南海新生代沉积基底性质和盆地类型

根据新的重磁、地震及钻井资料,结合大地构造性质和新生代主要构造变形特征,将南海新生代沉积盆地基底划分为三个基底区,即北部古生界断陷基底区、西部中—古生界走滑拉分基底区以及南部复杂基底区。北部基底区以古生界变质基底为主,同时含有中生界残留断陷,它由北部湾断陷基底区、珠江口中—古生界断陷基底区以及西沙古生界断陷基底区三个次级区构成;西部基底区以走滑伸展为特征,分为莺歌海古生界、中建南中生界以及万安中生界等三个次级走滑拉分基底区;南部基底区较复杂,划分为曾母新生代早期褶皱基底区和南沙中—古生界复杂基底区。这八个次级基底区之间主要以俯冲—碰撞缝合带、蛇绿岩带、深海放射虫沉积岩带、洋中脊火成岩带以及深大走滑转换断裂带等分隔,各自有着不同的演化历史,控制了南海新生代多种类型次级沉积盆地的地质特征。     

南海西缘结合带的贯通性

为了探讨南海西缘结合带的构造贯通性, 在系统分析其地质-地球物理资料的基础上, 剖析了该带的分段性和深-浅部构造几何学特征, 对该带的哀牢山-红河-越东-万纳-卢帕尔各段进行了全面的构造几何学及构造运动学上的对比分析, 提出该带是一条相互贯通的走滑断裂系统, 其各部分在构造几何学上符合走滑构造的基本构架, 构造运动学上具有同时性, 浅部各段具有共同相连的深部的"根", 表现出明显的时空上的贯通性与构造上的一致性.      

西准噶尔走滑断裂系元素分布特征及其成矿意义

我国新疆西北部西准噶尔走滑断裂构造体系(简称"西准系")是中亚造山带巴尔喀什马蹄形构造的向东延伸部分,由于中生代成吉思-准噶尔断裂的右行走滑断裂作用而被分成了两个部分。西准系是一个多米诺式的走滑断裂构造体系,主要由达拉布特断裂、玛依勒断裂、巴尔鲁克断裂等三条NE走向的左行走滑断裂及其夹在它们之间的地块所组成,可能是晚古生代与走滑断裂相关的陆条弯曲(褶皱)作用的产物。同时,西准噶尔地区也是重要的晚古生代成矿带,产出有一些大型和超大型的金属矿床,包括包古图斑岩铜矿、哈图金矿、萨尔托海铬铁矿和杨庄铍矿床等。本文分析了西准系走滑断裂构造与元素分布之间的关系。结果显示,西准噶尔成矿带元素与地球化学块体以及铜、金、钼、铬铁矿等矿床的分布,均受晚古生代西准系的形成与演化过程的控制。其中,庙尔沟、红山岩体与金地球化学块体之间的反对称分布特征,说明了花岗岩类侵入体和金元素在达拉布特断裂左行走滑过程中发生了重要的物质调整与迁移作用。庙尔沟岩体的逆时针旋转运动,造成了环状断裂与裂隙系统,以及与之相对应的Cu、Pb等元素风火轮式的分布形式。走滑断裂作用与岩体旋转运动的共同结果,导致了金元素沿断裂和裂隙的迁移与成矿,使得西准地区金矿床在断裂和裂隙中的发育。断裂构造体系与元素地球化学异常之间的关系,可以用来有效指导西准地区未来矿产资源的勘查。     

Lithostratigraphic and sedimentary evolution of the Kom Ombo (Garara) sub-basin,southern Egypt

