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.     

Structure and tectonics along the inner edge of a foreland basin: The Hunter Coalfield in the northern Sydney Basin,New South Wales

From the early Late Permian onwards, the northeastern part of the Sydney Basin, New South Wales, (encompassing the Hunter Coalfield) developed as a foreland basin to the rising New England Orogen lying to the east and northeast. Structurally, Permian rocks in the Hunter Coalfield lie in the frontal part of a foreland fold‐thrust belt that propagated westwards from the adjacent New England Orogen. Thrust faults and folds are common in the inner part of the Sydney Basin. Small‐scale thrusts are restricted to individual stratigraphic units (with a major ‘upper decollement horizon’ occurring in the mechanically weak Mulbring Siltstone), but major thrusts are inferred to sole into a floor thrust at a poorly constrained depth of approximately 3 km. Folds appear to have formed mainly as hangingwall anticlines above these splaying thrust faults. Other folds formed as flat‐topped anticlines developed above ramps in that floor thrust, as intervening synclines ahead of such ramp anticlines, or as decollement folds. These contractional structures were overprinted by extensional faults developed during compressional deformation or afterwards during post‐thrusting relaxation and/or subsequent extension. The southern part of the Hunter Coalfield (and the Newcastle Coalfield to the east) occupies a structural recess in the western margin of the New England Orogen and its offshore continuation, the Currarong Orogen. Rocks in this recess underwent a two‐stage deformation history. West‐northwest‐trending stage one structures such as the southern part of the Hunter Thrust and the Hunter River Transverse Zone (a reactivated syndepositional transfer fault) developed in response to maximum regional compression from the east‐northeast. These were followed by stage two folds and thrusts oriented north‐south and developed from maximum compression oriented east‐west. The Hunter Thrust itself was folded by these later folds, and the Hunter River Transverse Zone underwent strike‐slip reactivation.     

大杨树盆地的构造特征及变形期次

大杨树盆地是叠置于大兴安岭造山带的东部,与松辽盆地紧邻,呈北北东向长条带状展布的中新生代断陷-坳陷型盆地。大杨树盆地经历了多期变形作用,具有以伸展构造为主、并被挤压构造和反转构造叠加的构造特征。早白垩世龙江期主要受到了NWW—SEE向的拉伸作用,形成一系列北北东向控陷犁式正断层组合,在控陷断层的上盘发育小型箕状断陷;早白垩世九峰山期,大杨树盆地受挤压作用控制,使早期形成的断陷盆地发生反转作用,形成正反转构造,同时在某些地段形成逆冲断层和断层传播褶皱;早白垩世甘河期,大杨树盆地再次受到伸展作用,形成了一系列北北东向小型断陷。早白垩世晚期(甘河期之后)—晚白垩世早期,大杨树盆地受到强烈的挤压作用,使早期控陷正断层出现正反转作用,在盆地的浅部形成大型断层传播褶皱,使大杨树盆地全面隆升遭受剥蚀。第四纪大杨树盆地具有伸展的特征,发育一系列小型伸展断陷。     

Improved Geometric Model of Extensional Fault–bend Folding

Extensional fault–bend folds, also called rollovers, are one of the most common structures in extensional settings. Numerous studies have shown that oblique simple shear is the most appropriate mechanism for quantitative modeling of geometric relations between normal faults and the strata in their hanging walls. However, the oblique simple shear has a rather serious issue derived from the shear direction, particularly above convex bends. We use geometric and experimental methods to study the deformation of extensional fault–bend folds on convex bends. The results indicate that whether the fault bends are concave or convex, the shear direction of the hanging wall dips toward the main fault. On this basis, we improve the previous geometric model by changing the shear direction above the convex bends. To illustrate basin history, our model highlights the importance of the outer limit of folding instead of the growth axial. Moreover, we propose a new expression for the expansion index that is applicable to the condition of no deposition on the footwall. This model is validated by modeling a natural structure of the East China Sea Basin.     

