阜新-义县盆地构造演化及应力场光弹性模拟分析

阜新盆地的形成主要受北西向构造活动控制,在北西向构造形成时的北北东—南南西向挤压应力作用下,成盆前的北北东、南北和近南北向断裂受引张作用,导致内倾断裂以正断层形式作张性下滑,形成断陷,使阜新盆地扩张。早白垩世以后,新华夏系北西西—南东东挤压应力重新活动,北北东、南北和近南北向断裂遭受挤压,断陷作用消失,进而以压扭性方式重新活动,对阜新盆地起着破坏和改造作用。     

准噶尔西北缘石炭-二叠纪构造转换期变形分析及其地质意义

通过对扎伊尔山至哈拉阿拉特山一带详细的构造变形分析, 揭示出准噶尔西北缘主要发育以下3组构造组合: 近南北向、北东-南西向和近东西向.其变形序列为: 晚石炭世早期, 发育近南北向褶皱-冲断构造; 晚石炭世时期, 近南北向构造线受牵引拖拽呈北东-南西向, 达尔布特、克拉玛依蛇绿混杂岩以右旋走滑拉出或侧向楔冲形式构造就位于上覆石炭系中; 晚石炭世晚期至二叠纪, 发育以达尔布特断裂为代表的北东-南西向伸展断裂, 伴随广泛的中基性岩脉及花岗岩侵入; 二叠纪末至三叠纪初, 发育广泛的近东西向劈理、哈山一带逆冲推覆构造及达尔布特左旋走滑活动.石炭纪至二叠纪, 西准地区经历了从俯冲到碰撞再到碰撞后陆内变形的演化过程, 伴随着挤压和伸展多期构造叠加, 充分体现了该地区复杂构造转换变形的动力学过程.      

雪峰山西侧贵州地区中生代构造特征及其演化

贵州中生代变形主要发生在燕山期,发育三幕褶皱变形、两幕逆冲和三幕走滑。根据区域对比、卷入褶皱的地层和褶皱间的叠加关系,判断三期褶皱的形成顺序依次为近东西向、北东向和南北向,时限在J_3—K_2之间。逆冲推覆构造主要由向北西或西逆冲的近南北向逆冲断层组成,大体与南北向褶皱同时形成;自雪峰构造带西缘向西,依次划分出根部带、中部带和前锋带。但是,在根部带识别出两幕逆冲推覆,其它两带各识别出一幕。走滑断层也有3个方向:东西向、北东向和近南北向。东西向走滑断层呈现出右行压扭的运动学特征,而大多数北东向走滑断层是左行张扭性质的。依据各个方向断层间的切割和限制关系,推测东西向走滑断层最早形成,其次是南北向逆冲断层,北东向走滑断层最晚活动。这些断裂和褶皱特征,总体表现出贵州多重多种复合联合的构造特征,最后,探讨了本区的构造成因模式。     

雪峰山西侧贵州地区中生代构造特征及其演化

贵州中生代变形主要发生在燕山期,发育三幕褶皱变形、两幕逆冲和三幕走滑。根据区域对比、卷入褶皱的地层和褶皱间的叠加关系,判断三期褶皱的形成顺序依次为近东西向、北东向和南北向,时限在J3—K2之间。逆冲推覆构造主要由向北西或西逆冲的近南北向逆冲断层组成,大体与南北向褶皱同时形成; 自雪峰构造带西缘向西,依次划分出根部带、中部带和前锋带。但是,在根部带识别出两幕逆冲推覆,其它两带各识别出一幕。走滑断层也有3个方向：东西向、北东向和近南北向。东西向走滑断层呈现出右行压扭的运动学特征,而大多数北东向走滑断层是左行张扭性质的。依据各个方向断层间的切割和限制关系,推测东西向走滑断层最早形成,其次是南北向逆冲断层,北东向走滑断层最晚活动。这些断裂和褶皱特征,总体表现出贵州多重多种复合联合的构造特征,最后,探讨了本区的构造成因模式。     

琼西莺歌海盆地断裂系统的成因机制

通过对莺歌海盆地构造变形背景和变形基本特征的分析,详细地研究了盆地断裂系统的特征及其分布规律,并结合区域构造演化,对断裂的成因机制进行了探讨。认为北西向断裂控制了盆地的总体构造格局,尤其是强烈的右旋扭动形成南北向雁行式的张裂隙,诱导了泥-流体底辟构造的发生;泥-流体底辟活动进一步形成局部的应力场,开启新的断裂和破碎带,同时,形成与超压流体的活动相关的流体压裂。     