Southern Egypt is mostly covered by clastic sediments belonging to the Paleozoic and the Mesozoic. The Precambrian basement rocks bound the Etbai area to the east and Gabgaba area to the west. The basement extends further west forming dissected small and major exposures in southern Egypt, south of latitude 23° 30′ N but are covered by Cretaceous-Lower Tertiary sediments further north, the Western Limestone Plateau. The clastic sediments in southeast Egypt, on the western side of the basement rocks in-between latitudes 22° N and 24° 35′ N, built two sub-basins, Kom Ombo (Garara) sub-basin in the north and south Nile Valley sub-basin in the south. These are separated by a dissected basement wall. The two sub-basins have different lithostratigraphic successions, Paleozoic (Early to Late) in the south Nile Valley sub-basin whereas Late Paleozoic-Mesozoic-Tertairy in the Kom Ombo sub-basin. The platform clastic sediments within both sub-basins were possibly supplied from an easterly located Paleotethys extending to North Gondwana. The Oxfordian opening of the Indian Ocean associated with rise in sea level supplied more waters to the north and sediments by passed the filled southern Nile Valley sub-basin and reached the adjacent Kom Ombo sub-basin defining a depositional shift. On the other hand, during the Jurassic, Northern Egypt received Neotethys waters that filled deeper sub-basins (e.g., the Maghara sub-basin), hence the difference in lithology between Jurassic northern and southern sediments. Since the Jurassic, most of Egypt received Tethys waters. In the drilled wells studied, the younger top sediments surrounding the well sites are related to the Tethys geostratigraphy. The sub-basins in southern Egypt are controlled by N-S faults defining constant subsiding basins. The E-W Guinea–Nubia Lineament bounds the northern side of the Kom Ombo sub-basin, where it is closed by a northern basement arch.     

东海陆架盆地地质结构及构造演化

东海陆架盆地发育于东海大陆架之上,是一个复合型沉积盆地。盆地的西侧是浙闽隆褶带,东侧是钓鱼岛岩浆岩带,盆地从西至东呈现为凹-凸-凹的格局,南北差异明显,总体地质构造格架表现为东西分带、南北分块的特征。该盆地存在元古代的变质基底,是浙闽沿海陆区出露的深变质岩系向东的延伸,这套古老的变质岩系组成了陆架盆地的主要基底。盆地在垂向上表现为明显的多层结构。除古生界地质结构尚待证实外,中生界明显为裂谷型二层结构,新生界为三层结构。盆地结相特征受控于特定的构造演化过程。中生代以前不同性质的地体增生和中生代以来太平洋板块的运动方向不断变化以及印度板块作用造成的地壳蠕散是控制盆地形成和树造演化的主要体制,使盆地构造演化表现为多阶段、多种构造体的明显特征。     

Tectonics of the western part of the Polish Outer Carpathians

The western part of the Polish Outer Carpathians is built up from the thrust, imbricated Upper Jurassic-Neogene flysch deposits. The following Outer Carpathian nappes have been distinguished: Magura Nappe, Fore-Magura group of nappes, Silesian, Subsilesian and Skole nappes. Interpretation of seismic and magnetotelluric survey from the region South of Wadowice, allows observation of relationship between basement and flysch nappes in the Outer Carpathians. It also allows identification of dislocation cutting both flysch nappes and their basement. All the Outer Carpathian nappes are thrust over the southern part of the North European Platform. The platform basement is composed of older Precambrian metamorphic rocks belonging to the Bruno-Vistulicum terrane. Sedimentary cover consists of Paleozoic, Mesozoic and Neogene sequences. The characteristic features of this boundary are horsts and troughs of general direction NW-SE, turning W-E. Faults cutting only the consolidated basement and the Paleozoic cover were formed during the Hercynian Orogeny in the Carboniferous and the Early Permian. Most of the older normal faults were covered by allochtonous flysch nappes forming thus the blind faults. During the last stage of the geodynamic development the Carpathians thrust sheets moved towards their present position. Displacement of the Carpathians northwards is related to development of dextral strike-slip faults of N—S direction. The orientation of this strike-slip fault zones zone more or less coincides with the surface position of the major faults perpendicular to the strike of the Outer Carpathian thrustsheets. The huge fault cuts formations from the Paleozoic basement through the flysch allochton between the boreholes in Sucha Beskidzka area. The displacement of nappes of the Carpathian overthrust and diapiric extrusion of plastic formations of the lower flysch units occurred along this fault.     