济阳盆地中生代构造特征与油气

济阳盆地中生代构造主要包括：印支期ＮＷ向压性构造（褶皱及逆断层）、消亡的ＮＷ向负反转半地垒及半地堑、燕山期ＥＮＥ向压性构造（褶皱或逆断层）、ＳＮ向地垒。印支期ＮＷ向压性构造是华北板块同扬子板块的聚敛运动的产物,而ＮＷ向负反转地垒和地堑、ＥＮＥ向压性构造及ＳＮ向地垒导源于郯庐断裂的左旋剪切作用,新生代郯庐断裂右旋剪切运动导致上述构造消亡并成为隐伏构造。中生代隐伏构造为济阳盆地深层勘探提供了潜山圈闭（     

依舒地堑汤原、方正断陷古近纪边界断裂活动特征

依舒地堑位于黑龙江省东部,为一新生代断陷盆地,汤原断陷和方正断陷为其两个面积较大的二级构造单元。通过对汤原断陷和方正断陷边界断裂的研究,可以进一步了解依舒断裂带的形成和演化过程。研究发现,在始新世-渐新世依舒地堑边界断裂的活动整体上具有多中心、不均衡的特征,汤原断陷东部的边界断裂为控盆断裂,方正断陷东、西两侧的边界断裂对盆地的发展都具有一定的控制作用,但西部边界断裂为主要控盆断裂。断层的生长指数分析表明,依舒地堑内部的北西向断裂与边界断裂的活动具有一致的规律性,都起到协调边界断裂演化发展的作用。依舒地堑边界断裂转换引张方向是由莫霍面梯度带的倾斜方向所决定,梯度带的倾向与地堑的整体伸展方向相同。     

An extensional and transtensional origin of elongated magmatic domes and localised transfer faults in the northern Menderes metamorphic core complex,western Turkey

The northern Menderes metamorphic core complex has complex exhumation history and is one of the key localities to investigate the spatial and temporal relationships of extensional and compressional structures. Detachment faults and syn-extensional plutons are linked to a series of antiforms and synforms and the denudation of the northern Menderes Massif occurred in three stages. The first stage is related to the development of detachment faults under the consistent NE–SW-directed extension. The second stage is represented by a series of elongated magmatic domes that were oriented parallel, oblique and perpendicular to the regional extension direction. Emplacement of these asymmetrical magmatic domes appears to have been controlled by heterogeneous extension and post-dates the extensional Simav detachment fault. On the third stage, progressive heterogeneous extension that led to updoming of plutons has been finally accommodated by a localised and short-lived transfer zone, which was described as the Gerni shear zone for the first time in this study. The transfer zone is formed by a NE-striking, dextral ductile/brittle shear zone that accommodated the propagation of folds, conjugated strike-slip faults and normal- and oblique-slip faults. Mylonites associated with the transfer zone are related to the localisation of strain along the thermally weakened strike-slip fault systems by short-lived intrusions rather than to the development of regional-scale detachment faults. These structures are consistent with a transtensional simple shear model, which properly explains the evolution of extensional and compressional structures exposed in the northern Menderes core complex. Structural setting of the E?rigöz region is somewhat similar to that of the NE-trending gneiss domes in the northern Menderes Massif and updoming of magma during late stages of detachment faulting appears to have played an important role in the exhumation of lower and upper plate rocks.     

Early Paleozoic and Andean structural evolution in the Rio Jáchal section of the Argentine Precordillera

In the fold-and-thrust belt of the northern Argentine Precordillera, Early Paleozoic basin and slope sediments are affected by a folding event which was combined with a slight greenschist facies metamorphism. The structural geometries are influenced by the former normal faulted boundary towards the eastern carbonate platform. To the east of the slope, Early Paleozoic marine deposits record a ˜ W-vergent folding without a clear metamorphic overprint. This deformation probably took place in the Devonian to pre-Upper Carboniferous interval while in the west an onset during the Late Silurian is reasonable. During Andean (Late Tertiary) compression, the escarpment was again reactivated as an important, east-directed thrust fault, and the folded strata to the east were juxtaposed along distinct, east-directed high-angle reverse faults with some ˜ N-S fold structures interfering with pre-Tertiary folds. Hence, the present architecture of this part of the orogen was largely influenced by different Early Paleozoic depositional realms and structures of one pre-Tertiary compressional event. The latter can be linked with the collision of the Sierras Pampeanas basement complex at the eastern margin of the Precordillera and be related to the collision with the Chilenia Terrane in the west.     

