Petroleum geological characteristics and exploration targets of the oil-rich sags in the Central and West African Rift System

Based on seismic,drilling,and source rock analysis data,the petroleum geological characteristics and future exploration direction of the oil-rich sags in the Central and West African Rift System(CWARS)are discussed.The study shows that the Central African Rift System mainly develops high-quality lacustrine source rocks in the Lower Cretaceous,and the West African Rift System mainly develops high-quality terrigenous organic matter-rich marine source rocks in the Upper Cretaceous,and the two types of source rocks provide a material basis for the enrichment of oil and gas in the CWARS.Multiple sets of reservoir rocks including fractured basement and three sets of regional cap rocks in the Lower Cretaceous,the Upper Cretaceous,and the Paleogene are developed in the CWARS.Since the Late Mesozoic,due to the geodynamic factors including the dextral strike-slip movement of the Central African Shear Zone,the basins in different directions of the CWARS differ in terms of rifting stages,intervals of regional cap rocks,trap types and accumulation models.The NE-SW trending basins have mainly preserved one stage of rifting in the Early Cretaceous,with regional cap rocks developed in the Lower Cretaceous strata,forming traps of reverse anticlines,flower-shaped structures and basement buried hill,and two types of hydrocarbon accumulation models of"source and reservoir in the same formation,and accumulation inside source rocks"and"up-source and down-reservoir,and accumulation below source rocks".The NW–SE basins are characterized by multiple rifting stages superimposition,with the development of regional cap rocks in the Upper Cretaceous and Paleogene,forming traps of draping anticlines,faulted anticlines,antithetic fault blocks and the accumulation model of"down-source and up-reservoir,and accumulation above source rocks".The combination of reservoir and cap rocks inside source rocks of basins with multiple superimposed rifting stages,as well as the lithologic reservoirs and the shale oil inside source rocks of strong inversion basins are important fields for future exploration in basins of the CWARS.

Geological characteristics of the southern segment of the Late Sinian–Early Cambrian Deyang-Anyue rift trough in Sichuan Basin, SW China

Based on the latest drilling, seismic and field outcrop data, the geological characteristics(e.g. strata, development and sedimentary evolution) of the southern segment of the Late Sinian–Early Cambrian Deyang–Anyue rift trough in the Sichuan Basin are analyzed. First, the strata in the southern segment are complete. The first to second members of Dengying Formation(Deng 1 + Deng 2) are found with relatively stable thickness(400–550 m), and the third to fourth members(Deng 3+ Deng 4) show great thickness difference between the marginal trough and the inner trough, which is up to 250 m. The Cambrian Maidiping Formation and Qiongzhusi Formation in southern Sichuan Basin are relatively thin, with the thickness changing greatly and frequently. Second, the Deyang–Anyue rift trough extended southward during the Deng 4 period, affecting southern Sichuan Basin. Compared to the middle and northern segments of the rift trough, the southern segment is generally wide, gentle and shallow, with multiple steps, and alternating uplifts and sags, which are distributed in finger shape. Third, the Deng 1 + Deng 2 in southern Sichuan Basin records the dominance of carbonate platform and unobvious sedimentary differentiation, and the Deng 4 exhibits obvious sedimentary differentiation, namely, basin–slope–secondary slope–slope–secondary slope–platform margin–restricted platform, from the inner trough to the marginal trough. Fourth, the rift trough in southern Sichuan Basin has evolved in four stages: stabilization of Deng 1–Deng 2, initialization of Deng 3–Deng 4, filling of Maidiping–Qiongzhusi, and extinction of Canglangpu Formation.

Structural features and exploration targets of platform margins in Sinian Dengying Formation in Deyang-Anyue Rift, Sichuan Basin, SW China

