下扬子南黄海沉积盆地构造地质特征

南黄海盆地作为下扬子块体之上的大型叠合盆地,海相构造层保存完整,陆相断拗构造层也较为发育,盆地地质结构复杂,构造变形强烈,利用最新的地质地球物理资料和解释成果,对低勘探程度的南黄海盆地进行了研究,认为盆地演化大致经历了克拉通被动陆缘初始发育阶段—南缘前陆北缘被动陆缘过渡阶段—南北对冲前陆定型阶段—滨太平洋弧后陆内调整四个阶段。南黄海盆地属于台地—断拗复合地质结构,中、新生代为具有盆内隆起带的断陷箕状结构,且中、新生代多期构造运动在盆地原型改造和后期沉积发育上起着至关重要的作用,尤其印支—燕山早期运动、燕山中期黄桥运动和喜马拉雅期盐城运动与盆地地层变形、沉积发育、断裂发育及构造样式等盆地要素演化密切相关,进而导致盆地垂向地质结构和构造变形的层次性极为显著,而中生代燕山期和新生代喜马拉雅期两期构造岩浆活动则与滨太平洋域的动力学背景相关。     

南黄海中部隆起印支面剥蚀量恢复与演化过程——来自CSDP-2井的证据

南黄海中部隆起是下扬子地块向海域的延伸,是当前海相盆地海域资源调查的潜力区。中部隆起自印支期以来经历多期构造隆升、挤压及剥蚀作用,显著影响了盆地油气资源的形成和分布。2016年底完钻的大陆架科学钻探CSDP-2井首次在中部隆起钻穿印支不整合面,该不整合面在中部隆起既是新近系-第四系底界,又是下三叠统灰岩的顶界,横向延伸平缓,上、下地层产状差异巨大,下伏地层具有强烈的挤压变形及逆冲推覆,呈现显著的角度不整合接触关系。本次研究基于泥岩声波时差法计算的印支面地层剥蚀量约为1200 m,镜质体反射率法计算的剥蚀量约为1400 m,与地层趋势面估算的剥蚀量基本一致。结合南黄海盆地演化过程分析,认为中部隆起大致于晚三叠世开始隆升,至晚白垩世期间经历快速剥蚀,并可能延续到渐新世末期。在当前南黄海盆地资源调查逐步转向中、古生界海相残留盆地之际,依托实际钻探资料进行印支不整合面研究及剥蚀量恢复对于恢复盆地构造-热演化史及评价油气资源等均具有重要的现实意义。     

下扬子独立地块与中生代改造型残留盆地

下扬子地块在古纬度、火山岩和花岗岩时空发育、区域成矿专属性、沉积建造和构造变形等方面具独特性,与扬子地块有显著差异,是一个晚古生代——中生代早期的独立地块。受燕山期苏鲁板间造山作用影响,下扬子地块直至燕山中期才“楔入”在印支期已拼合的扬子与华北地块,从而演化成独特的下扬子改造型残留叠合盆地。这种改造型叠合盆地的基本特点是:晚印支-早燕山同造山期前陆盆地沉积层和上叠的中燕山期陆相沉积层遭受大量剥蚀,并与古生-中生界海相沉积层一起被卷入强烈的多期次的燕山造山运动,晚白垩世——古近纪又强烈反转成为断陷盆地,形成鲜明的上部地壳的双层结构。这是造成下扬子地区海相古生-中生界油气地质勘探高复杂性、高难度性和高风险性的根本原因,也造就了下扬子区海相烃源岩的二次生烃和晚期成藏的优势。     

