曲折边界斜向裂陷伸展的砂箱实验模拟

根据黄骅盆地边界几何特征简化所设计的３个砂箱实验模型表明,同一裂陷伸过程可以形成不同走向的正断层,基底菜边界方向的变化可以引起裂陷内部断层走向的变化,陷盆地断瞳向受基底展边界方向和裂陷伸展方向的共同影响,裂陷边界及其附近断层走向主要受基底伸展边界方向的影响,裂陷内部、离伸展边界较远部位的断层走向主要受展方向影响,凸菜曲折边界可以引起断层转向,而凹工折边界的复合方向构成对断层走向的控制,黄骅新生代盆     

渤海湾盆地黄骅坳陷新生代伸展量的时空分布特征*

以渤海湾盆地黄骅坳陷22条区域地震剖面的构造解释为基础,利用平衡剖面技术计算了不同位置剖面的伸展量、伸展率和伸展系数,并分析了伸展量的时空分布规律。研究表明,黄骅坳陷新生代具有幕式伸展的特点,而且伸展量的时空分布极不均匀。空间上,伸展量主要是由盆地主边界断层伸展位移造成的,主边界断层位移较大处的伸展量也相应较大;时间上,水平伸展运动可以分为始新世、渐新世和新近纪3个时期,其中,始新世伸展主要发生在盆地南部,渐新世发生在中北部,新近纪伸展量较小,主要发生在中部。伸展量时空分布是受盆地构造变形、构造演化控制的。始新世,NNE向沧东断层的伸展位移是控制盆地伸展变形的主要因素,且沧东断层在盆地南区的伸展位移量较大。渐新世,NNE向沧东断层在盆地中北区的伸展位移量相对较大,同时盆地内部NNE向基底断层的右旋走滑诱导的NE向基底正断层对盆地伸展变形做出贡献。新近纪,盆地在后裂陷的热沉降过程中NNE向基底断层仍然有右旋走滑位移,致使盆地中部发育NE向盖层正断层。     

南海北部新生代盆地断裂系统及构造动力学影响因素

利用地震资料、油气勘探资料分析了南海北部大陆边缘珠江口-琼东南新生代盆地断裂系统的时空差异及动力学成因机制.珠江口-琼东南盆地古近系裂陷构造层以NE向、近EW向基底正断层构成的伸展断裂系统的几何学、运动学沿着盆地走向有明显变化,盆地内部隐伏的区域性和局部的NW向断裂及相关构造变形带构成伸展断裂系统之间的构造变换带.在空间上,区域性的云开、松涛-松南等NW向构造变换带以西为NE-NEE向正断层构成的"非拆离"伸展断层系,以东为NE向正断层、近EW向正断层(走滑正断层)复合而成的拆离伸展断层系.在时间上,古近纪裂陷作用可划分为早(文昌组沉积期)、中(恩平组/崖城组沉积期)、晚(珠海组/陵水组沉积期)3个有明显差异的裂陷期.裂陷早期,盆地西部以平面式正断层控制的简单地堑、半地堑为主,伸展量相对较小,东部则以铲式正断层控制的复式地堑、半地堑为主,伸展量相对大,断层向深部收敛在中地壳韧性层构成拆离的伸展断层系统.裂陷中期,琼东南盆地、珠江口盆地西部断裂具有继承性活动特点,珠江口盆地东部发育NWW-EW向伸展断层,并向深层切割早期浅层拆离断层,形成深层拆离伸展断层系统,而沿着云开构造变换带发育反转构造.裂陷晚期,琼东南盆地、珠江口盆地西部断裂具有活动性减弱特点,琼东南盆地东部发育NWW-EW向伸展断层,形成深层拆离伸展断层系统,而沿着琼中央构造变换带发育反转、走滑构造.珠江口-琼东南盆地不同区段断裂系统及其构造演化的差异性受盆地基底先存构造、地壳及岩石圈结构及伸展量等多方面因素的影响,拆离伸展断层系统与发育NWW向"贯穿"断裂的基底构造薄弱带、现今地壳局部减薄带相关,南海扩展由东而西的迁移诱导北部大陆边缘块体沿着先存NW向深大断裂发生走滑旋转是导致变换构造带两侧差异伸展的动力学原因,应力场及岩石圈热结构变化是引起拆离断层深度变化的重要因素.     