丹池晚古生代盆地的沉积和构造演化*

丹池盆地属右江裂谷带靠近江南古陆南缘的次级裂陷盆地,其中的沉积可分为五个相区,十三种相类型。研究认为丹池盆地的形成、沉积作用、相和相序的分布均明显受到同沉积期断裂活动的影响。构造演化从泥盆纪初开始即有北西向丹池断裂的张裂作用,此种张裂与其派生的北北东向走滑断裂的复合作用,到二叠纪时,演变为北西向断裂的走滑活动,丹池盆地最初由半地堑式发展为地堑式盆地,到二叠纪成为-走滑盆地。     

鄂尔多斯盆地叠合演化及构造对成煤作用的控制

鄂尔多斯盆地是多期成煤盆地叠合改造形成的构造盆地。石炭纪、二叠纪、三叠纪和侏罗纪成煤盆地的沉积演化过程具有一定差异,但煤炭资源形成的时空规律具有高度相似性。大地构造背景转换过程控制聚煤期,石炭纪、二叠纪含煤岩系形成于加里东—海西构造运动转换过程,三叠纪和侏罗纪含煤岩系形成于印支—燕山转换过程。沉积作用转换区域控制成煤区,在近海型盆地中,成煤区位于向陆一侧的河-海沉积作用转换区域。在内陆湖泊型盆地中,成煤区位于围绕湖心呈环带状分布的河-湖沉积作用转换区域。燕山及以后的构造运动控制了含煤岩系的形变方式和煤炭资源赋存状态。鄂尔多斯成煤盆地后期改造的显著特点是西部逆冲,东部隆起,南部和北部隆升和断陷共生。盆地西缘发育近南北向逆冲推覆构造,导致侏罗纪含煤岩系大面积剥蚀,造成石炭纪、二叠纪含煤岩系剥蚀、重复、褶皱和断裂。东部发生大面积隆起,石炭纪、二叠纪和侏罗纪含煤岩系遭受大范围剥蚀。盆地内部形成向北西缓倾的斜坡和南北向延伸的向斜,使晚古生代、三叠纪、侏罗纪煤炭资源得到保存。南部和北部边缘相继发生先抬升后断陷,形成了银川—河套断陷和汾渭断陷,构成了鄂尔多斯盆地含煤岩系的南北边界。构造背景和沉积作用转换是控制煤炭资源形成的重要地质条件,在大地构造运动界面上覆岩系中,寻找沉积体系转换区域是战略性找煤的有效途径。     

塔里木盆地巴楚地区二叠纪以来构造应力场解析

通过构造地质演化分析, 将塔里木盆地西北部巴楚地区二叠纪以来具有较强构造变形的构造应力场分为3期:晚古生代二叠纪末、中生代三叠纪—古近纪和新生代新近纪以来。通过对巴楚地区岩墙、节理、擦痕、褶皱与断层等应力感构造的测量分析, 对各时代地层中应力感构造的发育特征进行对比与分期总结, 同时对节理等进行分期配套, 发现巴楚地区二叠纪末最大主压应力方向为北西向, 与中天山岛弧和塔里木板块的斜向碰撞有关; 三叠纪—古近纪为北北东向, 可能与侏罗纪塔里木盆地的顺时针旋转受到抑制有关; 新近纪以来由于印度板块与欧亚板块相互碰撞, 巴楚地区最大主压应力方向为南北向。利用二维有限元方法对巴楚地区新近纪构造应力场进行了数值模拟, 模拟结果与实际情况拟合较好。      

鄂尔多斯盆地西缘煤田构造演化及其控制因素

鄂尔多斯盆地西缘位于华北陆块和秦祁昆山造山带两个一级大地构造单元之间的过渡带内,特定的大地构造背景使其具有复杂的构造演化历程及特殊的煤田构造格局。鄂尔多斯盆地西缘由贺兰山逆冲推覆构造系统和六盘山东麓逆冲推覆构造系统组成,具有"南北分段、东西分带"的特点。为了进一步探讨鄂尔多斯盆地西缘煤田构造格局的形成演化及区域构造控制因素,本文基于野外地质调查和煤田勘查资料,恢复了本区自晚古生代以来的沉降抬升史和古构造应力场特征。印支期:研究区北部最大主压应力方向为北西-南东向,南部最大主压应力方向为北东-南西向;燕山期:北部最大主压应力方向为北西西-南东东向,南部最大主压应力方向为北东东-南西西向;喜马拉雅山期:北部受北西西-南东东向拉张应力,南部最大主压应力方向为北东-南西向。采用有限元数值模拟,探讨了鄂尔多斯盆地西缘煤田构造格局的形成与区域构造的演化的关系,强调北段贺兰山逆冲推覆构造系统的形成与阿拉善地块的向东挤出逃逸密切相关。     