南海西北次海盆及其邻区地壳结构和构造意义

西北次海盆的深部地壳结构蕴含着南海北部陆缘拉张过程的重要信息.广角反射/折射测线(OBS2006-2)长386 km,是目前唯一的一条沿NEE向穿过西沙地块、并平行于西北次海盆扩张脊的深地震测线.通过射线追踪与走时模拟方法(RAYINVR),获得了OBS2006-2测线下方的速度结构.结果表明:西沙地块的沉积层厚度约为1~2 km,而西北次海盆的沉积层厚度大约为2~3 km;Moho界面从西沙地块的27 km逐步抬升到西北次海盆的12 km,Moho界面下方的速度为7.8~8.0 km/s;未发现壳内高速层和低速层.在西沙地块和西北次海盆的过渡区,有着较大量的岩浆活动信息,推测与西北次海盆的初始扩张有关.OBS2006-2测线中114.5°E以西的地区为减薄的陆壳,而114.5°E以东的地区为洋壳,莫霍面在陆壳与洋壳的结合处剧烈抬升,地壳厚度明显减薄.西北次海盆的扩张脊下方可能有残余岩浆的存在.      

中国西北地区南华纪—古生代构造重建及关键问题讨论

中国西北是古亚洲构造域和特提斯构造域共同作用的地区,南华纪—古生代时期经历了复杂的洋-陆演化过程,诸陆（地）块于三叠纪基本拼贴就位,奠定了中生代以来陆内盆山演化的基础。但对于西北地区南华纪—古生代时期古亚洲洋盆最终关闭的时限、位置,以及秦祁昆古生代造山带属于特提斯构造域还是古亚洲构造域等重大区域地质问题目前仍存在较大争议。文章在最新地质填图的基础上,通过对沉积建造、岩浆建造、变质变形等的综合分析,将西北地区南华纪—古生代的构造单元厘定为3个洋板块、4个弧盆系和2个陆（地）块群等9个二级、46个三级和112个四级构造单元,力图刻画消失的大洋盆地的残留组成和诸陆（地）块的边缘增生结构。结合古地磁、生物古地理研究成果,恢复了古生代不同时期西北洋-陆系统在全球的位置,讨论了洋盆消减、诸陆（地）块拼贴的过程。      

再论塔里木板块的归属问题

长期以来，对塔里木板块属于华北板块？扬子板块？还是一个独立的板块？一直存在争议。本文根据塔里木板前寒武纪基底的性质，古生代沉积建造序列，生物古地理区系的面貌和古地磁资料认为：（１）塔里木是属于前寒武纪陆壳基底的独立板块，与周边板块之间的存在不同规模的洋盆；（２）早古生代时，塔里木位于南半球，更接近于扬子板块，而远离华北板块（３）在古生代一中生代时，塔里木板块与周边坡板块先后碰撞，直到三叠纪末，塔里     

Neogene stress field in the central and eastern parts of the outer Polish Carpathian Foredeep

The Polish Carpathian Foredeep (PCF) is a foreland basin formed during the regional flexure of the East European continental lithosphere related to a continental collision in the Carpathian realm. The infill of the PCF basin consist of the uppermost Lower to the Upper Miocene (Ottnangian-Pannonian) sediments. These are mostly mudstones and clays, more rarely sandstones, limestones and evaporites. Numerous thrusts, strike-slip and normal faults, and even folds exist in the whole PCF. The orientation of these structures is variable but they show the privileged directions. The spatial analysis of structures and their crosscutting relationships, together with published seismic data permit conclude that the regional stress field in studied part of PCF was stable during the whole Neogene time till now. The orientation of the maximum horizontal stress axis was NNE-SSW. The local changes of the stress field orientation were caused by activity of the strike-slip fault in the foredeep basement or even the rotation of the basement blocks. The visible response on the basement activity were mostly outcrop-scale structures, namely the number and variety of structures are increasing in individual outcrop. However, the map-scale structures were also generated, for example so called Ryszkowa Wola Horst, a large pop-up structure.     