南黄海海域中生代前陆盆地形成的构造背景

南黄海盆地占据了下扬子板块的主体,自元古宙以来经历了多期构造运动,受到华北板块、扬子板块、华南板块、太平洋板块多个板块相互作用的影响,形成多期盆地演化阶段的叠合盆地。分析了南黄海盆地前人钻井资料及最新二维地震资料,并与下扬子苏北盆地地层及构造特征进行对比,认为整个下扬子区域受华北—扬子板块碰撞的影响,经历了中生代前陆盆地演化阶段。下扬子陆域部分地区发育相对完整的中生代沉积,记录了华北—扬子板块之间洋壳消减、陆陆碰撞、前陆盆地发育及碰撞后活动。而在下扬子对应海域延伸部分的南黄海盆地中,仅在盆地北部烟台坳陷东北缘通过钻井证实有侏罗纪前陆盆地地层,钻遇地层仅发育侏罗系上部陆相沉积,在地震剖面中可以解释出侏罗系下部海陆交互相地层,向上转变为陆相沉积地层。对比下扬子陆域与海域地层发育情况,华北—扬子板块碰撞造山过程对于下扬子整个区域的影响因地而异,在三叠纪末期—侏罗纪时期南黄海盆地内沉积缺失,南黄海海域区处于广泛抬升状态,印支运动期间地层挤压活动强烈,烟台坳陷内海相地层中逆冲断层广泛发育。在南黄海盆地东北缘,前陆盆地侏罗系地层发育于南倾边界断层的上盘,认为南黄海盆地侏罗纪前陆盆发育的构造背景受到同期北侧千里岩超高压变质带从深部折返影响,随着千里岩隆起带的快速抬升,为南黄海盆地北缘提供了沉积空间及物源,沉积了大套的侏罗系前陆盆地地层。     

东部海域地学大断面地质结构特征及其对综合地层分区的约束

本文利用实测的地质地球物理资料,在中国东部海域开展了地学大断面重磁震联合反演,系统研究了各构造单元的基底性质和地层结构,并以此为约束开展了海陆综合地层分区。研究认为,东海陆架盆地基底为元古宇和古生界,盖层发育5套构造层;南黄海盆地具有双重基底,盖层可以划分为8个构造层。东海陆架盆地以晚中生代燕山期以来的变形为主;南黄海盆地海相下构造层主要表现为挤压变形,陆相中构造层主要发育拉张作用形成各种构造样式。区内莫霍面深度稳定,一般在30 km左右,仅在勿南沙—中部隆起处上地幔略有抬高,总体上南部东海陆架盆地区莫霍面埋深要大于北部南黄海盆地—苏鲁造山带。将中国东部海域划分为2个地层大区,6个地层区和14个地层分区。大断面地层结构研究揭示,在南黄海海域和东海海域广泛发育中、古生代地层,巨厚的中—古生界为油气资源的形成与赋存提供了丰富的物质基础。     

对南黄海盆地构造层特征及含油气性的新认识

南黄海是由古、中、新生界叠置而成的一个大型叠合盆地,发育4个特征各异的构造层:构造层Ⅰ(Z-S)、构造层Ⅱ(D-T)、构造层Ⅲ(T3-E)和构造层Ⅳ(N-Q)。构造层Ⅰ在海区广泛分布,主要为一套下古生界的盆地相-台地相沉积建造,最新地震资料推测,其厚度大且稳定,但构造特征不清楚。构造层Ⅱ由上古生界至中生界三叠系组成,是以碎屑岩和灰岩为主的一套海相地层,主要受到印支运动和早燕山运动的强烈影响,南、北部残留地层及结构不同,但以挤压构造样式为主。与陆区比较,南黄海盆地海相构造层Ⅰ和构造层Ⅱ的构造格局相对稳定,变形强度较弱。构造层Ⅲ发育白垩系和古近系,局部存在上三叠统—侏罗系,白垩系和古近系主要赋存在坳陷或凹陷内,隆起或凸起基本缺失,为一套陆相砂泥岩沉积,在北部坳陷分布较广,但厚度变化快,剖面上表现为地堑、半地堑的结构特征,以拉张构造样式为主。构造层Ⅳ(N-Q)为区域沉降的产物。南黄海盆地在形成过程中经历了多次构造运动的改造,不同构造单元具有不同的油气成藏特征和富集规律,北部坳陷发育有古生古储、古生新储、新生古储等油气成藏组合类型,是油气勘探最有利的区域。     