基于平面砂箱实验对黄骅盆地新生代构造成因的新解释

根据黄骅盆地实际情况设计系列砂箱实验模型。基于实验结果分析,笔者认为黄骅盆地是近Ｓ—Ｎ 向伸展形成的新生代裂陷盆地。盆地内部不同方向的断层形成于同一伸展变形过程。导致盆地内部断层方向复杂多变的原因是盆地裂陷边界方向的变化, 而非走滑构造或拉分作用叠加的结果。实验模型同时也可较好地用以解释整个渤海湾盆地区新生代构造的成因。     

二连盆地中生代构造变形主控因素:物理模拟与讨论

二连盆地是中国东北部中生代含油气盆地,与中国东部中生代裂陷盆地之间存在显著的几何学与运动学相似性,根据盆内构造线走向和典型地震剖面构造样式可划分为中央正向裂陷带和周缘斜向裂陷带。尽管前人对盆地中生代构造变形开展了大量研究,但有关同期构造控制因素的认识尚不清晰。为此,研究以二连盆地为原型,设计了3组分别改变伸展速率、伸展方向及同沉积作用的平面沙箱模型。实验结果表明伸展方向控制裂陷内部断层特征;南东向的伸展速率改变深层构造薄弱带的扩展和断裂发育规模;同沉积作用促进基底滑脱层的活动强度,且进一步抑制边界断裂的生长。模拟结果还揭示了伸展方向是该盆地构造变形的主要控制因素;同沉积作用和伸展速率为次要控制因素。同时根据中国东部及邻区典型中生代裂陷盆地的几何学与运动学相似性,认为"南东向伸展"可以提供较好的运动学解释。     

“不协调伸展”作用下裂陷盆地断层的形成演化模式

应用"不协调伸展"的目标砂箱模拟实验成果和新的脆性断裂力学模型——"不协调性准则",分析了裂陷盆地断层形成和演化的控制影响因素,建立了裂陷盆地断裂系统形成和演化的新模式——"不协调伸展"模式。该模式显示:"不协调伸展"的递进变形过程是导致裂陷盆地断裂系统的复杂性的根本原因,实质是不同方向、性质和规模的基底先存构造(主要是先存断裂)的活动性方面存在差异,导致所控制形成的断层在走向、形成的先后次序、规模等方面存在差异,从而形成复杂的断层组合;"不协调伸展"模式是裂陷盆地断裂系统形成和演化的基本型式,复杂的断裂系统可以在方向不变的区域伸展构造作用下在递进变形过程中逐渐形成;裂陷盆地断裂系统虽然比较复杂,但断层的形成和演化是有序的,分布是有规律的,可以通过"不协调性准则"加以分析和预测。     

“不协调伸展”作用下裂陷盆地断层的形成演化模式

应用“不协调伸展”的目标砂箱模拟实验成果和新的脆性断裂力学模型——“不协调性准则”,分析了裂陷盆地断层形成和演化的控制影响因素,建立了裂陷盆地断裂系统形成和演化的新模式——“不协调伸展”模式。该模式显示：“不协调伸展”的递进变形过程是导致裂陷盆地断裂系统的复杂性的根本原因,实质是不同方向、性质和规模的基底先存构造(主要是先存断裂)的活动性方面存在差异,导致所控制形成的断层在走向、形成的先后次序、规模等方面存在差异,从而形成复杂的断层组合;“不协调伸展”模式是裂陷盆地断裂系统形成和演化的基本型式,复杂的断裂系统可以在方向不变的区域伸展构造作用下在递进变形过程中逐渐形成;裂陷盆地断裂系统虽然比较复杂,但断层的形成和演化是有序的,分布是有规律的,可以通过“不协调性准则”加以分析和预测。     

裂陷盆地断层的形成和演化——目标砂箱模拟实验与认识

摘要 断层的分布、活动和演化是裂陷盆地构造研究的核心,也是其油气勘探的关键。大量高精度的三维地震资料表明裂陷盆地内断层分布组合十分复杂,无法用经典构造地质学理论——Anderson模式作出合理的解释, 现有的模式（叠加模式和斜向伸展模式等）也还没有很好地揭示裂陷盆地断层复杂性的实质和断层形成和演化的内在规律。本文以渤海湾盆地张巨河构造带和北部湾盆地涠西南凹陷两个有高精度三维地震资料覆盖、断层分布与组合十分复杂并富含油气的典型裂陷盆地区为原形,进行了目标砂箱模拟实验,再现了目标区构造的基本特征。砂箱实验所揭示裂陷盆地断裂系统的基本特征是：1）基底先存构造（主要所控制的断层构成了盆地断裂系统的基本格架;2）断层的形成与演化决定于基底先存断裂的取向、区域伸展方向及伸展量。首先形成的是有刚性边界基底先存断裂控制的断层。其次,形成的是薄弱带基底先存断裂控制的断层。继而,形成的是小型基底先存断裂控制的断层。最后,在远离基底先存构造的区域,形成与伸展方向垂直的新生断层。3）伸展作用早期,断层的方位主要决定于基底先存断裂的方位。随着伸展量的增大,受伸展方向的影响越来越大,晚期形成的断层常反映区域伸展作用方向。4）不协调递进伸展变形过程是导致裂陷盆地复杂断层体系的根本原因。上述砂箱模拟实验揭示的裂陷盆地在不协调性伸展作用下断层的形成与演化规律可以利用“不协调性准则”从理论上给予解释,表明在裂陷盆地中具有普遍意义。     