Based on the seismic, logging, drilling and other data, the distribution, structural types and mound-shoal hydrocarbon accumulation characteristics of platform margins of the Sinian Dengying Formation in the Deyang-Anyue Rift and its periphery were analyzed. Four types of platform margins are developed in the Dengying Formation, i.e., single-stage fault-controlled platform margin, multi-stage fault-controlled platform margin, gentle slope platform margin, and overlapping platform margin. In the Gaoshiti West-Weiyuan East area, single-stage fault controlled platform margins are developed in the Deng 2 Member, which trend in nearly NEE direction and are shielded by faults and mudstones, forming fault-controlled–lithologic traps. In the Lezhi-Penglai area, independent and multi-stage fault controlled platform margins are developed in the Deng 2 Member, which trend in NE direction and are controlled by synsedimentary faults;the mound-shoal complexes are aggraded and built on the hanging walls of the faults, and they are shielded by tight intertidal belts and the Lower Cambrian source rocks in multiple directions, forming fault-controlled–lithologic and other composite traps. In the Weiyuan-Ziyang area, gentle slope platform margins are developed in the Deng 2 Member, which trend in NW direction;the mound-shoal complexes are mostly thin interbeds as continuous bands and shielded by tight intertidal belts in the updip direction, forming lithologic traps. In the Gaoshiti-Moxi-Yanting area, overlapping platform margins are developed in the Deng 2 and Deng 4 members;the mound-shoal complexes are aggraded and overlaid to create platform margin buildup with a huge thickness and sealed by tight intertidal belts and the Lower Cambrian mudstones in the updip direction, forming large-scale lithologic traps on the north slope of the Central Sichuan Paleouplift. To summarize, the mound-shoal complexes on the platform margins in the Dengying Formation in the Penglai-Zhongjiang area, Moxi North-Yanting area and Weiyuan-Ziyang area are large in scale, with estimated resources of 1.58×1012 m3, and they will be the key targets for the future exploration of the Dengying Formation in the Sichuan Basin.

Geological structure and dynamic mechanism of the Termit rift basin in West African rift system

Based on seismic and drilling data in the study area,the geological structure and kinematic process of the Termit rift basin were studied using seismic profile interpretation and balanced restoration to find out the dynamic mechanism of the basin.(1)The geological structure of the Termit Basin is represented as a narrow rift basin,with development of series of structural styles in extensional,extensional strike-slip and compressional stress setting.On plane,it is narrow in the north and wide in the south,and transitions from graben to half-graben from north to south;it features a graben controlled by the boundary faults in the north and a fault-overlapped half-graben in the south.(2)Before the Cretaceous,a series of hidden faults developed in the West African rift system,which laid the foundation for the development location and distribution direction of the Termit Basin;during the Cretaceous to Paleogene periods,the basin experienced two phases of rifting in Early Cretaceous and Paleogene,which controlled the initial structure and current structural shape of the basin respectively;during the Neogene to Quaternary,the basin was subjected to weak transformation.(3)In the Precambrian,the Pan-African movement gave rise to a narrow and long weak zone within the African plate,which provided the pre-existing structural conditions for the formation of the Termit Basin.In the Early Cretaceous,affected by the South Atlantic rifting,the Pan African weak zone was reactivated,resulting in the first stage of rifting and the basic structural framework of the Termit Basin.In the Paleogene,affected by the subduction and convergence of the Neo-Tethys Ocean,the African-Arabian plate extended in near E-W trending,and the Termit Basin experienced the second stage of rifting.The oblique extension in this period caused intense structural differentiation,and the current structural pattern of alternate uplifts and depressions took shape gradually.

The Late Neoproterozoïc Continental Tholeiitic Basalts of the Toubkal Inlier (Western High-Atlas, Morocco): A Post-Pan-African Rifting Witness in the Northern Margin of the West African Craton

The late Neoproterozo&#239c Toubkal inlier (Ancient Massif of the High-Atlas, Morocco) contains two igneous basaltic series (Tircht and Sidi Chamharouch). Investigated rocks display characteristics of within-plate continental tholeiitic and are similar to rocks originated in orogenic contexts. The geochemical results allow the assumption that subduction active processes are indirectly responsible for the genesis of theses rocks. The orogenic signature is linked probably to a Pan-African magmatic source previously metasomatized in the northern margin of the West African Craton.