合肥盆地基底构造属性

根据合肥盆地及周边地表地质、地震剖面、同位素测年及MT等新资料的综合研究,提出中-新生代合肥盆地的基底是一个不同构造类型基底的叠合与复合.上古生界以前的基底以六安断裂为界,其北为华北板块陆壳型-过渡壳型结晶基底及其上的华北克拉通-被动大陆边缘盆地沉积的上元古-下古生界基底;其南为大别型结晶基底及其上的北淮阳弧后盆地沉积的上元古-下古生界变质基底,而上古生界基底属于弧后前陆盆地型沉积.六安断裂是合肥盆地部位北大别弧、北淮阳晚元古-早古生代弧后盆地在早古生代晚期-晚古生代早期与华北板块的弧-陆碰撞缝合线.     

东濮凹陷构造变形的物理模拟研究

东濮凹陷是一个研究程度较高的含油气区,前人在构造变形研究方面多注重于伸展变形的几何学分析而忽略了形成机制中走滑分量的作用。本文在对区域地质背景和东濮凹陷构造特征分析基础上,设计平、剖面砂箱实验对该凹陷的构造变形进行伸展-走滑模拟研究。结果表明:(1)具走滑性质的断裂组合形成的构造样式更加复杂多样,走滑断层弯曲会产生挤压或伸展分量,在相邻的区域内形成局部的凹陷和隆起,主动盘的不同会形成不同的断裂组合;(2)在区域NNW—SSE向伸展变形下,形成了东濮凹陷两洼一凸的近对称格局,基底深断裂的张扭性开裂加速了凹陷的形成,主断层上、下盘均有明显的活动;(3)受基底断裂活动影响,大约Es~2-Ed沉积期凹陷存在一个明显的右旋走滑变形期,在凹陷的中部隆起带上出现了负花状、火焰状等典型走滑构造样式,走滑变形具有阵发性特点。     

西沙海域盆地构造格局及其差异演化过程分析

西沙海域夹持于南海西北次海盆和西南次海盆之间,构造演化过程与南海的扩张和南海西部的走滑作用关系密切.基于覆盖西沙海域的区域地震资料开展了构造—地层解释、盆地结构特征分析和区域构造演化制图,整体上将西沙海域划分出3种类型盆地,即高角度断层控制的盆地、低角度拆离断层控制的盆地和走滑盆地.结合地壳厚度变化和伸展薄化程度,突出断层的构造样式,将西沙海域划分为北部拆离断层构造发育区、东南部拆离断层构造发育区、西部走滑断层发育区和中部高角度断层发育区,进而明确了西沙海域盆地的基本构造格局.同时,以关键构造界面为主线,强调了不同类型断层在岩石圈地壳减薄过程中的作用,阐明了西沙海域盆地的差异构造演化过程.      

Ouachita, Appalachian, and Ancestral Rockies deformations recorded in mesoscale structures on the foreland Ozark plateaus