下扬子地区古生代盆地的改造变形

包括苏北-南黄海地区在内的下扬子区海相古生界盆地,在中三叠世末以来的构造演化过程中,经历了3期不同性质构造作用的改造变形。(1)在中三叠世末-早、中侏罗世的印支运动期,发生了江南-雪峰基底拆离体由南东向北西方向(同时派生由南向北,由东向西方向)的逆冲推覆,以及后缘弹性松弛断陷构造作用的改造,使海相古生界盆地发生了第Ⅰ期的由强及弱、递进衰减的逆冲 褶皱变形。(2)在晚侏罗-早白垩世的燕山运动期,叠加了第Ⅱ期以郯庐断裂带为代表的NNE向大陆平移走滑构造的左行简单剪切,以及拉分断陷构造作用的改造变形。(3)在晚白垩世-古近纪的喜马拉雅运动期,下扬子区在由南向北的伸展拆离与多米诺式拉张断陷构造作用下,受到了第Ⅲ期的变形改造。这3期构造变形作用促使扬子板块海相油气的早期聚集、晚期热演化和再分配。文中将重点讨论下扬子区板内海相古生界盆地自中三叠世末以来所经历的3期不同性质构造作用的改造变形。     

庞西垌‐金山银金矿田构造演化及控矿特征分析

<正>庞西垌-金山银金矿田位于钦杭带南段云开地块内(周永章,2012)。云开地块一般被认为是扬子和华夏地块的结合带(覃小锋等,2008),东西两侧分别以吴川-四会断裂、博白-岑溪断裂为界,呈北东向展布,自元古代起经历了多期的构造、岩浆作用。区内出露的地层主要有新元古代云开群变质岩、加里东期混合岩及下古生界地层,岩浆活动频繁,以燕山期花岗岩浆为主。庞西垌-金山银金矿田地处粤东桂西交界,包括了庞西垌、金山、中苏、竹根坡、高村等银金矿床及一     

南黄海盆地海相领域油气勘探战略思考

随着南黄海海域新一轮油气资源调查的展开,勘探深层海相油气成为必然趋势。借鉴下扬子地台海相油气勘探学术研究基础,概述了南黄海盆地由古生界组成、经历中生代构造运动形成的“古构造”,以及与古构造相关的非均质性碳酸盐岩裂隙(裂缝)储集系统,认为它们与下扬子区中、古生界海相地层的沉积序列、烃源岩及油气成藏规律具有可比性,因而具备形成油气田(藏)的地质条件。尤其是南黄海盆地南部的勿南沙隆起区,作为一个相对稳定的古构造单元,是寻找古生古储或古生新储油气藏有利地区,可作为近中期勘探战略优选靶区。     

苏北盆地中—古生界海相烃源岩发育规律及其意义

苏北盆地与南黄海盆地属于同一构造单元,苏北盆地的烃源岩发育规律的研究对南黄海油气勘探具有重要启示意义。在野外地质研究和69个烃源岩实测数据的基础上,结合已有分析化验数据及油气勘探资料,对苏北盆地的中—古生界海相烃源岩厚度分布和地球化学特征进行了分析,结果表明烃源岩整体沿北东向展布,在中—古生界均存在多个烃源岩发育中心,并明显有向南黄海海域延伸的趋势;下古生界普遍比上古生界的热演化程度高,并具有区域不均一性,二叠系的热演化程度相对较低,存在二次生烃的潜力。苏北盆地在中—古生界海相地层烃源岩特征的研究,进一步揭示了南黄海盆地具有良好的油气勘探潜力。     

Structural characteristics and evolution of the South Yellow Sea Basin since Indosinian