中西非裂谷系富油凹陷石油地质特征与勘探方向

基于地震、钻井、烃源岩测试分析等资料,对中西非裂谷系主要盆地富油凹陷石油地质特征进行研究,并探讨未来油气勘探方向。研究表明:中非裂谷系发育下白垩统湖相优质烃源岩,西非裂谷系发育上白垩统陆源海相优质烃源岩,两类烃源岩为中西非裂谷系油气富集提供了物质基础。中西非裂谷系发育包括基岩在内的多套储集层,并存在下白垩统、上白垩统和古近系3套区域盖层。晚中生代以来,受中非剪切带右旋走滑作用等地球动力学因素的影响,中西非裂谷系不同方向的盆地在裂谷作用期次、区域盖层发育层段、圈闭类型及成藏模式等方面存在差异。其中,北东—南西向盆地主要保存了早白垩世一期裂谷层序,区域盖层位于下白垩统裂陷期地层内,形成反转背斜、花状构造及基岩潜山等圈闭类型,发育“源储一体、源内成藏”及“源上储下、源下成藏”两种成藏模式;北西—南东向盆地具有多期裂谷叠置特征,发育上白垩统和古近系区域盖层,形成披覆背斜、断背斜、反向断块等圈闭类型,以“源下储上、源上成藏”为主要成藏模式。多期叠置裂谷盆地的源内成藏组合、强反转盆地的源内岩性油藏及页岩油是中西非裂谷系盆地未来勘探的重要领域。

四川盆地德阳—安岳裂陷西侧大探1井震旦系灯影组天然气勘探重大突破及意义

近期,部署实施于四川盆地德阳—安岳裂陷西侧(以下简称裂陷西侧)的风险探井大探1井,在震旦系灯影组二段、灯影组四段(以下简称灯二段、灯四段)分别测试获天然气42×10^(4)m^(3)/d、81×10^(4)m^(3)/d,取得了裂陷西侧天然气勘探的重大战略突破。为了评价裂陷西侧灯影组沉积、储层和油气成藏地质条件,通过对野外露头、岩心、薄片及测试资料等进行分析,重新厘定了区内老井地层、沉积格局、有利区带展布特征,深化了裂陷西侧灯影组油气成藏地质认识,指导了下一步天然气勘探。研究结果表明:①裂陷西侧震旦系地层完整、序列齐全,灯影组地层广泛分布,灯四段与麦地坪组呈整合接触,桐湾Ⅱ幕位于麦地坪组顶部,因此灯影组未遭受到广泛剥蚀;②裂陷西侧灯二段、灯四段丘滩体面积分别约为3000 km^(2)、4000 km^(2),丘滩相储层特征与裂陷东侧基本一致,储集岩均以凝块白云岩和砂屑白云岩为主,差异主要体现在西侧灯影组渗透性更高,并发育大量晚期网状缝,此与该区受晚期强烈挤压密切相关;③川西南地区发育中元古界峨边群、震旦系陡山沱组、寒武系筇竹寺组3套烃源岩,受晚期构造挤压,通源断裂发育,3套烃源岩与灯影组形成下生上储、侧生旁储、上生下储高效天然气成藏组合;④大探1井所在的大兴场构造具备双层构造体系特征,保存条件好,而且关键成藏期位于古构造高部位,早期普遍成藏,晚期调整定型,具备规模成藏的含油气地质条件;⑤提出了非继承性构造演化区,在正向地质单元寻找规模化的滩带,在负向地质单元寻找烃源岩的勘探思路,并建立了“滩带—断层—烃源”跨时空配置成藏新模式。结论认为,大探1井在裂陷西侧灯影组天然气勘探取得的重大突破,进一步展示了该区巨大的天然气勘探潜力,且该区有可能成为继安岳气田之后一个重要的天然气开发主战场。

Geological Structure and Historical Development of Pre-Jurrasic Basement of West Siberia Oil- and Gas-Bearing Megabasin Karabash Zone

An additional comprehensive study of the west Siberia Karabash zone basement has been conducted. Core samples from more than 300 wells that opened the rocks of the basement were analyzed by different methods. A new map of the pre-Jurassic basement of Karabash zone of the west part of the Khanty-Mansi Autonomous Okrug (KhMAO) has been made. For the first time for the West Siberia megabasin U-Pb dating was made for samples from Shaim-Kuznetsovsk meganticlinorium and late to middle Devonian ages were obtained. The Devonian ages was obtained for metamorphic complexes of the region and, in general, for the basement of West Siberia. The complexes considered as Precambrian before that. The obtained results enable significantly to clarify more exact history of pre-Jurassic rock forming for the basement of the west part of West Siberia craton and its structure in the limits of Karabash zone. Thus, obtained data testify that in pre-Jurassic basement of the west part of the West Siberia (Karabash zone), filling grabens basalt effusion began during Permian time (probably at the end of early Permian) at sublatitudinal compression, that is, at collision, possibly immediately after or subsynchronously with the origin of the granite. On the edge of Permian and Triassic (or in early Triassic), sublatitudinal compression changed into stretching, and submeridional grabens came to existence and basalt effusion came up to the maximum.