Active Faulting Pattern,Present‐day Tectonic Stress Field and Block Kinematics in the East Tibetan Plateau

Abstract: This paper examines major active faults and the present-day tectonic stress field in the East Tibetan Plateau by integrating available data from published literature and proposes a block kinematics model of the region. It shows that the East Tibetan Plateau is dominated by strike-slip and reverse faulting stress regimes and that the maximum horizontal stress is roughly consistent with the contemporary velocity field, except for the west Qinling range where it parallels the striking of the major strike-slip faults. Active tectonics in the East Tibetan Plateau is characterized by three faulting systems. The left-slip Kunlun-Qinling faulting system combines the east Kunlun fault zone, sinistral oblique reverse faults along the Minshan range and two major NEE-striking faults cutting the west Qinling range, which accommodates eastward motion, at 10–14 mm/a, of the Chuan-Qing block. The left-slip Xianshuihe faulting system accommodated clockwise rotation of the Chuan-Dian block. The Longmenshan thrust faulting system forms the eastern margin of the East Tibetan Plateau and has been propagated to the SW of the Sichuan basin. Crustal shortening across the Longmenshan range seems low (2–4 mm/a) and absorbed only a small part of the eastward motion of the Chuan-Qing block. Most of this eastward motion has been transmitted to South China, which is moving SEE-ward at 7–9 mm/a. It is suggested from geophysical data interpretation that the crust and lithosphere of the East Tibetan Plateau is considerably thickened and rheologically layered. The upper crust seems to be decoupled from the lower crust through a décollement zone at a depth of 15–20 km, which involved the Longmenshan fault belt and propagated eastward to the SW of the Sichuan basin. The Wenchuan earthquake was just formed at the bifurcated point of this décollement system. A rheological boundary should exist beneath the Longmenshan fault belt where the lower crust of the East Tibetan Plateau and the lithospheric mantle of the Yangze block are juxtaposed.     

柴北缘大柴旦地区山前带构造建模及演化研究

针对柴北缘大柴旦地区北东、北西向两组逆冲推覆断裂交汇,构造变形极其复杂,构造解析困难的问题,充分利用野外地质调查、地震、重磁电、钻井(孔)等资料,理清了研究区主要断裂体系及其组合特征与展布规律。采用地表和地下构造、浅部和深部构造、地震和非震资料相结合的方法,开展了山前带构造建模研究与构造解析。通过研究,确定了研究区发育NW和近WE向两组断层和盆缘逆冲、盆内逆冲、盆内挤压走滑等3类断裂体系,平面上具有分区、分带性;建立了盆缘、盆内不同构造变形机制的构造解释模型;共识别出了挤压、伸展和走滑等3大类8种构造样式,明确了构造样式组合模式及其分布规律,理清了研究区“南北分带、东西分区”的构造变形特征;南西北东向构造演化剖面分析明确了盆缘、盆内推覆构造与盆内反冲构造后展式演化时序及其对中生界残留分布的控制作用。     