Based on the seismic data gathered in past years and the correlation between the sea and land areas of the Lower Yangtze Platform, the structural characteristics of the South Yellow Sea Basin since the Indosinian tectonic movement is studied in this paper. Three stages of structural deformation can be distinguished in the South Yellow Sea Basin since the Indosinian. The first stage, Late Indosinian to Early Yanshanian, was dominated by foreland deformation including both the uplifting and subsidence stages under an intensively compressional environment. The second stage, which is called the Huangqiao Event in the middle Yanshanian, was a change for stress fields from compression to extension. While in the third stage (the Sanduo Event) in the Late Himalayan, the basin developed a depression in the Neogene-Quaternary after rifting in the Late Cretaceous-Paleogene. The long-time evolution controlled 3 basin formation stages from a foreland basin, then a fault basin to a final depression basin. In conclusion, since the Indosinian, the South Yellow Sea Basin has experienced compressional fold and thrust, collisional orogen, compressional and tensional pulsation, strike-slip, extensional fault block and inversion structures, compression and convergence. The NE, NEE, nearly EW and NW trending structures developed in the basin. From west to east, the structural trend changed from NEE to near EW to NW. While from north to south, they changed from NEE to near EW with a strong-weak-strong zoning sequence. Vertically, the marine and terrestrial facies basins show a “seesaw” pattern with fold and thrust in the early stages, which is strong in the north and weak in the south and an extensional fault in later stages, which is strong in the north and weak in the south. In the marine facies basin, thrust deformation is more prevailing in the upper structural layer than that in the lower layer. The tectonic mechanism in the South Yellow Sea Basin is mainly affected by the collision between the Yangtze and North China Block, while the stress environment of large-scale strike-slip faults was owing to subduction of the Paleo-Pacific plate. The southern part of the Laoshan uplift is a weak deformation zone as well as a stress release zone, and the Meso-Paleozoic had been weakly reformed in later stages. The southern part of the Laoshan uplift is believed, therefore, to be a promising area for oil and gas exploration.     

Prospective prediction and exploration situation of marine Mesozoic-Paleozoic oil and gas in the South Yellow Sea

The South Yellow Sea Basin is a large sedimentary basin superimposed by the Mesozoic-Paleozoic marine sedimentary basin and the Mesozoic-Cenozoic terrestrial sedimentary basin, where no oil and gas fields have been discovered after exploration for 58 years. After the failure of oil and gas exploration in terrestrial basins, the exploration target of the South Yellow Sea Basin turned to the marine Mesozoic-Paleozoic strata. After more than ten years’ investigation and research, a lot of achievements have been obtained. The latest exploration obtained effective seismic reflection data of deep marine facies by the application of seismic exploration technology characterized by high coverage, abundant low-frequency components and strong energy source for the deep South Yellow Sea Basin. In addition, some wells drilled the Middle-Upper Paleozoic strata, with obvious oil and gas shows discovered in some horizons. The recent petroleum geological research on the South Yellow Sea Basin shows that the structure zoning of the marine residual basin has been redetermined, the basin structure has been defined, and 3 seismic reflection marker layers are traceable and correlatable in the residual thick Middle-Paleozoic strata below the continental Meso-Cenozoic strata in the South Yellow Sea Basin. Based on these, the seismic sequence of the marine sedimentary strata was established. According to the avaliable oil and gas exploration and research, the marine Mesozoic-Paleozoic oil and gas prospects of the South Yellow Sea were predicted as follows. (1) The South Yellow Sea Basin has the same sedimentary formation and evolution history during the sedimentary period of the Middle-Paleozoic marine basin with the Sichuan Basin. (2) There are 3 regional high-quality source rocks. (3) The carbonate and clastic reservoirs are developed in the Mesozoic-Paleozoic strata. (4) The three source-reservoir-cap assemblages are relatively intact. (5) The Laoshan Uplift is a prospect area for the Lower Paleozoic oil and gas, and the Wunansha Uplift is one for the marine Upper Paleozoic oil and gas. (6) The Gaoshi stable zone in the Laoshan Uplift is a favorable zone. (7) The marine Mesozoic-Paleozoic strata in the South Yellow Sea Basin has the geological conditions required to form large oil and gas fields, with remarkable oil and gas resources prospect. An urgent problem to be addressed now within the South Yellow Sea Basin is to drill parametric wells for the Lower Paleozoic strata as the target, to establish the complete stratigraphic sequence since the Paleozoic period, to obtain resource evaluation parameters, and to realize the strategic discovery and achieve breakthrough in oil and gas exploration understanding.©2019 China Geology Editorial Office.     