西非裂谷系Grein坳陷构造几何学与运动学特征

西非裂谷系由一系列中—新生代裂谷盆地组成,Grein坳陷位于西非裂谷系北部,对其开展构造特征及形成演化过程研究对认识西非裂谷系形成演化具有重要意义。本文基于最新二维地震数据,对Grein坳陷开展构造几何学特征解析,在此基础上运用构造平衡恢复方法进行了构造运动学恢复,结合区域大地构造背景,对Grein坳陷的成因机制进行探讨。研究结果表明:(1)Grein坳陷整体呈缓坡断阶型半地堑结构,具有明显的“东断西超”特征。坳陷南北差异较大,北部呈断阶形态,南部为凹陷形态;(2)Grein坳陷白垩纪—第四纪构造演化包括两期裂谷作用,可划分为5个阶段,即早白垩世断陷沉积期(Ⅰ),晚白垩世稳定沉积期(Ⅱ),白垩纪末构造反转期(Ⅲ),古近纪断陷沉积期(Ⅳ)和新近纪—第四纪稳定沉积期(Ⅴ);(3)Grein坳陷白垩纪末构造反转期主要受非洲—阿拉伯板块与欧亚板块碰撞影响,板块碰撞使非洲板块内部发生了两次强烈构造事件,分别为晚白垩世圣通期(Santonian)和马斯特里赫特期(Maastrichtian),其中马斯特里赫特期(Maastrichtian)构造活动在Grein坳陷内部表现明显,该时期坳陷发生构造反转,西北部被抬升,使得上白垩统地层发生剥蚀。

西秦岭文县沟岭子沉积改造型锰矿矿床地质特征及成因研究

研究区位于摩天岭古陆北缘裂谷盆地,关家沟背斜东南翼,特殊的地质构造环境,形成了龙门山-大巴山(台缘坳陷)Fe-Cu-Pb-Zn-Mn-V-P-S-重晶石-铝土矿成矿带。矿床主要富集于关家沟古陆两侧的滨海台地稳定的碳酸盐建造中,岩石地球化学分析表明,矿床形成环境为古陆缘浅海陆棚和滨海台地区。通过地质特征综合分析,认为沟岭子沉积改造型锰矿经历了震旦纪原始沉积期—印支变质改造期—喜山次生改造期3个时期,在关家沟古陆与摩天岭古陆间受隔阻的近滨海台地环境中形成。

西秦岭北缘渐新世砾岩沉积特征及沉积环境——渐新世—中新世盆地构造环境约束

西秦岭北缘漳县—武山地区沿漳河两岸出露一套厚度近300 m的渐新统红色砾岩、砂砾岩夹粗砂岩组成的砾岩组合。这套砾岩角度不整合在古生代、中生代不同时代地层之上或以断层与前新生代地层相接触,其在孙家峡一带出露典型,层序完整,故称其为孙家峡砾岩。这套砾岩向上逐渐过渡为红色或灰色泥岩、粉砂质泥岩、钙质泥岩等湖相沉积,构成了一个下粗上细正旋回沉积组合。这套沉积组合是漳县渐新世—中新世含盐盆地最下部的一个沉积旋回,其沉积旋回、沉积环境及其沉积的构造背景研究对于漳县渐新世—中新世含盐盆地的构造属性确定和认识印度—欧亚板块碰撞汇聚动力学的远程地质响应等具有重要意义。通过对孙家峡砾岩的沉积旋回、沉积构造、砾石特征、古流向等详细研究,结合控制这套砾岩组合的边界断层多期变形资料和区域上同时代相应沉积地层的对比,取得了如下认识:(1)孙家峡砾岩沉积旋回、沉积构造和砾石分选、磨圆、排列等特征指示了其除底部为冲洪积扇和扇上河道沉积外,主体为山区辫状河道相、曲流河道相夹洪泛相沉积为主的河流加积沉积;砾石成分和古流向指示了F1断层之南的志留纪—三叠纪造山带地层虽对其物源有一定贡献,但其主要物源区更可能是来自西部祁连地块;(2)依据孙家峡砾岩及上覆湖相沉积共同构成的具有断陷盆地的正旋回沉积特征和控制盆地沉积的F1断层早期伸展正断层作用,证实这套砾岩组合为伸展断陷河谷盆地沉积,砾岩之上的湖相沉积是持续快速伸展断陷而形成的湖相沉积;(3)西秦岭北缘渐新世断陷盆地性质确认,澄清了地学界长期持有的压陷盆地或前陆挠曲盆地的模糊认识,也指示了西秦岭北缘渐新世—中新世盆地发育初期无疑是处于伸展拉张状态,这与印度—欧亚碰撞汇聚向北扩展的挤压缩短构造相悖。因此,推测渐新世印度—欧亚碰撞汇聚的动力学效应尚未波及到该区域。

