料和地质认识,提出了中国喜马拉雅构造运动的陆内变形特征及其分布规律受控于小型克拉通板块拼贴的基底结构和印/欧碰撞与太平洋板块俯冲所主导的双重控制因素;喜马拉雅构造运动的发育特征主要表现为三种动力学机制:青藏高原隆升、盆地与造山带体制和东部拉张活动。喜马拉雅构造运动的大地构造格局及其构造变形分布规律集中体现为4个构造域:青藏高原隆升区、环青藏高原盆山体系、稳定区和环西太平洋裂谷活动区。我国沉积盆地在喜马拉雅构造运动中的构造特征分为三种类型:(1)东部渤海湾、松辽等盆地受拉张构造环境控制的裂谷沉降;(2)中部四川、鄂尔多斯等盆地受青藏高原的向东推挤、盆缘冲断、盆内抬升剥蚀;(3)西部的塔里木、准噶尔、柴达木等盆地受青藏高原的向北推挤、冲断挠曲沉降,表现为克拉通单边或双边的压缩挠曲沉降与克拉通内部的冲断隆升沉降等多种盆山耦合形式。喜马拉雅构造运动控制着中国油气晚期定位与富集成藏,主要体现在:盆地的沉积与成藏,形成新生界自生自储的含油气盆地和油气藏;圈闭形成与油气运聚成藏;早期油气藏的调整和再分配;油气藏的破坏。 相似文献
9.
10.
评述“前陆盆地”名词在中国中西部含油气盆地中的引用——反思中国石油构造学的发展 总被引:22,自引:5,他引:17
“前陆盆地”一词,在中国中西部含油气盆地研究中被许多学者广泛引用,在空间上有“泛前陆盆地化”,在地史演化中有“扩大化”,名词术语引用上有“复杂化”的倾向,因而引起同行的关注。本文从文献中追踪前陆盆地原命名者的涵义和沿革,正确理解国外学者提出前陆盆地的特及模式,再根据中国的实际地质特征与国外典型前陆盆地对比,结果发现我国中西部前陆盆地的特殊在于大国外所称的前陆盆地的共同性。因而认为在中国中西部直接引用“前陆盆地”一词不当。建议采用“陆内俯冲型前陆盆地”(Intracontinental subduction foreland basin)一(间称-C型前陆盆地),以示有中国地质特色的前陆盆地,为今后建立油气成藏模式和指导油气勘探理论依据。最后,还讨论了中国石油学发展中,值得反思的3个问题。 相似文献
11.
中国中西部前陆盆地的地质特征及油气聚集 总被引:35,自引:2,他引:35
中国中西部前陆盆地具有十分丰富的油气资源,近年来油气勘探也取得了很大的成果,但总体上来说其地质情况复杂、研究程度较低。世界上典型的前陆盆地一般位于造山带和稳定的克拉通之间的狭长槽地,而在中国中西部则主要为与古特提斯造山带在新特提斯阶段再活动有关的陆内会聚形成的“再生”前陆盆地,因此与世界典型前陆盆地相比中国中西部前陆盆地具有一定的“特殊性”。根据两期前陆的叠合程度差异造成的盆地几何形态、挠曲沉降、地层层序、沉积充填、构造变形特征的特点,将中国中西部前陆盆地归纳为改造型、新生型、叠加型和早衰型四种组合类型的前陆盆地。中西部不同组合类型前陆盆地具有不同的结构特征,决定了不同组合类型前陆盆地成藏特征和油气勘探潜力上的差异。 相似文献
12.
三塘湖盆地属西部典型的改造型叠合盆地,火山岩油气藏主要分布于石炭系、二叠系火山岩中。本文结合盆地构造演化史与生烃史,分析了三塘湖盆地石炭-二叠纪火山岩油气藏形成的动态过程。火山岩油气藏主要形成于二叠纪末-三叠纪海西印支期和侏罗纪末-白垩纪末期的燕山期,油气藏的形成及后期调整与构造运动密切相关。火山岩油气藏具多期运聚、多期成藏和多期调整改造成藏特征,其成藏模式为以火山岩风化壳为储集层、下覆湖相泥岩为烃源岩,油气在构造背景下,沿不整合面聚集成藏,形成下生上储地层型油藏组合模式。本文结合构造演化史分析三塘湖盆地火山岩油气成藏过程,对西部沉积盆地下组合火山岩油气藏的勘探具有良好借鉴与指导意义。 相似文献
13.