Onshore–offshore structure and hydrocarbon potential of the South Yellow Sea

Recent high-resolution airborne gravity data taken over the South Yellow Sea and its western onshore–offshore transition zone, combined with ground gravity data taken over the onshore area (Subei Basin), China, show that the South Basin of the South Yellow Sea and the Subei Basin correspond to the same gravity low anomaly. Magnetic data also support our interpretations. Both areas have similar strata, structures and hydrocarbon potential, and form a large Cenozoic terrestrial sedimentary basin controlled by the Tanlu Fault. Cenozoic terrestrial strata are well developed in the South Basin of the South Yellow Sea, and thick Meso–Paleozoic marine strata are preserved in the Central uplift area. Future hydrocarbon exploration in the South Yellow Sea should focus on the Cenozoic continental sequence, especially the Paleogene in the South Basin, as well as the Meso–Paleozoic marine rocks in the Central uplift area. The western part of the middle depression and middle and western parts of the north depression in the South Basin of the South Yellow Sea have the greatest potential for hydrocarbon accumulation.     

南黄海盆地中部隆起构造特征及其成因机制

通过选取南黄海盆地中部隆起内部地震反射清晰、构造特征明显的典型地震剖面,开展精细的构造解释,系统梳理了南黄海盆地中部隆起的构造样式特征,识别出挤压（滑脱、高角度逆冲、对冲/背冲）、走滑（正花状、y字型）、伸展（铲式正断层）等多种构造组合样式.首次提出在中部隆起内部发育2条NW-SE向走滑断层.在此基础上,结合区域应力场特征和深部地球动力学背景,明确了中部隆起构造样式的发育期次、成因机制和构造演化历程.研究结果表明:（1）滑脱构造主要位于中部隆起北部,滑脱面位于志留系底部的泥页岩.滑脱构造应力机制来源于三叠纪末印支运动时期华北板块与下扬子板块之间的碰撞造山作用;（2）高角度逆冲主要位于中部隆起南部,其应力机制来源于早侏罗世燕山运动早期,古太平洋板块初始高速、低角度NW向俯冲;（3）走滑断层主要表现为具有压扭特征的正花状构造,位于中部隆起东南部、中西部,对应于早白垩世时期,古太平洋板块低角度俯冲由NW向转变为NNW向引起的左旋剪切作用,中国东部郯庐断裂在该时期亦表现为左旋剪切特征;（4）伸展正断表现为铲式正断层特征,发育在中部隆起南北边界,即在中部隆起与南黄海盆地南部坳陷、北部坳陷的接触部位,对应于晚白垩世燕山运动晚期,古太平洋板块由低角度俯冲转为高角度俯冲,此时中国东部构造应力体制经历着由挤压向拉张的转换.      

Characteristics of marine strata distribution in South Yellow Sea based on airborne gravity and magnetic data

Based on the high accuracy airborne gravity and magnetic data of South Yellow Sea, combined with the characteristics of gravitational and magnetic field and geophysical properties, the authors analyzed the matched filtering through radially averaged logarithmic power spectrum to separate and extract the gravity and magnetic anomaly caused by the interfacial fluctuation of marine strata. And the depth of the marine strata interface of South Yellow Sea was interpreted by the tangent and Vaquier methods. The authors also compiled the depth of the bottom and top interface of the marine strata after geological and geophysical interpretations. In addition, a preliminary division of South Yellow Sea marine strata tectonic units was carried out and the strata distribution was also discussed. The central depression and southern depression of Subei- South Yellow Sea depression area were developed on the strongly magnetic basement, with weak tectonic deformation. The marine strata remain intact with a shallow depth of 4 km to 8 km. South Yellow Sea is the oil and gas exploration area with great resource potential.     

基于航空重、磁数据的南黄海海相地层分布特征识别

基于南黄海海域实测高精度航空重、磁数据,结合航空重、磁场及物性特征,通过平均对数功率谱分析匹配滤波方法技术,对南黄海海相地层界面起伏引起的重、磁异常特征进行分离、提取,采用切线法和外奎尔法计算海相地层界面的深度,经地质和地球物理综合解释,编制了南黄海海相地层底界面、顶界面深度图及海相地层厚度图。在此基础上,初步划分了南黄海海相地层构造单元,探讨了南黄海海相地层的分布特征。苏北—南黄海坳陷区的中部坳陷和南部坳陷均发育在强磁性基底之上,构造变形较弱,海相地层保存完整,埋藏浅,厚度为4~8 km,是南黄海地区具有较大资源潜力的油气勘探区。     