西非构造演化及其对油气成藏的控制作用

西非海岸盆地群的形成和发育,与中生代以来大西洋裂开和后期的持续扩张作用有关,是冈瓦纳大陆解体和大西洋扩张形成的大陆裂谷和被动陆缘盆地。盆地的发育受西非板块构造演化的影响,经历了晚古生代—早中生代大陆克拉通阶段(前裂谷阶段)、中—晚中生代以来的裂谷阶段、过渡阶段和中生代末—第三纪的被动陆缘阶段。由于南大西洋的裂开南早北晚,受其影响,盆地的形成时间也具有南早北晚的特征。裂谷中部盆地发育良好,向南次之,北部发育较差;裂谷末期,广泛发育了一套厚层的盐岩沉积;被动陆缘发育早期继承了裂谷阶段的沉积特征,但晚期(始新世后)则与裂谷阶段相反,北部形成了巨厚的尼日利亚三角洲沉积。北部油气藏的形成明显较南部晚,加蓬盆地以南以盐下含油气系统为主,尼日利亚盆地则以盐上第三系含油气系统为主;油气藏的形成与盐岩活动形成的构造关系密切;油气分布向海方向层位逐步变新。

中西非裂谷盆地白垩系两类优质烃源岩发育模式

中西非裂谷系位于非洲中部,主要为沿中非剪切断裂带分布的被动裂谷盆地,进一步划分为中非裂谷系和西非裂谷系。针对国内外对勘探程度极低的中西非裂谷盆地白垩系优质烃源岩展布、发育机理及油气成藏模式认识薄弱的现状,笔者在开展大量中西非裂谷盆地上、下白垩统两类烃源岩样品的主微量元素等地球化学分析的基础上,从含油气盆地构造、烃源岩发育古环境、古气候、古生产力和有机质保存条件等分析出发,剖析了不同类型含油气盆地优质烃源岩发育主控因素,分别建立了中、西非裂谷系低勘探程度含油气盆地下白垩统、上白垩统优质烃源岩的发育模式:中非裂谷盆地(Bongor、Muglad、Melut盆地)下白垩统裂陷期快速沉降、温暖湿润气候条件下,勃发的水生有机质(藻类)控制的深水湖相优质烃源岩"生产力"单因素发育模式;西非裂谷盆地(Termit盆地)上白垩统拗陷期海侵、炎热潮湿气候条件下,陆源有机质输入为主,优越的保存条件(偏咸水体)优质海相烃源岩"生产力+保存条件"双因素控制的发育模式。从而进一步锁定富油气凹陷和主力成藏组合,有效指导含油气盆地内选区选带,助推油气规模储量发现。

藏南错那-沃卡裂谷的第四纪正断层作用及其特征

地表调查发现,位于西藏南部的错那-沃卡裂谷带包含了3个相对独立的地堑-半地堑——沃卡、邛多江和错那-拿日雍错地堑（从北到南）,并构成了该区重要的近SN向控震构造带。该裂谷带整体的展布方式及其中各地堑主边界断裂带的正断层活动指示了100°±2°的区域伸展方向。各边界断裂带的活动强度分析表明,断裂的平均垂直活动速率介于0.3-1.9mm/a。其中,末次盛冰以来合理的活动速率估算值为1.2-1.5mm/a,而末次间冰期以来的活动速率只有（0.6±0.3）mm/a,暗示该裂谷带的断裂活动行为可能类似于地震的丛集活动,存在间歇期与活跃期交替出现的特点。综合分析认为,中-下地壳物质的近EW向伸展或流动所导致的上地壳均匀拉张模式可能是该裂谷带的主要成因。

