权家河煤矿褶皱构造发育特征

系统分析了权家河煤矿不同规模褶皱构造的形态特征、组合方式和展布规律,探讨了造就褶皱构造发育特征的地质条件及其演化过程。从而为指导权家河煤矿生产和揭开渭北煤田地质构造发育规律的面纱提供了依据。      

博格达山地区二叠纪以来构造应力场解析及地质意义

博格达山是现代地质学研究的一个热点,但是大部分研究都集中在博格达何时隆升,对于其构造应力场的研究较少。作者通过对博格达山地区不同时代地层中岩墙、节理、褶皱和断层等构造进行分期配套以及构造要素测量分析,认为二叠纪以来博格达山及周缘地区具有较强构造变形,构造应力场可划分为3期:二叠纪末期最大主压应力方向为北西西向,可能与后碰撞伸展作用和乌拉尔碰撞带向东挤压的远程效应有关;侏罗纪末-早白垩世最大主压应力为近南北向,与欧亚板块和拉萨地块的碰撞有关;新近纪以来由于印度板块与欧亚板块相互碰撞的远程效应,博格达山地区最大主应力方向为NNE-NE向。这些结果表明,博格达山具有多期次的构造运动,主要受欧亚板块南缘不同时期小陆块碰撞的控制,并且这些构造应力场对周缘盆地油气成藏具有一定影响。     

前陆冲断带复杂构造解析与建模——以准噶尔盆地南缘第一排背斜带为例

构造解析应从构造的变形机制、变形过程、变形量和变形时间四个方面入手,合理的构造解释方案是构造解析的基础,论文将等倾角区划分和轴面分析等几何学方法应用到地震解释中,从以上4个方面对准噶尔盆地南缘第一排背斜带做了系统的构造解析。地层结构揭示第一排背斜带深部发育楔状构造,楔状构造由5个古生界—中生界组成的断层转折褶皱叠加而成,是潜在的勘探目标群。在构造楔沿侏罗系西山窑组煤层向北扩展过程中,台阶状逆断层的大部分位移量沿构造楔顶部的反冲断层向南消减,另一部分位移量则沿西山窑组煤层向北传递至第二排背斜带,在总位移量保持稳定的前提下,第一排背斜带和第二排背斜带在走向上的此消彼长,反映位移量在南、北两个方向上的转换。     

湖南炎陵印支期隔槽式褶皱形成机制

为查明湘东南印支期褶皱特征及形成机制,对炎陵地区进行了详细的地质填图和野外观察。调查表明,泥盆纪跳马涧组与前泥盆纪褶皱基底间不整合界面在空间上组成背、向斜,表明褶皱基底参与了印支期褶皱作用。平面上,向斜出露宽度及延伸规模明显较背斜小,向斜转折端表现清楚且狭窄尖长,而背斜转折端没有清楚显示;剖面上,不整合界面靠近向斜核部产状陡,向两翼方向迅速变缓。反映出背斜平缓开阔、向斜紧闭狭窄且侧翼呈上拱尖棱状的隔槽式褶皱特征。印支期褶皱呈北北东向,横跨在前泥盆纪褶皱基底中加里东期北西向褶皱之上,但未对加里东期褶皱造成明显地叠加改造效应,说明前泥盆纪地层在印支运动中没有发生明显地弯滑褶皱作用。露头显示,褶皱过程中盖层未沿不整合界面产生明显滑脱。因此,认为炎陵地区隔槽式褶皱形成于基底(厚皮式)横向收缩与压扁作用,并从理论上论证了其隔槽式褶皱不可能是盖层沿基底滑脱的产物,纠正了前人的薄皮式观点。     

新疆独山子山前活断层和活褶皱及古地震研究

本文初步研究了新疆独山子山前活断层、活褶皱构造。这些表层构造有着不同性质的地表变形,是多次古地震活动的反映。文中将这些古地震遗迹分为四期,并计算了该断层带的地震复发周期和平均位移速率。     