准噶尔东部晚古生代—中生代构造样式、变形序列及棋盘格构造的形成过程与机制

自晚古生代以来，准噶尔盆地东部经历了多期陆内变形事件的改造，形成了独特的棋盘状构造，其形成演化是中亚造山带陆内变形的一个缩影，但其形成过程仍处于争议之中。此次研究围绕准噶尔盆地及周缘地区的二叠纪至新生代的构造变形开展研究，结果表明准噶尔盆地东部变形的驱动力主要来自不同板块边缘的相互作用，尤其是来自特提斯构造域的影响。晚二叠世，准噶尔盆地遭受了近东西向的挤压应力改造，盆地整体发生变形，形成了一系列近南北向逆冲断层和褶皱，为准东地区乃至整个盆地的棋盘格构造奠定了基础。早—中侏罗世期间，准噶尔盆地及其周缘地区经历区域性伸展，在盆地东北、西北缘均发育重要的左行张剪性走滑变形，形成了大型的走滑双冲构造。晚侏罗世，准东地区经历近东西向缩短作用，导致了侏罗纪之前的地层再次发生近南北向褶皱，变形的动力则可能来自特提斯构造域的向北作用，使准噶尔盆地经历不同程度顺时针旋转。晚白垩世，准东地区经历近南北向缩短作用，导致了之前的近南北向褶皱和断层褶皱变形，准东的棋盘格构造样式最终定型。新生代晚期，准东地区受到印度-欧亚板块碰撞远程效应的影响，但是影响范围和强度相对较小。     

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.     

准噶尔盆地南缘二叠纪—三叠纪构造-沉积环境与原型盆地演化*

准噶尔盆地南缘(简称“准南”)的构造-沉积演化历史以及原型盆地性质一直以来备受争议。依据沉积环境分析、地层对比以及沉积演化研究,结合火成岩年代学、大地构造学等研究成果,探讨了该区二叠纪—三叠纪多期次的伸展—挤压环境转换及沉积盆地性质转变。晚石炭世,准南西段处于北天山洋壳向伊犁地体俯冲的末期,沉积环境以滨浅海为主,为残留洋盆地;准南东段以半深海相碳酸盐沉积为主,发育典型的双峰式火成岩,显示为陆内的伸展环境。早二叠世,准南以滨浅海相细粒碎屑岩沉积为主,发育同沉积断裂和伸展垮塌变形构造,表现为陆内裂陷盆地的特征。中二叠世,准南仍以滨浅海相为主,但其沉积速率明显加快,沉积厚度变大,整体上表现为以热力沉降为主的坳陷盆地。晚二叠世,北天山和博格达地区普遍发育冲积扇或扇三角洲,上二叠统泉子街组和中二叠统红雁池组之间呈明显的角度不整合接触,沉积环境发生突变,均显示北天山快速冲断隆升,表明该时期准南为陆内压陷盆地。早三叠世,准南快速冲断结束,该区进入相对稳定的发展阶段,以发育滨浅湖相细粒沉积物为主,表现为弱挤压的陆内压陷盆地的特征。中晚三叠世,由于持续湖侵,沉积盆地范围进一步扩大,北天山被削高补低,准南乃至整个准噶尔盆地进入统一的内陆湖泊演化阶段,整体上以滨浅湖相—半深湖相沉积为主,表现出陆内坳陷盆地的特征。综合上述原型盆地性质和沉积环境分析,可将准南二叠纪—三叠纪构造-沉积演化划分为4个阶段:晚石炭世—中二叠世为后碰撞伸展阶段,晚二叠世为北天山挤压冲断阶段,早三叠世为弱挤压压陷和削高补低阶段,中晚三叠世为稳定拗陷和准平原化阶段。     