伸展方式对伸展构造形成特征影响的相似模拟

本文分析了三种不同基底伸展方式、具有膝状边界形态的砂箱实验模型 ,结果表明基底伸展方式的不同可以导致伸展盆地平面变形面貌和剖面构造样式上的显著差异。伸展方式对于凹形边界和凸形边界具有不同的影响。凹侧主动伸展模型在凹形边界附近形成平行边界复合方向的断层 ,在凸形边界附近则形成平行边界走向的断层。凸侧主动伸展则趋于在两侧边界附近形成近于垂直伸展方向的断层。由此可见 ,可能借助伸展盆地的断层平面变形面貌判别主动分离块体。     

二连盆地乌尼特坳陷伸展构造特征及成盆演化

乌尼特坳陷属于二连盆地五大坳陷之一,早白垩世在区域引张力下形成一系列地堑、半地堑,其伸展构造由伸展断层及变换构造组成。伸展断层中的主边界断层主要为铲式,混杂岩断陷带主边界断层多在混杂岩深层滑脱,复式向斜断陷带主边界断层多在浅层滑脱。平面上主边界断层表现为简单弧形或波状延伸,位移量通过变换断层及走向斜坡等进行调节/传递。首尾相连的断陷间主要以狭窄的背向型(divergent)及宽阔的相向型(convergent)变换带进行构造变换,穿过变换带断陷极性常常发生变化。早白垩世早期,乌尼特坳陷由多个相互独立的小型断陷组成;早白垩世中期,随着伸展量不断加大,相邻断陷边界断层逐渐侧向连接成为区域性边界断层,相邻断陷侧向连接成为大型复式断陷;早白垩世晚期,断陷群下沉坳陷进入后裂陷期。     

黄骅坳陷中北区和歧口凹陷断裂构造特征及古应力分析

主要分析了黄骅坳陷中北区和歧口凹陷断裂构造特征。根据三维地震资料编制的Ｔ４和Ｔ０断裂纲要图表明，研究区断裂为伸展正断层，以ＮＥ向、ＮＮＥ向和ＥＷ向断裂为主。在不同时期，歧口凹陷断层走向发生明显变化，由沙一下段ＮＥ向变为上第三系的近ＥＷ向。在不同地段，伸展断裂具有不同的优势方向。横向变换带上发育的断裂也为伸展断裂，具有与主断层垂直相交的方向。通过对断裂古应力分析，黄骅盆地是伸展型盆地，推测其伸展作用为三维放射状，横向变换带也具有三维伸展特征，不存在横向挤压和走滑剪切作用。     

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.      

TECTONIC DEFORMATION AND STRONG EARTHQUAKE ACTIVITIES ON THE EAST BORDER OF TIBET PLATEAU

TECTONIC DEFORMATION AND STRONG EARTHQUAKE ACTIVITIES ON THE EAST BORDER OF TIBET PLATEAU     

略论华北地块北缘显生宙三类不同的造山作用

华北地块北缘显生宙发育3种不同类型的造山作用。古生代,华北地块北缘处于古亚洲洋构造域,造山作用属陆缘俯冲-碰撞型,形成以EW向至NEE向为主的褶皱、逆冲推覆构造及韧性剪切带等构造类型。造山机制与古亚洲洋板块向南俯冲-碰撞导致近SN向构造动力的挤压作用密切相关。中生代,华北地块北缘处于西滨太平洋构造域,造山作用以陆内挤压型为主,形成以NE-NNE向与近EW向为主的多期不同方向的褶皱、逆冲断裂、推覆构造、韧性剪切带及局部地区的固态塑性流变构造等构造类型;造山动力以古太平洋(或Izanagi)板块西向俯冲导致NW-NWW向强烈挤压力为主。新生代,华北地块北缘虽仍属西滨太平洋构造域,但造山作用以陆内伸展型为主,裂谷作用与陆内伸展构造居主导地位,褶皱变形微弱,张性-张扭性断裂活动显著,形成现今盆-山构造地貌格局;造山动力以NW-NWW向主张应力为主。造山类型的两次重大转换分别发生于早、中三叠世与晚白垩世。      