Mesoscale structures in Paleozoic rocks of the Ozark plateaus reveal four Pennsylvanian deformation episodes in midcontinent North America. The two earliest episodes can be assigned to progressive northwestward docking of the Ouachita terrane with North America. Early extensional structures (Event 1) indicate a northwest/southeast maximum horizontal stress (Hmax) during Early Pennsylvanian Ouachita terrane advance. Event 2 extensional and strike-slip structures indicate Hmax across the Ozark plateaus that varies systematically from north-northwest/south-southeast in the south to northeast/southwest in the north. This suggests development of a slip-line deformation field in response to minor northeastward lateral escape of lithospheric blocks away from the northwestward-moving Ouachita terrane's leading edge, which acted as an indenter in western Arkansas, southeastern Oklahoma, and Texas. Younger contractional and strike-slip structures of Event 3 indicate northeast/southwest Hmax across the entire Ozark plateaus, and deformation orientation and intensity are not readily assigned to Ouachita foreland deformation and may be related to Middle Pennsylvanian Ancestral Rockies contractional deformation. Finally, Event 4 contractional structures indicate northwest/southeast Hmax consistent with southern Appalachian late stage convergence.Deformation episodes are localized along basement fault zones, particularly at major bends, suggesting minor restraining-bend uplifts along strike-slip faults. Geometries of conjugate normal fault and hybrid shear joint arrays indicate localized areas of high differential stress consistent with basement block uplift at these bends. High-angle faults reactivated in a reverse sense and bedding-parallel veins suggest tensile minimum stresses and pore fluid pressures exceeding lithostatic stress, consistent with brine pulses driven into the midcontinent during Late Paleozoic orogeny (as proposed by other authors).     

定远凹陷形成的区域构造背景及其演化过程

定远凹陷上古生界构造归属及其构造演化过程,对下一步该地区煤炭资源评价与非常规天然气选区具有关键性的意义。文章利用最新的地球物理与钻探成果,应用构造解析及区域对比等方法,结合区域构造规律与前人相关认识,对定远凹陷构造特征、上古生界构造归属及中生代以来的构造演化过程进行了详细的论述,其结果认为定远凹陷内发育的上古生界煤系地层属于淮南煤田中部复式向斜构造带东部的延伸。该凹陷受大别造山带隆起及郯庐断裂带中、新生代走滑活动影响,分别经历了印支期（T3）前陆变形、早中侏罗世（J1+2）相对隆起、晚侏罗世（J3）末期至早白垩世初期（K1初期）郯庐断裂带左行走滑改造、早白垩世期间（K1）至古近纪(E）伸展改造、古近纪末期挤压反转以及新近纪（Q）—第四纪（N）坳陷式均匀沉降六个主要演化阶段。     

兴蒙造山带的基底属性与构造演化过程

为了解兴蒙造山带基底属性和多个构造体系演化与叠加历史,系统总结了近年来在基础地质研究中取得的新成果,并利用这些成果讨论了兴蒙造山带的基底属性与演化历史.兴蒙造山带是指我国东北地区古生代构造作用影响的地区,这些地区也遭受了中生代构造作用的叠加与改造.兴蒙造山带主要由微陆块和其间的造山带组成.虽然传统上认为属于前寒武纪结晶基底的地质体主要已解体为古生代和早中生代,但随着新太古代和古元古代地质体的相继发现,以及新生代玄武岩中幔源古元古代橄榄岩包体的发现,可以判定兴蒙造山带内微陆块应具有古老的前寒武纪基底,并且壳幔是耦合的.微陆块内部地壳增生以垂向增生为主,且主要发生在新元古代和中元古代,以及次要的新太古代和古生代.相反,陆块间造山带或岛弧地体的陆壳则以侧向增生为主,且主要发生在新元古代和古生代.额尔古纳地块与兴安地块的拼合发生在早古生代早期;兴安地块与松嫩地块的拼合发生在早石炭世晚期;松嫩地块与佳木斯地块的拼合发生在早古生代晚期,中生代早期又经历了裂解与再闭合的构造演化过程;华北克拉通北缘增生杂岩带与北方微陆块群的最终拼合发生在晚二叠世-中三叠世,古亚洲洋的最终闭合发生在中三叠世,且为剪刀式闭合.晚古生代晚期蒙古-鄂霍茨克大洋板块南向俯冲作用的发生以及早中生代(三叠纪-早侏罗世)的持续南向俯冲,控制了大兴安岭-冀北-辽西地区的岩浆活动,蒙古-鄂霍茨克大洋的闭合发生在中侏罗世,晚侏罗世-早白垩世主要表现为闭合后的伸展环境.古太平洋板块中生代的俯冲起始时间为早侏罗世,晚侏罗世-早白垩世早期东北亚陆缘主要表现为走滑的构造属性和陆缘地体从低纬度到高纬度的构造就位过程,早白垩世晚期-古近纪岩浆作用的向东收缩揭示了古太平洋板块的持续俯冲和俯冲板片的后撤过程,古近纪晚期日本海的打开标志着东北亚陆缘从活动陆缘已经转变为沟-弧-盆体系,并且标志着东亚大地幔楔的形成.     