伊犁盆地尼勒克地区中二叠世陆相地层碎屑物源分析及其对西天山构造演化过程的约束

西天山在二叠纪时期的大地构造环境有岛弧成因和大陆裂谷成因两种不同的观点,伊犁盆地尼勒克地区中二叠统陆相红层的研究是解决上述争议的关键之一。该段地层自下而上是一套由冲洪积扇相、河流相、浅湖相和半深湖相组成的湖侵序列。本文综合该套地层的古水流、砾岩砾石成分与砂岩碎屑组分、重矿物组合、碎屑岩地球化学以及石榴子石化学特征等方面的研究,认为尼勒克盆地中二叠统陆相红层的物源复杂多样,包括超镁铁质-镁铁质岩、安山岩、英安岩、流纹岩、矽卡岩、片麻岩、灰岩和碎屑岩等不同岩石类型,记录了西天山造山带的构造剥蚀与再沉积过程。结合下二叠统乌郎组双峰式火山岩以及区域性角度不整合等资料的综合分析,本研究认为尼勒克地区中二叠世盆地形成于造山后伸展的大地构造背景。     

The Jurassic structural evolution of the western Daqingshan area,eastern Yinshan belt,North China

The western Daqingshan area, located in the eastern Yinshan belt, is dominated by the southern Daqingshan fold-and-thrust system and the northern Shiguai basin. Based on detailed structural investigations, stratigraphic controls, and geochronology, a three-stage tectonic evolution is proposed for the western Daqingshan area during the Jurassic. The discovery of syndepositional normal faults in the Early–Middle Jurassic sequences suggests that an N–S extensional regime (ca. 200–170 Ma) characterized the first deformational stage, which controlled the initial formation of the Shiguai basin. Subsequently, the relatively expansive rift basin was dissected by the initial development of the Daqingshan fold-and-thrust system that was associated with a N–S compressional regime (ca. 170–160 Ma). This phase of deformation involved the Lower–Middle Jurassic synrift sediments into a series of E–W-trending compressional structures, and controlled the deposition of Late–Middle Jurassic Changhangou growth strata ahead of the deformation front. Finally, the progression of Daqingshan fold-and-thrust system was dominated by NW–SE compression (ca. 160–145 Ma), which converted the previous E–W-trending compressional structures into a stepped geometry marked by several NE-trending oblique footwall ramps, and resulted in the depocentre of the Late Jurassic Daqingshan synorogenic conglomerate migrating markedly northeastwards. The driving mechanisms for these three palaeostress fields are considered as asthenosphere upwelling following Permian–Triassic collisional orogenesis, closure of the Mongol–Okhotsk Ocean, and NW-directed subduction of the Palaeo-Pacific plate, respectively.     

准噶尔盆地二叠纪盆地属性的再认识及其构造意义

准噶尔盆地及其邻区野外剖面、钻井剖面的系统对比和地震剖面的精细解释表明,二叠系沉积演化、断裂控制沉积、箕状断-超反射特征及大地构造背景均显示,二叠纪准噶尔盆地是形成于张性背景下的断陷-裂陷盆地。准噶尔盆地及邻区火山岩地化特征、年代学数据及区域构造研究成果也证明,二叠纪是张性的大地构造背景。早二叠世—中二叠世早期以发育冲积扇沉积为特征,各构造部位的沉积环境差异较大,强烈断陷并逐渐形成坳隆相间的沉积格局,为断陷盆地的裂陷期;中二叠统中晚期由早二叠世隆坳分割的局面逐渐转化为统一的大型内陆湖盆,吐哈盆地与准噶尔盆地水体相通,形成统一的沉积体系,为断陷盆地扩张期;晚二叠世时期以出现冲积-河流相红色粗碎屑沉积为特征,准噶尔盆地和吐哈盆地分割自成沉积体系,是断陷盆地的萎缩期。因此,中生代盆地演化是建立在二叠纪张性背景的基础之上,二叠纪断陷-裂陷盆地的提出对重新认识中生代盆地演化历程将具有重要启示意义,也将对今后的油气勘探具有重要指导意义,值得进一步研究。     

沉积盆地同沉积构造活动的沉积记录

同构造沉积盆地的沉积作用与构造环境及其活动性质有着内在的统一性,尽管控制沉积作用的因素很多(诸如气候、物源等),但最基本的因素乃是同沉积作用的构造活动,它控制着沉积体的分布、厚度、相型等。甚至不少沉积体是在两种或三种构造环境下发生的,因而有着纵横交替、相互更叠的复杂层序。而作为特殊沉积作用的沉积矿产,则更显著地制约于同沉积构造活动,尤其作为导矿构造的基底构造以及盆地演化中的控制性构造,则是寻找隐伏矿产的一     