川西和川东北地区处于扬子地台西北缘,均具有褶皱冲断带-前陆盆地的二元结构,其构造特征具一定相似性。根据地震资料解释和典型气藏解剖,再结合前人研究成果,分析了川西和川东北地区构造演化差异性及其对各自成藏特征的影响,结果表明:川西地区主要受龙门山造山带影响,从印支期中晚期开始发育前陆盆地,之后主要受燕山中晚期和喜马拉雅期构造运动的影响;而川东北地区从燕山早期开始发育前陆盆地,之后在燕山中期和晚期受大巴山、米仓山和雪峰山联合作用影响,最后大巴山造山带在喜马拉雅期的强烈活动使其最终定型。上述差异构造演化对川西和川东北地区陆相层系的成藏特征的影响主要表现在4个方面:烃源岩的发育、输导体系的形成、气藏的保存和天然气成藏过程。川西地区主要发育须家河组烃源岩,形成了以NE向和SN向断裂及其伴生裂缝为主的输导体系,多期构造运动形成的大型通天断裂影响了山前断褶带气藏的保存,成藏经历了印支晚期、燕山中期、晚期和喜马拉雅期4个关键时刻。川东北地区发育须家河组和下侏罗统两套烃源岩,输导体系以NW向断裂为主,隆升剥蚀和大型断裂造成了山前断褶带较差的保存条件,成藏经历了燕山中期、燕山晚期和喜马拉雅期三个关键时刻。 相似文献
14.
B.P.Singh 《地学前缘(英文版)》2013,4(2):199-212
The Paleogene succession of the Himalayan foreland basin is immensely important as it preserves evidence of India-Asia collision and related records of the Himalayan orogenesis. In this paper, the depositional regime of the Paleogene succession of the Himalayan foreland basin and variations in composition of the hinterland at different stages of the basin developments are presented. The Paleogene succession of the western Himalayan foreland basin developed in two stages, i.e. syn-collisional stage and post-collisional stage. At the onset, chert breccia containing fragments derived from the hanging walls of faults and reworked bauxite developed as a result of erosion of the forebulge. The overlying early Eocene succession possibly deposited in a coastal system, where carbonates represent barriers and shales represent lagoons. Up-section, the middle Eocene marl beds likely deposited on a tidal flat. The late Eocene/Oligocene basal Murree beds, containing tidal bundles, indicate that a mixed or semi-diurnal tidal system deposited the sediments and the sedimentation took place in a tide-dominated estuary. In the higher-up, the succession likely deposited in a river-dominated estuary or in meandering rivers. In the beginning of the basin evolution, the sediments were derived from the Precambrian basement or from the metasediments/volcanic rocks possessing terrains of the south. The early and middle Eocene (54.7–41.3 Ma) succession of the embryonic foreland possibly developed from the sediments derived from the Trans-Himalayan schists and phyllites and Indus ophiolite of the north during syn-collisional stage. The detrital minerals especially the lithic fragments and the heavy minerals suggest the provenance for the late Eocene/Oligocene sequences to be from the recycled orogenic belt of the Higher Himalaya, Tethyan Himalaya and the Indus-suture zone from the north during post-collisional stage. This is also supported by the paleocurrent measurements those suggest main flows directed towards southeast, south and east with minor variations. This implies that the river system stabilized later than 41 Ma and the Higher Himalaya attained sufficient height around this time. The chemical composition of the sandstones and mudstones occurring in the early foreland basin sequences are intermediate between the active and passive continental margins and/or same as the passive continental margins. The sedimentary succession of this basin has sustained a temperature of about 200 °C and undergone a burial depth of about 6 km. 相似文献
15.