西非裂谷系Termit盆地古近系油气成藏主控因素分析

Termit盆地隶属于西非裂谷系,是发育于前寒武系—侏罗系基底之上的中、新生代裂谷盆地。国外石油公司自1974年开始对该盆地进行勘探,截止2008年在中国石油获得勘探许可前,仅在西部Dinga断阶带发现7个油气藏,区域甩开勘探没有获得商业发现。针对这一国外石油公司勘探近40年后放弃的区块,面临着如何寻找潜力区带、发现规模油气的巨大挑战。本文基于Termit盆地晚白垩世大规模海侵、早白垩世和古近纪两期裂谷叠置的构造演化特点,分析了古近系油气成藏的主控因素。这种后期叠置裂谷(古近纪)的成藏模式有别于其他纯陆相单一旋回的裂谷盆地,烃源岩为上白垩统海相泥页岩,储层为古近系陆相砂岩,盖层为古近系湖相泥岩,表现为跨世代(跨二级层序)油气聚集特征。其油气成藏具有6个主控因素,即大范围海相烃源岩"控源"、叠置裂谷"控砂"、断裂与砂岩输导层"控运"、构造地貌"控势"、断层与砂体配置"控藏"、盖层与侧向封挡"控保"。成藏主控因素分析揭示了Termit盆地古近系的油气富集规律,有效指导了该盆地潜力区带评价与规模油气发现。

断陷湖盆储集砂体发育的主控因素——以辽河西部凹陷古近系为例

断陷湖盆是我国东部新生代发育的主要含油气湖盆,探讨这类盆地储集砂体发育主控因素,对油气储层预测具有重要的实践意义。运用沉积—构造地质学和地球物理理论与技术,对辽河断陷西部凹陷古近系砂体发育特征进行研究,结果表明:沉积环境、古地貌、基准面和湖平面变化是断陷湖盆储集砂体发育的主要控制因素。除了沉积环境,构造运动造就的古地貌影响最大。西部凹陷古近纪古地貌包括古隆起、古沟谷、古台地、古坡折和古断槽等单元类型,它们不同程度地控制着沉积体系的展布和砂体的发育。根据构造特征,古坡折分为断阶型、陡崖型和陡坡型,它们分别对应于冲积扇-扇三角洲-远岸浊积扇沉积体系、冲积扇-近岸浊积扇沉积体系、冲积扇-扇三角洲和冲积扇-近岸浊积扇沉积体系等的发育。

西昆仑阿卡孜达坂绿片岩:受大陆地壳混染的板内玄武岩

形成于震旦-早寒武纪的西昆仑阿卡孜达坂变质火山岩是一套绿片岩相的中基性岩石,其构造性质对于西昆仑的构造演化历史具有重要的制约意义。这些变质火山岩具低到中的SiO2(42.3%-64.7%),MgO(2.69%-7.54%),宽的TiO2(0.94%-3.05%)和Fe2O3T(7.64%-18.47%)含量,显示出玄武质或安山质的母岩特征。这些岩石富含高场强元素(Nb,Ta,Zr,Hf)和稀土(∑REE=-407μg/g),并具有相对高的Ti/Y(183-673),Th/Yb(0.5-3.9)以及较低的Hf/Ta(1.6-8.6)比值。它们相对富集轻稀土(La/Yb=5.4-20),除了两个具有Nb正异常的样品外多数样品具有不同程度的负Nb异常(Nb/Nb*=-0.2)并呈现介于板内和消减带有关岩浆之间的过渡特征。这些变质火山岩所具有的消减带特征排除了其来自大洋中脊,洋岛,板内海山和大洋台地玄武岩的可能性,而岩石所具有的板内特征以及两个具Nb正异常的样品表明这些变质火山岩并非形成于破坏性的板块边缘环境(如岛弧或活动大陆边缘)。它们相对高的Gd/Yb比值(1.4-2.9)明显不同于典型的岛弧拉斑玄武岩,同时其较高的Zr/Y(3.1-12),Ta/Yb(0.27-0.73)和较低的Zr/Nb(多数小于12)显示出强烈的大陆板内特征。这些特征表明阿卡孜达坂变质火山岩的原岩是受陆壳物质混染的板内玄武岩,很可能形成于一个陆内裂谷环境。阿卡孜达坂变质火山岩与东昆仑和北祁连所发育的同时代的板内火山岩一起,可能反映了塔里木克拉通从冈瓦纳大陆的裂解事件。在上述研究的基础上,结合已有资料对震旦纪至早古生代期间的西昆仑构造演化历史进行了讨论。