Structures along the Orobic thrust, Central Orobic Alps, Italy

A series of regional deformation phases is described for the metamorphic basement and the Permian cover in an area in the central Orobic Alps, northern Italy. In the basement deformation under low-grade amphibolite metamorphic conditions is followed by a second phase during retrograde greenschist conditions. These two phases predate the deposition of the Permian cover and are of probable Variscan age. An extensional basin formed on the eroded basement during the Late Carboniferous, filled with fan conglomerates and sandstones, and rhyolitic volcanic rocks. Well-preserved brittle extensional faults bound these basins. Further extension deformed basement and cover before the onset of Alpine compressional tectonics. Cover and basement were deformed together during two phases of compressional deformation of post-Triassic age, the first giving rise to tectonic inversion of the older extensional faults, the second to new thrust faults, both associated with south-directed nappe emplacement and regional folding. Foliations develop in the cover only during the first phase of deformation as part of the activity on “shortening faults”. Main activity on the Orobic thrust actually postdates the first phase of thrusting and foliation development in the cover.     

Intracontinental Collisional Orogeny During Late Permian-Middle Triassic in South China: Sedimentary Records of the Shiwandashan Basin

Sedimentary response to an orogenic process is important for determining whether South China had compressional or extensional orogeny during the period from the Late Permian to the Middle Triassic besides the tectonic and magmatologic evidence. An intracontinental collision event took place between the Yangtze and Cathaysia blocks in the Late Permian. Beginning at the Late Triassic, the tectonic movement was completely changed in nature and entered a post-collisional extensional orogenic and basin-making process. This paper presents sedimentological evidence from the Late Permian to the Middle Triassic in the Shiwandashan basin at the southwestern end of the junction zone between the Yangtze and Cathaysia blocks.     

西南三江构造体系及演化、成因

西南三江构造体系突出表现为以昌都-兰坪-思茅地块为中轴的不对称走滑对冲构造,次为与走滑断裂相伴的伸展滑脱、走滑拉分盆地构造体系,再次为块体内部的近北东、北西向走滑断裂系。西南三江造山带构造体系演化分为挤压收缩变形、走滑深熔热隆、走滑剪切伸展、走滑剥蚀隆升等4个阶段。自晚白垩世开始,印度板块与欧亚板块碰撞,西南三江造山带对冲体构造体系初始形成。自渐新世开始,印度板块持续向北楔入欧亚大陆,印度板块与扬子克拉通构成力偶,两者相向、相对运动,挤压与剪切特提斯大洋缝合带及两大陆边缘弧盆系等地质体,西南三江造山带对冲体构造体系进一步发展,近南北向剪切走滑构造体系形成,构造方向也由近东西转为近南北向。而与近南北向主走滑断裂带之相伴的伸展滑脱构造、拉分盆地,块体内部近北东、北西“X”型剪切走滑断裂同时相伴形成。这样,就形成了西南三江造山带大规模的对冲、走滑、旋转及其伴生的伸展、拉分盆地构造的构造体系。     

论鄂尔多斯盆地及其周缘侏罗纪变形

侏罗纪是东亚大地构造发展的重要转折时期,在鄂尔多斯盆地及其周缘可划分为两个性质不同的构造变形阶段。早中侏罗世,盆地处于弱引张应力环境,引张方向近N-S至NNE-SSW向,伸展变形主要发生在盆地周边地带,其发生与晚三叠世华南-华北地块沿秦岭造山带碰撞后的陆内应力场调整作用有关。中晚侏罗世,盆地遭受多向挤压应力作用,挤压方向近W-E、NW-SE和NE-SW,在盆地周缘形成展布方向不一、构造样式不同的边界挤压构造带,盆地轮廓基本定型。西缘近N-S向逆冲-推覆构造带的形成与阿拉善地块和陇西地块向东挤出作用有关;东缘及东南缘总体呈“S”形展布的挤压边界带表现为反向逆冲断裂及其相关褶皱,推测发生在山西台褶带深部滑脱系统的前锋上盘断坡。盆地北侧大青山地区近东西向大型推覆构造和早中侏罗世伸展断陷盆地构造挤压反转,表明阴山造山带在中晚侏罗世时期强烈的N-S向缩短变形和再生造山。鄂尔多斯盆地周缘边界构造带记录了中晚侏罗世强烈的陆内多向内挤压作用和大陆地壳增厚过程,其发生的动力学背景与周邻不同板块(古太平洋、西伯利亚、特提斯)同时向东亚大陆汇聚产生的远程效应有关。中晚侏罗世多向挤压变形加速了鄂尔多斯盆地生烃过程,对多种能源矿产富集和成藏定位产生重要影响。