塔里木盆地巴楚隆起北缘吐木休克弧形基底卷入斜向滑移构造

石油地震资料揭示塔里木盆地中央巴楚隆起为结晶基底和古生代地层相对隆升区,地表为第四纪陆相碎屑岩不整合覆盖,隐伏隆起大部分区域缺失中、新生界。在隆起南北两侧构造变形比较强烈,均发育基底卷入的逆冲构造和古生界内逆冲构造。根据钻井资料和二维地震测线详细的构造解释,应用断层相关褶皱理论得知：吐木休克基底卷入逆冲断层是在中生界早期形成的基底卷入楔形构造的基础上,在新生界晚期再次活动形成的;新生代晚期中亚地区强烈陆内变形,导致塔里木盆地先期形成的巴楚隆起再次挤压隆升;晚期变形过程中,先存构造与形成新构造挤压方向的偏差导致新构造发育有走滑分量,形成典型的斜向挤压构造——吐木休克旋转弧形构造。平面分布上,弧形构造东西向延伸的中段和北东向延伸的西段,早期为基底卷入楔形构造,晚期发育基底卷入逆冲构造;近北西向延伸的东段,晚期发育基底卷入楔形构造叠加在早期基底卷入楔形构造之上,说明该构造至少经历了两期变形。由于晚期基底卷入逆冲断层具有走滑分量,导致盖层单斜构造发育3类应变带及相应构造：拉伸变形带发育的正断层、剪切变形带发育的走滑断层及挤压应变带即走滑构造分量;西段发育左行逆冲走滑断裂带及伸展变形;东段发育右行逆冲走滑断裂带。弧形构造西部发育的构造样式与2012年Keating等模拟的斜向断层位移形成的构造样式非常相似,说明弧形构造西段吐木休克基底卷入逆冲构造具有走滑分量,从而合理地解释了该区发育的构造样式及正断层形成机制。     

塔拉斯-费尔干纳断裂带南端构造转换及其新生代区域构造响应

塔拉斯费尔干纳断裂(TF)为中亚最大规模的断裂,其向南是否贯穿塔里木盆地西部研究较少,带来对其新生代运动性质的争论。研究表明,TF断裂在喀什凹陷以小规模的右旋走滑断裂逐渐消失,断层东盘以逆冲断层系的水平缩短变形,调节新生代右旋走滑位移,与巴楚隆起的阻挡作用相关。区域构造分析表明,随着帕米尔北缘逆冲断层系向北扩展,喀什凹陷中新生代沉积形成密集分布的线性褶皱和逆冲断层带。帕米尔高原向北仰冲触发TF不同区段在新生代差异性构造复活,发生大规模右旋位移及其南端构造转换(逆冲带隆升和前陆盆地发育)。新生代大断裂差异性复活及其构造调节,造成帕米尔构造节东西两侧不对称的构造样式。     

Formation and shortening deformation of a back-arc rift basin revealed by deep seismic profiling, central Japan

The northern Fossa Magna (NFM) basin is a Miocene rift system produced in the final stages of the opening of the Sea of Japan. It divides the major structure of Japan into two regions, with north-trending geological structures to the NE of the basin and EW trending structures to the west of the basin. The Itoigawa-Shizuoka Tectonic Line (ISTL) bounds the western part of the northern Fossa Magna and forms an active fault system that displays one of the largest slip rates (4–9 mm/year) in the Japanese islands. Deep seismic reflection and refraction/wide-angle reflection profiling were undertaken in 2002 across the northern part of ISTL in order to delineate structures in the crust, and the deep geometry of the active fault systems. The seismic images are interpreted based on the pattern of reflectors, the surface geology and velocities derived from refraction analysis. The 68-km-long seismic section suggests that the Miocene NFM basin was formed by an east dipping normal fault with a shallow flat segment to 6 km depth and a deeper ramp penetrating to 15 km depth. This low-angle normal fault originated as a comparatively shallow brittle/ductile detachment in a high thermal regime present in the Miocene. The NFM basin was filled by a thick (>6 km) accumulation of sediments. Shortening since the late Neogene is accommodated along NS to NE–SE trending thrust faults that previously accommodated extension and produce fault-related folds on their hanging wall. Based on our balanced geologic cross-section, the total amount of Miocene extension is ca. 42 km and the total amount of late Neogene to Quaternary shortening is ca. 23 km.     