The South China Sea is rich in oil and gas resources. With the increasing exploration of oil and gas resources in the northern South China Sea and the increasing demand for energy in the world, The central‐southern South China Sea have become important constituencies for oil and gas resources. The central‐southern basins of South China Sea can be divided into three types of basin groups, namely, the southern basin group (Zengmu Basin, Brunei‐Sabah Basin), the western basin group (Wan'an Basin, Zhong jiannan Basin) and the Central Basin Group (Liyue Basin, Beikang Basin, Nanweixi Basin and Palawan Basin). At present, the degree of exploration is relatively low, and the source rock has not yet formed a understanding of the system. The main source rock development time, source rock characteristics, hydrocarbon generation potential and control factors of each basin group are still unclear, which seriously restricts the exploration of oil and gas. Based on the sedimentary facies distribution and sedimentary filling evolution, combined with the geoche mical characteristics of the source rocks, the source age, organic matter type, hydrocarbon generation potential and main controlling factors of the basins in the central‐southern basins are discussed. By the detailed research on delta scale, provenance system, paleoclimate conditions, ancient vegetation development and hydroca rbon generation parent material, the main controlling factors of hydrocarbon generation potential of source rocks in each basin group are revealed. 相似文献
16.
Upendra Baral Ding Lin Tapos Kumar Goswami Mondip Sarma Muhammad Qasim Devojit Bezbaruah 《地学学报》2019,31(1):18-27
Geochronology is useful for understanding provenance, and while it has been applied to the central and western Himalaya, very little data are available in the eastern Himalaya. This study presents detrital zircon U–Pb ages from the late Palaeocene–Eocene Yinkiong Group in NE India. The samples are from the late Palaeocene to early Eocene Lower Yinkiong Formation, and the Upper Yinkiong Formation deposited during the early to mid‐Eocene within the Himalayan foreland basin. The U–Pb ages of the detrital zircon within the Lower Yinkiong Formation are older than late Palaeozoic, with a cratonic and early Himalayan Thrust Belt affinity, whereas the Cenozoic grains in the Upper Yinkiong Formation indicate a Himalayan Thrust Belt source and possibly a granitic body within the Asian plate. The shift of the sources and the changes in the foreland basin system strongly suggest that the India–Asia collision in the Eastern Himalaya began before or immediately after the deposition of the Upper Yinkiong Formation, i.e., within the early Eocene (c. 56 to 50 Ma). 相似文献
17.
To reveal the causes of differences in the hydrocarbon accumulation in continental marginal basins in the centralsouthern South China Sea,we used gravity-magnetic,seismic,drilling,and outcrop data to investigate the tectonic histories of the basins and explore how these tectonic events controlled the hydrocarbon accumulation conditions in these basins.During the subduction of the Cenozoic proto-South China Sea and the expansion of the new South China Sea,the continental margin basins in the central-southern South China Sea could be classified as one of three types of epicontinental basins:southern extensional-foreland basins,western extensional-strike slip basins,and central extensional-drift basins.Because these basins have different tectonic and sedimentary histories,they also differ in their accumulated hydrocarbon resources.During the Cenozoic,the basin groups in the southern South China Sea generally progressed through three stages:faulting and subsidence from the late Eocene to the early Miocene,inversion and uplift in the middle Miocene,and subsidence since the late Miocene.Hydrocarbon source rocks with marine-continental transitional facies dominated byⅡ-Ⅲkerogen largely developed in extremely thick Miocene sedimentary series with the filling characteristics being mainly deep-water deposits in the early stage and shallow water deposits in the late stage.With well-developed sandstone and carbonate reservoirs,this stratum has a strong hydrocarbon generation potential.During the Cenozoic,the basin groups in the western South China Sea also progressed through the three developmental stages discussed previously.Hydrocarbon source rocks with lacustrine facies,marine-continental transitional facies,and terrigenous marine facies dominated byⅡ2-Ⅲkerogen largely developed in the relatively thick stratum with the filling characteristics being mainly lacustrine deposits in the early stage and marine deposits in the late stage.As a reservoir comprised of self-generated and self-stored sandstone,this unit also has a high hydrocarbon generation potential.Throughout those same three developmental stages,the basin groups in the central South China Sea generated hydrocarbon source rocks with terrigenous marine facies dominated byⅢkerogen that have developed in a stratum with medium thicknesses with the filling characteristics being mainly sandstone in the early stage and carbonate in the late stage.This reservoir,which is dominated by lower-generation and upper-storage carbonate rocks,also has a high hydrocarbon generation potential. 相似文献
18.