下扬子区新生代伸展构造变形及其区域构造意义

下扬子区是中国东部重要的含油气盆地区之一,其新生代伸展构造变形一直是下扬子新生代构造动力学的核心问题.通过对下扬子海陆全区新生代断陷盆地结构与构造格局分析,明确了下扬子区伸展构造变形特征,探讨了变形成因机制及其区域构造意义.区域构造分析表明,下扬子区伸展变形构造由一系列NNE-NE-NEE走向的总体呈弧形展布的正断层构成,表现为受伸展断裂系统控制的断陷结构,具有多向伸展特征,自南向北可分为江南、沿江-苏北-南黄海和南黄海北部3个构造伸展区.有限元数值与构造物理模拟表明,受控于太平洋板块俯冲推挤传递至陆内的侧向构造作用力,下扬子块体南向蠕移,区域上近南北向伸展变形,郯庐断裂右旋走滑,两者共同构成一个"右旋侧向扩展变形"系统.在区域构造上,大兴安岭-太行山-武陵山重力梯度带以东的中国东部新生代伸展变形构造和盆地成因与古太平洋板缘边界条件密切相关.      

南黄海盆地中部隆起CSDP-2井志留系-石炭系岩石学特征及其沉积相

目前,大陆架科学钻探CSDP-2井是南黄海盆地中部隆起上的唯一深钻,是揭示南黄海中-古生界海相地层时代,恢复其沉积环境和构造运动的基准井。本文针对该井开展岩心描述并进行薄片观察,结合测井数据、古生物化石等资料,将志留系-石炭系划分为下志留统高家边组、侯家塘组、坟头组,上泥盆统五通组,下石炭统高骊山组、和州组,上石炭统黄龙组、船山组。其中,志留系沉积了一套浅海陆棚相的细碎屑岩,沉积物以浅海-滨海相砂泥岩为主;泥盆系五通组同样为碎屑岩沉积,稳定的石英砂岩和紫红色泥岩并存,下部为潮坪相,上部则为三角洲相;而石炭系发育台坪、泻湖、颗粒滩等碳酸盐岩台地亚相,岩性以生屑灰岩和泥晶灰岩为主。区域地层对比表明,南黄海盆地中-古生界海相地层是下扬子区由陆域向海域的延伸,其志留系-石炭系岩性序列与下扬子陆域基本一致。     

南黄海海域生储盖层特征及油气远景评价

根据近年来新取得的资料,结合前人的研究成果,对南黄海海域的生储盖层特征进行了综合研究。古生界、中生界海相地层为南黄海海域的主力烃源岩,从构造运动和沉积发育情况分析,将南黄海海域的古生界、中生界海相地层生成油气的成藏过程划分为三叠纪印支运动前、侏罗纪—白垩纪、古近纪和新近纪4个阶段。通过对生储盖层的特征分析,说明南黄海古生界、中生界海相地层油气资源具有开发前景。在对南黄海盆地海相中生界、古生界烃源条件和后期保存条件研究的基础上,预测了盆地内海相油气资源的有利运聚区,为南黄海海域的油气勘探及研究工作提供了依据,对我国新的海上油气开发及部署作出了贡献。     

南黄海北部航空重力场特征及主要地质认识

南黄海北部重力场信息丰富、梯级带发育、异常特征明显,充分反映了该区隆坳构造格局、断裂展布等地质特征。综合研究认为: NE向断裂构成了南黄海北部主体构造格架,嘉山-响水断裂、南黄海北缘断裂共同构成了苏鲁造山带南部边界; 依据航空重磁资料新发现的NW向宫家岛深大断裂对南黄海北部基底构成、岩浆岩分布具有重要的控制作用; 通过重磁联合反演,发现在南黄海北部坳陷的东北凹陷存在着前寒武系稳定的结晶基底; 航空重力资料表明,胶莱盆地向东延伸进入南黄海,在海域内其最大沉积厚度可达3 km。上述地质认识和发现为南黄海北部海洋区域地质调查、油气资源调查及重大基础地质问题的解决提供了借鉴。