四川盆地下侏罗统陆相页岩气源储特征及耦合评价

四川盆地陆相页岩气勘探前景良好,目前已在川东北地区下侏罗统获得良好页岩气显示和工业气流.与海相页岩相比,陆相页岩具有相变快、岩相组合类型多(夹层发育)、有机质丰度低和源储配置关系复杂等特点.运用"源储耦合"研究思路,利用宏观-微观结合的储层表征技术对下侏罗统自流井组大安寨段页岩的烃源特征、储集特征及其耦合关系开展了分析...     

断陷湖盆浅水三角洲沉积特征:以Muglad盆地Unity凹陷Aradeiba组为例

浅水三角洲是沉积学和油气勘探开发领域的热点,目前研究主要集中在大型坳陷型盆地内,部分学者研究证明在断陷湖盆萎缩期或裂陷初期也存在浅水三角洲沉积,但研究较为薄弱.本文利用岩心、测井、地震以及分析化验资料,对Muglad盆地研究区内Aradeiba组浅水三角洲的沉积有利条件、沉积特征以及垂向演化特征进行了深入剖析,结合湖平...     

湖南及邻区志留纪兰多弗里世鲁丹期至埃隆期岩相古地理及加里东期板块构造演化

湖南兰多弗里世鲁丹期岩相古地理格局以桃江—白马山—苗儿山一线为界,其南东为华夏洋壳板块兰多弗里统鲁丹阶周家溪组陆屑浊积深水盆地相,陆屑来自更南东的湘中南褶皱山地;其北西为扬子陆壳板块兰多弗里统鲁丹阶龙马溪组沉积洋盆,南东后缘是上陆棚相,北西前缘是下陆棚相,陆屑都由南东湘中南褶皱山地提供。至兰多弗里世埃隆期岩相古地理发生巨变：龙马溪组顶部Coronograptus cyphus笔石带末即大约440.8±1.2 Ma时,发生华夏洋壳板块向扬子陆壳板块俯冲碰撞事件,华夏洋壳板块周家溪组本身褶皱造山为华夏褶皱山地,华夏洋壳板块洋盆关闭。同时华夏洋壳板块以A型俯冲形式下插到扬子陆壳板块之下,并使扬子陆壳板块南东前缘崛起形成加里东期雪峰造山带。后者将扬子陆壳板块南东前缘牵引、挠曲和凹陷成华夏洋壳板块弧后前陆盆地,小河坝组是该弧后前陆盆地的沉积盖层,陆屑都由南东的雪峰造山带提供。该弧后前陆盆地沉积了三角洲相—滨海相的小河坝组,向北东、北西和南西方向相变为台地相石牛栏组,再向北西陕南紫阳相变为盆地相斑鸠关组。小河坝组两次采集的重砂样均出现蓝闪石,它是蓝闪石片岩标志矿物,蓝闪石片岩是确认加里东期华夏洋壳板块与扬子陆壳板块俯冲碰撞及形成雪峰造山带的判别标志。     

澳大利亚布朗斯(Browns)Co-Cu-Ni多金属矿床地球化学特征及与中国南方黑色岩系金属矿床对比

黑色岩系中金属元素地球化学特征一直是矿床地质研究的重点.澳大利亚布朗斯Co-Cu-Ni多金属矿产于古元古代黑色岩系中,属典型的层控矿床;该矿床中主要成矿元素为Co、Cu、Ni和Pb,矿化分带不明显,蚀变微弱.δ34S均值范围为-5.21‰～14.78‰,估计生物成因的硫占一定比例,后期有细菌还原硫酸盐成因的高硫同位素组...     

华南燕山晚期构造-岩浆事件与成矿作用——来自广西大瑶山龙头山金矿床的地球化学约束

广西贵港大瑶山成矿带位于华南东南沿海成矿带西南端,对矿带内龙头山金矿黄铁矿化斑岩进行定年的结果为96.1±3.0 Ma,与区域内邻近的平天山侵入岩体(96.2±0.4 Ma)相同.龙头山矿床的Sr同位素组成与其锆石的REE特征表明,成矿作用伴随有大量的流体参与;矿化斑岩与区内侵入相岩石相同的形成时代以及矿化斑岩中锆石C...     

古沙漠记录的沉积体系及层序地层研究进展——以鄂尔多斯盆地白垩系为例

鄂尔多斯盆地白垩纪古沙漠沉积地层主要为冲积扇、湖泊、河流、三角洲及沙漠沉积体系.风成沉积和沙漠沉积、风成沉积体系和沙漠沉积体系等概念有必要予以区分.基准面变化是沙漠和河流、湖泊等其他陆相地层对比的基础.鄂尔多斯盆地志丹群划分为上下两个三级层序单元,反映了两期古沙漠由风成沉积强盛期到衰退期的演化,且每个层序可划分为低位、...     