龙门山断裂带印支期左旋走滑运动及其大地构造成因

位于青藏高原东缘的龙门山构造呈北东—南西向将松潘—甘孜褶皱带和华南地块分割开。前者主要是由一套巨厚的三叠纪复理石沉积组成 ,分布在古特提斯海的东缘。后者由前寒武纪基底和上覆的古生代和中生代沉积盖层组成。位于汶川—茂汶断裂以东的前龙门山存在一系列倾向北西的逆掩断层 ,它们将许多由元古宙和古生代岩层组成的断片向南东置于四川盆地的中生代红层之上 ,构成典型的薄皮构造。许多研究由此断定松潘—甘孜褶皱带和四川盆地之间在中生代发生过大规模的北西—南东向挤压。然而 ,汶川—茂汶断裂西侧的松潘—甘孜褶皱带内部的挤压构造线大多是垂直于而不是平形于龙门山断裂带 ,这表明当时的挤压应力不是北西—南东向而是北东—南西向。近年来在龙门山构造带内发现 ,在三叠纪时龙门山断裂带在发生推覆的同时还经历过大规模的北东—南西向的左旋走滑运动 ,协调走滑运动的主要构造为汶川—茂汶断裂。走滑运动的成因与松潘—甘孜褶皱带北东—南西向缩短有关。汶川—茂汶断裂的左旋走滑在龙门山的北东端被古特提斯海沿勉略俯冲带的消减和发生在大巴山的古生代 /中生代岩层的褶皱和冲断作用所吸收 ,在龙门山的南西端被古特提斯海沿甘孜—理塘俯冲带的消减和松潘—甘孜三叠纪复理石的褶皱和冲断作用所吸?     

四川盆地川中地区走滑断裂的分布、类型与成因

近期研究发现四川克拉通盆地内存在大型走滑断裂带,是断控油气藏勘探开发的有利新领域,走滑断裂的分布与成因对油气目标评价具有重要意义。本文在三维结合二维地震资料解释的基础上,分析走滑断裂的分布与成因类型,并探讨走滑断裂的形成机制。结果表明,川中三维地震工区发育北西向走向为主的大型板内走滑断裂系统;走滑断裂呈雁列、斜列的不连续的带状分布,断裂发育成熟度低,具有断裂样式的多样性与分层分布的差异性;四川盆地存在川中克拉通内走滑断层、川东南帚状走滑构造、川东调节走滑带、川东北楔入走滑带、川西北斜向冲断走滑带等5个地区发育5种类型走滑断裂带;走滑断裂形成于震旦系灯影组沉积晚期,受控于原特提斯洋俯冲背景下的斜向伸展作用,基底北西向先存断裂构造复活,形成了调节斜向伸展裂陷槽的川中板内走滑断裂系统。结果揭示克拉通盆地可能发育大型的板内走滑断裂系统,不同于常规的板缘与板内调节走滑断裂系统。     

Segmentation and inversion of the Hangjinqi fault zone,the northern Ordos basin (North China)

This paper deals with the segmentation and inversion of the Hangjinqi fault zone (HFZ), which is the dominant structure in the northern part of the Ordos basin in North China. HFZ was reactivated during the Late Triassic and obliquely inverted during the Middle Jurassic shortening. Subsurface geological mapping and structural analysis were carried out to determine the segmentation and kinematic history of the deformation. The HFZ was a left-stepping fault zone and was made up of three segments: the Porjianghaizi fault (PF), Wulanjilinmiao fault (WF) and Sanyanjing fault (SF), which are separated by two relay ramps. Two distinct phases can be identified in its structural evolution: (1) during the Late Triassic compressional deformation, the HFZ was characterized by shortening and thrusting to the north; and (2) During the Middle Jurassic phase the HFZ was oblique to the extensional fault trends, the reverse faults were reactivated as dextral strike-slip faults as a result of transtensional inversion. The inversion ratio of the HFZ indicates an increase in deformational degree from east to west over the whole region. The first deformation stage resulted from the N–S compression between the South China and North China plates during the Late Triassic. The second deformation stage of compression was related to the west-northwestward subduction of the paleo-Pacific plate during the Middle Jurassic. In the Jurassic deformation framework, the HFZ may be interpreted as an accommodation structure parallel to the Yanshan–Yinshan orogenic belt developed in the northern Ordos area.     