碧口群火山旋回及其地质构造意义

通过详细的野外剖面观察和室内岩石地球化学研究,将碧口群火山岩划分为3个火山旋回,每个旋回下部为基性火山岩(细碧岩及细碧质凝灰岩),上部为酸性火山岩(石英角斑岩或石英角斑质凝灰岩)。基性火山岩富集LREE及LIL。第一旋回基性火山岩属碱性系列,第二、三旋回基性火山岩属拉斑玄武岩系列。基性火山岩浆形成于与洋岛玄武岩类似的地幔柱源,其中第三旋回基性火山岩浆晚期受岩石圈地幔混染;酸性火山岩为地壳重熔作用的产物。碧口群火山岩属大陆裂谷双峰式火山岩系,是中—新元古代扬子地块北缘大陆拉张作用的产物。这种拉张作用是秦岭造山带从震旦纪开始的大规模扩张作用的先兆。

西秦岭新生代双峰式火山作用及南北构造带成因初探

本文提供了西秦岭新生代流纹岩的全岩化学、稀土微量元素和Pb、Sr、Nd同位素分析数据,以及新生代双峰式火山岩27个同位素定年结果。研究表明,西秦岭新生代双峰式火山岩具有与东非裂谷完全相同的岩石组合。K/Ar和39Ar/40Ar同位素定年确定新生代双峰式火山岩的年龄从23~7·1Ma。双峰式火山岩中的钾霞橄黄长岩与钾玄岩的87Sr/86Sr在0·704031~0·70525之间,206Pb/204Pb为18·408~19·062,207Pb/204Pb为15·476~15·677,208Pb/204Pb为38·061~39·414,εNd=0·3~5·3,几乎全部为正值,与新特提斯地幔端元地球化学域非常相似,岩浆起源于与OntongJava和FOZO地幔柱相似的亏损地幔源区。由此推测,火山岩的成因与印-亚大陆碰撞诱发的软流圈地幔流向东移动和上涌有关,也是青藏高原向东扩展的一种响应。西秦岭新生代双峰式火山岩的厘定为查明南北构造带的性质提供了岩石探针,它证明南北构造带是一条大陆裂谷。但是,将西秦岭的双峰式火山岩产出的大地构造背景,深部地球物理以及地幔热结构与贝加尔裂谷和东非裂谷的地幔相比较可以看出,南北构造带的裂谷特征不同于东非大陆裂谷,也与贝加尔裂谷不尽相同。南北构造带的裂谷成因与印-亚大陆碰撞诱发的软流圈物质向东的移动和上涌有关,其特征受西秦岭周边各个小块体间相对运动速度与方向以及东昆仑断裂-西秦岭北缘断裂运动性质的联合制约。由此推测,南北构造带是一条复杂的裂谷带,也可能是一个发展中的板块边界。

尼日尔Termit盆地及其周缘晚白垩世古地理演化

Termit盆地及其周缘是中西非裂谷中典型的中、新生代裂谷盆地,也是中石油海外最具潜力的风险勘探区,但由于多期构造运动的复杂性,研究区晚白垩世的古地理演化缺乏系统的分析研究。本文将Termit盆地及其周缘作为研究区域,在构造演化的基础上利用地球化学、地层学及地球物理等手段进一步分析了研究区的古沉积环境、古气候及古物源,最终明确了晚白垩世的古沉积演化。研究认为,晚白垩世早期的森诺曼阶(Cenomanian)研究区开始发生海侵,三冬阶(Santonian)时期达到最大海侵范围,之后开始逐渐海退的过程。马斯特里赫特阶(Maastrichtian)时期的区域构造挤压事件使盆地形态发生改变,该构造事件最终以区域不整合结束。地球化学资料、岩性资料以及地震资料综合表明,森诺曼阶(Cenomanian)—三冬阶(Santonian)时期研究区处于偏还原的浅海陆架沉积,属典型的热带气候,接受来自北东向的物源供给;至坎潘阶(Campanian)—马斯特里赫特阶(Maastrichtian)时期,伴随着海平面的下降,研究区由海相沉积逐渐转变为海陆过渡相沉积,且物源主要来自于北东及南西两个方向。本次研究明确了Termit盆地及其周缘在晚白垩世的古沉积演化过程,这为进一步明确研究区的沉积体系及砂体的预测提供了理论依据。