鄂尔多斯盆地东北部构造热演化史的磷灰石裂变径迹分析

运用磷灰石裂变径迹(AFT)分析的构造热年代学研究方法,系统探讨鄂尔多斯盆地东北部不同区段中新生代以来的热演化历史,为盆地东北部石油和天然气等多种沉积能源矿产的勘探预测提供新的约束条件。模拟结果表明:盆地东北部经历了250~150 Ma缓慢埋藏增温过程,平均增温速率为0.9℃/Ma;150~120 Ma为快速增温阶段,平均增温速率高达2.1℃/Ma,地层温度达到最高,且均大于130℃。之后不同区段经历差异降温过程:北缘露头区经历了120~65 Ma快速降温,平均冷却速率约1.3℃/Ma;65~10 Ma缓慢降温,平均冷却速率约为0.4℃/Ma。南缘露头区及盆地沉降区则经历了120~30 Ma缓慢降温,平均冷却速率约为0.9℃/Ma;30~10 Ma快速降温,平均冷却速率约为1.5℃/Ma。10 Ma以来,盆地东北部整体抬升冷却,平均冷却速率约6.5℃/Ma。分析结果认为燕山中期构造热事件之最高热增温作用的关键时刻为(120±10)Ma,促成鄂尔多斯盆地东北部主要烃源岩层系的成熟生烃和大规模油气成藏。在后期的差异抬升冷却过程中,北缘露头区在65 Ma±通过了110℃等温面,南缘露头区及盆地的沉降区在30 Ma±通过了110℃等温面,有利于相邻地区原生油气藏的积聚和保存,古近纪晚期(30 Ma)尤其是新近纪晚期近10 Ma以来的强烈构造抬升作用有可能是引发原生油气藏调整—改造和次生成藏的关键因素。     

华南沉积岩系Hg、Sb丰度

从区域构造地球化学演化的角度来看,华南Hg、Sb矿床的形成主要可划分为三个阶段:(1)沉积层(主要是元古宙基底沉积层)堆积过程中Hg、Sb的储集;(2)元古宙基底(沉积层)的下沉-熔融-花岗岩形成与Hg、Sb释放;(3)在有利构造的引控下,含Hg、Sb流体形成、演化与成矿,简称为储存-释放-富集宏观三阶段。本文重点阐述的是第一阶段,华南沉积层特别是元古宙基底沉积层的Hg、Sb丰度。文中将华南沉积层Hg、Sb丰度分为四种类型:Ⅰ原生本底丰度;Ⅱ同生异常丰度;Ⅲ后生丰度;Ⅳ混合丰度。本文计算、统计出华南沉积岩系本底丰度Hg为0.368μg/g,Sb为1.28μg/g。华南元古宙基底沉积岩系本底丰度Hg为0.363μg/g,Sb为1.45μg/g都明显高于地壳及花岗岩Hg、Sb丰度值。     

辽河盆地东部凸起区二叠系层速度-砂地比定量解释

辽河盆地东部凸起勘探程度较低,钻井资料较缺乏,但地震资料相对较丰富。为了能在有限的资料中发掘更多能反映二叠系砂岩分布情况的信息,借助于地震处理中的速度分析资料,利用层速度-砂地比定量解释模型得到二叠系砂地比分布图,并在此基础上对二叠系的有利勘探区带进行了预测。     

U-Pb Zircon and Re-Os Molybdenite Geochronology of theW-Mo Mineralized Region of South Qinling,China, andtheir Tectonic Implications

A W-Mo mineralized region is located along the northern margin of the South Qinling tectonic belt of China. WMo mineralization occurs mainly in Cambrian–Ordovician clastic and carbonate rocks, and the ore bodies are structurally controlled by NW–SE-and NNE–SSW-striking faults. Evidence for magmatism in the area is widespread and is dominated by intermediate–felsic intrusives or apophyses, such as the Dongjiangkou, Yanzhiba, Lanbandeng, and Sihaiping granitic bodies. Quartz-vein-type mineralization and fault-controlled skarn-type mineralization dominate the ore systems, with additional enrichment in residual deposits. At present, there are few or insufficient studies on(1) the age of mineralization,(2) the relationship between intermediate–felsic granite and W-Mo mineralization,(3) the source of ore-forming materials,and(4) the metallogenic and tectonic setting of the mineralized area. In this paper, we present geochronology results for numerous intrusive granitic bodies in the South Qinling tectonic belt. U-Pb zircon geochronology of the Lanbandeng monzogranite and Wangjiaping biotite monzogranite yields ages of 222.7 ± 2.3 and 201.9 ± 1.8 Ma, respectively. In contrast to the Late Triassic age of the Lanbandeng monzogranite, the age of the newly discovered Wangjiaping biotite monzogranite places it at the Triassic–Jurassic boundary. Re-Os molybdenite geochronology on the Qipangou W-Mo deposit yielded a model age of 199.7 ± 3.9 Ma, indicating the deposit formed in the early Yanshanian period of the Early Jurassic. Granitoid intrusions in the mineralized area are characterized by composite granite bodies that crystallized at ca.240–190 Ma. While there were multiple stages of intrusion, most occurred at 210–220 Ma, with waning magmatic activity at 200–190 Ma. The Re-Os age of molybdenite in the region is ca. 200–190 Ma, which may represent a newly discovered period of W-Mo metallogenesis that occurred during the final stages of magmatism. The heat associated with this magmatism drove ore formation and might have provided additional ore-forming components for metallogenesis(represented by the Wangjiaping biotite monzogranite). Ore materials in the mineralized area were derived from mixed crustal and mantle sources. Enrichment of the region occurred during intracontinental orogenesis in the late Indosinian–Yanshanian, subsequent to the main Indosinian collision. At this time, the tectonic environment was dominated by extension and strike-slip motion.