辽东湾北部地区走滑构造特征与油气富集规律

辽东湾北部地区右行走滑构造特征较为典型,主要表现为:沿走滑断裂带发育雁行式伸展断裂;剖面上发育花状构造;走滑断裂沿走向呈“S”型或反“S”型波状弯曲;沿走滑断裂带断槽与断鼻构造相间分布。分析认为,渐新世晚期,辽东湾北部地区南北向拉张、东西向挤压的区域应力场控制了右行走滑构造的形成,断槽与断鼻构造相间分布是由于沿走滑断裂带局部应力场性质发生改变所致。右行走滑断裂的“S”型弯曲部位为增压弯部位,走滑断裂两侧断块在此汇聚,地层因应力集中而形成断鼻构造;右行走滑断裂的反“S”型弯曲部位为释拉张部位,走滑断裂两侧断块在此离散,地层因拉张而发生断陷形成断槽。受走滑构造所控制,油气沿走滑断层自断槽向断鼻方向运移、聚集而成藏。研究走滑构造发育特征,对于预测圈闭分布以和研究油气富集规律具有重要意义。     

The Variscan tectonic inheritance of the Upper Rhine Graben: evidence of reactivations in the Lias,Late Eocene–Oligocene up to the recent

Processing of gravity and magnetic maps shows that the basement of the Upper Rhine Graben area is characterized by a series of NE–SW trending discontinuities and elongated structures, identified in outcrops in the Vosges, Black Forest, and the Odenwald Mountains. They form a 40 km wide, N30–40° striking, sinistral wrench-zone that, in the Visean, shifted the Variscan and pre-Variscan structures by at least 43 km to the NE. Wrenching was associated with emplacement of several generations of plutonic bodies emplaced in the time range 340–325 Ma. The sub-vertical, NE–SW trending discontinuities in the basement acted as zones of weakness, susceptible to reactivation by subsequent tectonism. The first reactivation, marked by mineralizations and palaeomagnetic overprinting along NE–SW faults of the Vosges Mountains, results from the Liassic NW–SE extension contemporaneous with the break-up of Pangea. The major reactivation occurred during the Late Eocene N–S compression and the Early-Middle Oligocene E–W extension. The NE–SW striking basement discontinuities were successively reactivated as sinistral strike-slip faults, and as oblique normal faults. Elongated depocenters appear to form in association with reactivated Variscan wrench faults. Some of the recent earthquakes are located on NE–SW striking Variscan fault zones, and show sinistral strike-slip focal mechanisms with the same direction, suggesting also present reactivation.     

深大断裂对松辽断陷盆地群南部的控制作用

通过野外地质调查及对各断陷典型地震剖面和构造发育史剖面的综合研究,系统探讨了研究区深大断裂对断陷盆地群的控制作用。以西拉木伦河-长春-延吉板块拼接带、赤峰-开原超岩石圈断裂为边界,将研究区自南向北分为辽西盆地区、辽北盆地区和吉西盆地区等3个一级构造分区;根据控盆断裂及其断陷盆地群的时空分布、断陷构造样式、不同时期伸展量等特征将辽北盆地区分为西部、中西部、中东部等3个二级断陷区。西拉木伦河断裂控制了西部区断陷的形成和分布;嫩江—八里罕断裂和孙吴—大庆—阜新断裂对中西部断陷区的控盆效应大体相近;孙吴—大庆—阜新断裂与佳木斯—伊通断裂共同对中东部断陷区起着重要的控制作用;昌图断陷主要受佳木斯—伊通断裂所控制。辽北盆地区主要表现为双断式地堑,断陷群的形成和分布不仅受北北东向断裂控制,也受到近东西向的西拉木伦河断裂和赤峰—开原断裂重新活动的控制。中西部断陷区伸展率具有从九佛堂组沉积期—沙海组沉积期—阜新组沉积期依次减小的变化规律。中东部断陷区与中西部断陷区存在明显差异,NNE向与近EW向深大断裂对两区构造分区控制程度不同。     

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。