塔里木盆地古生代构造格架与沉积特征

本文以板块构造理论为主线，应用最新的物探成果和钻井资料，分析了前古生代塔里木盆地地球动力学背景和寒武－奥陶纪、志留－泥盆纪、石炭－二叠纪板块构造演化所形成的盆内隆坳构造格架与沉积特征，认为古生代克拉通原型盆地的发育、各时期的沉积相带分布与沉积建造以及下古生界东厚西薄、上古生界东薄西厚的厚度特征，都是不同地质时代构造演化控制的结果。     

鄂尔多斯盆地基底演化及其对盖层控制作用

基底演化过程与其上覆沉积盖层的发展密切相关,因而可以通过盖层与基底的构造格局对比分析来推断基底演化的主要阶段,并进一步讨论盆地基底演化与盖层变形之间的相互作用。研究发现,鄂尔多斯盆地基底演化与自身结构和受力方式均有密切关系,同时对盖层变形有重要控制作用。早古生代在南北向洋-陆碰撞背景下,基底受自身组成结构制约在盆地内部发育了北东向隆坳相间的构造格局,晚古生代受南北向陆-陆碰撞的影响而在早期北东向展布的隆坳构造基础上叠加了南北向的中央古隆起,由于此时厚度较小,盖层的整体格局与局部形态都受控于基底的构造格局。至中生代燕山期,盆地受到了东西向挤压作用,基底内部形态基本保持不变,盆地基底边缘有明显的垂向活动,具体表现为东升西降;此时盖层发育已较为完整,因此更多地体现了相对孤立演化的特征,但其“跷跷板”式的运动总体上仍受到基底边缘升降活动的控制。     

松辽盆地构造演化与中国东部构造体制转换

本文综合应用盆地构造解析、平衡地质剖面恢复、构造物理模拟等方法,探讨了松辽盆地构造演化及其地球动力学背景。松辽盆地基底是前侏罗纪古亚洲洋构造域众多微板块、地体拼贴形成的复合陆块。中—晚侏罗世,盆地基底受到郯(城)—庐(江)断裂系北段大规模左旋走滑活动的强烈改造,派生NNE、NNW和近NS向次级断裂,控制了基底构造格局、断陷盆地分布及其构造。断陷期可划分为早、晚两个脉冲式伸展阶段,早期阶段受多方向平面式正断层控制发育堑—垒构造,具有双向纯剪伸展的特点,但NNE向拉伸更显著,可能是深部岩石圈拆沉引起热穹窿与基底断裂持续左旋走滑拉分的叠加;晚期阶段受低角度犁式正断层控制发育西断东超的复合半地堑,受控于近EW向单剪伸展机制,是区域性地壳伸展拆离与岩石圈减薄的结果。拗陷期大规模热沉降是对古太平洋构造域向东迁移的响应。白垩纪末期盆地受到NWW向脉冲式挤压而发生反转,可能与伊泽纳奇板块消亡、太平洋板块开始俯冲这一转换过程中的地体拼贴有关。     

沂沭断裂带内盖层的剪切变形及其构造意义

通过沂沭断裂带内晚元古代至古生代益层变形的详细研究，发现这套盖层遭受了明显的顺层左旋走滑剪切变形。这期盖层变形是与沂沭断裂带基底中北北东走向左行韧性剪切带同期形成的。它们是郯庐断裂带中生代大规模左行平移运动在不同层次上所造成的不同产物。这套益层的变形及其特征证明了郯庐断裂带大平移发生在中生代。