柴达木盆地西部英东地区多期构造运动导致油气分布复杂,勘探难度大.采用油气地球化学、流体包裹体、定量荧光以及傅里叶红外光谱等方法系统分析英东地区油气成藏演化过程.研究表明:(1)英东地区新近系储层发育黄色和蓝色荧光两类油包裹体和天然气包裹体,黄色荧光和蓝色荧光油气包裹体对应两期油气充注时间分别为12 Ma和5 Ma.(2)现今油藏原油具有同源-低熟的特点,黄色荧光油包裹体成熟度较低与现今油藏原油特征相似, 是现今油藏的主要贡献者.(3)蓝色荧光油包裹体的成熟度较高,蓝色荧光油包裹体和气烃包裹体是早期低熟原油沿后期构造产生的断层疏导体系向上调整运移至浅层分馏和脱气的产物.通过以上分析明确了英东油藏经历了下油砂组(N21)沉积末期(12 Ma)的低熟原油充注和上油砂组(N22)沉积末期(5 Ma)至今油气调整与改造的成藏过程, 与喜山期主要构造活动期有很好的对应关系,反映构造活动对油气成藏具有重要控制作用. 相似文献
19.
广西西南部十万大山盆地,大地构造位置属于华南板块的西北缘,是在华南板块与扬子板块拼接之后,晚古生代华南洋再一次打开,又接受沉积的。泥盆纪一早二叠世,该地区形成被动大陆边缘;晚二叠世末,随着太平洋板块向西俯冲,该地区转变成弧后盆地;早三叠世一伤罗纪,进一步转化成前陆盆地。在被动大陆边缘的碎屑岩陆架沉积阶段,生成碎屑岩烃源岩;在碳酸盐台地沉降阶段,发育砂屑灰岩、藻灰岩、礁灰岩和暴露作用生成的白云岩储集岩。因而其早期被动大陆边缘阶段构成了古生新储组合;前陆盆地早期,在前渊盆地内沉积了一套碎屑岩烃源岩,它与早期的储集层构成了新生古储组合,同时也对下伏地层起到了封闭作用。随着逆冲体向西推进,沉积地层也逐层向克拉通斜坡上超覆,发育地层圈闭。前陆中期阶段快速沉积的巨厚的复理石和晚期的磨拉石促进了早期烃源岩的迅速埋藏、成熟和保存。十万大山盆地具备了典型前陆盆地的生烃成藏地质条件,因而该盆地有较好的油气远景。 相似文献
20.
ZHAO Zongju ZHU Yan YANG Shufeng WANG Genghai XU Yunjun FENG Jialiang DENG Hongying Department of Geoscience Zhejiang University Hangzhou Zhejiang Hangzhou Institute of Petroleum Geology Hangzhou Zhejiang Zhou Jian Fei Zhenbi 《《地质学报》英文版》2002,76(2):205-220
Through an integrated study of Mesozoic and Palaeozoic petroleum geology in southern China and a summing-up of the results of exploration, the authors tentatively put forward a set of methods of studying petroleum systems in modified residual basins or superposed basins. Its core idea is to put emphasis on the study of the dynamic evolution of petroleum systems. The tempo-spatial evolution, hydrocarbon-generating processes and hydrocarbon-generating intensities and amounts of resources in different geological stages of chief source rocks are mainly deduced backward by 3-D basin modelling. The regularities of formation and destruction of oil and gas accumulations are summarized by analyzing the fossil and existing oil and gas accumulations, the direction of migration is studied by palaeo-structural analysis, and the dynamic evolution of Palaeozoic and Mesozoic petroleum systems in southern China is studied according to stages of major tectonic movements. The authors suggest that the realistic exploration 相似文献