Influence of syn-sedimentary faults on orogenic structure: examples from the Neoproterozoic–Mesozoic east Siberian passive margin

The east margin of the Siberian craton is a typical passive margin with a thick succession of sedimentary rocks ranging in age from Mesoproterozoic to Tertiary. Several zones with distinct structural styles are recognized and reflect an eastward-migrating depocenter. Mesozoic orogeny was preceded by several Mesoproterozoic to Paleozoic tectonic events. In the South Verkhoyansk, the most intense pre-Mesozoic event, 1000–950 Ma rifting, affected the margin of the Siberian craton and formed half-graben basins, bounded by listric normal faults. Neoproterozoic compressional structures occurred locally, whereas extensional structures, related to latest Neoproterozoic–early Paleozoic rifting events, have yet to be identified. Devonian rifting is recognized throughout the eastern margin of the Siberian craton and is represented by numerous normal faults and local half-graben basins.Estimated shortening associated with Mesozoic compression shows that the inner parts of ancient rifts are now hidden beneath late Paleozoic–Mesozoic siliciclastics of the Verkhoyansk Complex and that only the outer parts are exposed in frontal ranges of the Verkhoyansk thrust-and-fold belt. Mesoproterozoic to Paleozoic structures had various impacts on the Mesozoic compressional structures. Rifting at 1000–950 Ma formed extensional detachment and normal faults that were reactivated as thrusts characteristic of the Verkhoyansk foreland. Younger Neoproterozoic compressional structures do not display any evidence for Mesozoic reactivation. Several initially east-dipping Late Devonian normal faults were passively rotated during Mesozoic orogenesis and are now recognized as west-dipping thrusts, but without significant reactivation displacement along fault surfaces.     

中国东-南部裂陷盆地断裂系统复杂性的表现形式及成因机制——以南堡凹陷和涠西南凹陷为例

中国东-南部裂陷系列盆地油气资源十分丰富,而断层的分布演化十分复杂,是油气进一步勘探开发需要解决的关键问题。本文应用广义断层模式,在大量三维地震资料构造解析的基础上,以渤海湾盆地的南堡凹陷和北部湾盆地的涠西南凹陷为例,对中国东-南部盆地复杂的断裂系统进行了解剖和归纳,并提出了伸展变形区预测断层性质的伸展应变椭圆。结果表明,中国东-南部裂陷盆地断裂系统的复杂性存在9种表现方式,从成因上进一步归纳为3个方面:(1)断层的走向和性质多样;(2)断层在平、剖面上存在复杂多变的组合形式;(3)断层形成和演化存在复杂的时-空关系。造成复杂性的根本原因是先存断裂分布的复杂性和不同方向(北西-南东向和近南北向)伸展变形的叠加。不同盆地、同一盆地不同区域应力场演化具有很大的相似性:40Ma以前,北西-南东向伸展;38Ma以来,近南北向伸展。断层分布和演化差异主要是由先存构造分布差异造成的。     

Tectonic Model of Boundary Fault Migration and its Genetic Mechanism in the Nanpu Sag,Bohai Bay BasinEI北大核心CSCD

Due to the important control on basin formation and hydrocarbon accumulation, boundary faults have always been the focus of attention in the study of rift basins. However, researches on boundary fault migration in the rift basins have not been reported yet. On the basis of structural analysis of 3D seismic data in the Nanpu Sag, faulting model of pre-existing weaknesses regional tectonic stress field results, and the latest exploration achievements in the Jidong Oilfield, the northern boundary faults in the Nanpu Sag were systematically analyzed. A new model of boundary fault (Boundary faults migration model) is proposed. The results show that: (1) in the rifting stage, with the evolution of tectonic stress field, the northern boundary faults are continuously migrating; (2) the No.5 fault is the northern boundary fault in E2s3 era in the west side of the sag, and the Gaoliu fault is the northern boundary fault in E3d1-2 era in the middle of the sag; (3) the change of stress field (the extension direction) in the rifting stage is the primary cause for the boundary fault migration in the rift basin. Considering that the change of extension direction during 40-38 Ma involves almost all the Cenozoic rift basins in the eastern and southern China, the model of boundary fault migration is expected to have useful implication for fine structural interpretation and oil and gas exploration of the rifted basins in the east and south of China. © 2018, Science Press. All right reserved.     

渤海湾盆地黄河口凹陷东洼断裂体系发育特征及其变形过程的构造物理模拟

黄河口凹陷东洼是渤海盆地典型的盆缘洼陷,基于新一轮区域三维地震精细解释资料,采用构造解析与构造物理模拟技术相结合的方式,对黄河口凹陷东洼的断裂体系特征与构造演化过程进行研究.研究表明,受走滑和伸展变形的共同作用,研究了发育了以NNE-NE走向为主的走滑断裂体系和以EW-NEE走向为主的伸展断裂体系,断裂构造演化经历了孔店组-沙四段沉积时期的初始张扭裂陷阶段、沙三段沉积时期的走滑伸展裂陷阶段、沙一二段和东营组沉积时期的伸展萎缩持续走滑阶段、馆陶组和明化镇组沉积时期张扭变形阶段等4个阶段.其中,主走滑断层是在初始张扭裂陷阶段所形成的NE向伸展断层基础上持续活化而成;主伸展断层则形成于走滑伸展裂陷阶段的SN向伸展作用应力背景下.在伸展萎缩持续走滑阶段,各方位断裂在近SN向伸展作用下持续再活动,表现为走滑-伸展复合变形为主;在张扭变形阶段,先期主干断裂选择性活动,同时新生形成大量新近系的次级断层.      

Late Mesozoic and Cenozoic rifting and its dynamic setting in Eastern China and adjacent areas

During the Late Mesozoic and Cenozoic, extension was widespread in Eastern China and adjacent areas. The first rifting stage spanned in the Late Jurassic–Early Cretaceous times and covered an area of more than 2 million km² of NE Asia from the Lake Baikal to the Sikhot-Alin in EW direction and from the Mongol–Okhotsk fold belt to North China in NS direction. This rifting was characterized by intracontinental rifts, volcanic eruptions and transform extension along large-scale strike–slip faults. Based on the magmatic activity, filling sequence of basins, tectonic framework and subsidence analysis of basins, the evolution of this area can be divided into three main developmental phases. The first phase, calc-alkaline volcanics erupted intensely along NNE-trending faults, forming Daxing'anling volcanic belt, NE China. The second phase, Basin and Range type fault basin system bearing coal and oil developed in NE Asia. During the third phase, which was marked by the change from synrifting to thermal subsidence, very thick postrift deposits developed in the Songliao basin (the largest oil basin in NE China).Following uplift and denudation, caused by compressional tectonism in the near end of Cretaceous, a Paleogene rifting stage produced widespread continental rift systems and continental margin basins in Eastern China. These rifted basins were usually filled with several kilometers of alluvial and lacustrine deposits and contain a large amount of fossil fuel resources. Integrated research in most of these rifting basins has shown that the basins are characterized by rapid subsidence, relative high paleo-geothermal history and thinned crust. It is now accepted that the formation of most of these basins was related to a lithospheric extensional regime or dextral transtensional regime. During Neogene time, early Tertiary basins in Eastern China entered a postrifting phase, forming regional downwarping. Basin fills formed in a thermal subsidence period onlapped the fault basin margins and were deposited in a broad downwarped lacustrine depression. At the same time, within plate rifting of the Lake Baikal and Shanxi graben climaxed and spreading of the Japan Sea and South China Sea occurred. Quaternary rifting was marked by basalt eruption and accelerated subsidence in the area of Tertiary rifting. The Okinawa Trough is an active rift involving back-arc extension.Continental rifting and marginal sea opening were clearly developed in various kind of tectonic settings. Three rifting styles, intracontinental rifting within fold belt, intracontinental rifting within craton and continental marginal rifting and spreading, are distinguished on the basis of nature of the basin basement, tectonic location of rifting and relations to large strike–slip faults.Changes of convergence rates of India–Eurasia and Pacific–Eurasia may have caused NW–SE-trending extensional stress field dominating the rifting. Asthenospheric upwelling may have well assisted the rifting process. In this paper, a combination model of interactions between plates and deep process of lithosphere has been proposed to explain the rifting process in East China and adjacent areas.The research on the Late Mesozoic and Cenozoic extensional tectonics of East China and adjacent areas is important because of its utility as an indicator of the dynamic setting and deformational mechanisms involved in stretching Lithosphere. The research also benefits the exploration and development of mineral and energy resources in this area.