Parasitic folds with wrong vergence: How pre-existing geometrical asymmetries can be inherited during multilayer buckle folding

Parasitic folds are typical structures in geological multilayer folds; they are characterized by a small wavelength and are situated within folds with larger wavelength. Parasitic folds exhibit a characteristic asymmetry (or vergence) reflecting their structural relationship to the larger-scale fold. Here we investigate if a pre-existing geometrical asymmetry (e.g., from sedimentary structures or folds from a previous tectonic event) can be inherited during buckle folding to form parasitic folds with wrong vergence. We conduct 2D finite-element simulations of multilayer folding using Newtonian materials. The applied model setup comprises a thin layer exhibiting the pre-existing geometrical asymmetry sandwiched between two thicker layers, all intercalated with a lower-viscosity matrix and subjected to layer-parallel shortening. When the two outer thick layers buckle and amplify, two processes work against the asymmetry: layer-perpendicular flattening between the two thick layers and the rotational component of flexural flow folding. Both processes promote de-amplification and unfolding of the pre-existing asymmetry. We discuss how the efficiency of de-amplification is controlled by the larger-scale fold amplification and conclude that pre-existing asymmetries that are open and/or exhibit low amplitude are prone to de-amplification and may disappear during buckling of the multilayer system. Large-amplitude and/or tight to isoclinal folds may be inherited and develop type 3 fold interference patterns.     

An alternative interpretation for the formation of doubly plunging folds in sandstone terrains

Folds are marvellous features of mountain terrains, but despite extensive research, many fundamental problems have still not been solved. In terrains of sandstone, fold hinges are rarely straight lines but curved, forming a pattern characterized by doubly plunging, elliptical dome‐and‐basin structures. Such structures are an obvious manifestation of coeval or successive shortening deformation in two orthogonal principal directions in the horizontal plane. Based on an anatomic investigation of the fold pattern of sandstone beds at the rocky beaches of Saint‐Jean‐Port‐Joli (Quebec, Canada), we propose that the doubly plunging folds may result from a transition from a plane deformation to a constrictional deformation due to auxetic effects of quartz‐rich rocks. The sandstone beds possessed potentially such negative values of Poisson's ratio that, when placed under compression in one direction, they become contracted in the transverse direction, producing a series of doubly plunging folds. Further work is needed to approve or disapprove the interpretation.     

The glaciotectonic deformation of Quaternary sediments by fault-propagation folding

Fault-propagation folding is an important yet seldom recognised structural style within sediments affected by glacier-induced deformation. Fault-propagation folds develop in the hanging wall of low angle thrust faults and compensate part of the slip along the fault. Field examples are recognised across northern Europe, in glaciotectonic complexes of north Germany, Wales and the Isle of Man. The recognition of the fault-propagation fold mechanism in glaciotectonic deformation is important because resultant structures are related to exactly the same phase of deformation (i.e. the same phase of ice advance), and thus play a critical role in analyses of the temporal and spatial evolution of glacier-induced deformation. Some field examples show monoclinal geometries that are in good agreement with predictions of trishear kinematic theory. The trishear approach is appropriate to model these structures because the structures analysed in the field and simulated below show characteristics that are compatible with fault-propagation folds that were produced by trishear kinematics. The curved forelimb and the monocline geometry of the fault-propagation folds fit to the trishear model. The occurrence of footwall synclines is also in good agreement with trishear kinematics. These synclines show the typical thickening of the strata in the hinge. With respect to the modelling output, most important factors for the structural evolution of the fault-propagation folds is the ramp angle of the thrust, the position of the tip line and the propagation-to-slip ratio along the fault. This fits to observations made by previous studies at large scale fault-propagation folds in fold-and-thrust belts.     

Regional significance of kilometric-scale north-east vergent recumbent folds associated with east to south-east directed shear on the southern border of the Central Iberian Zone (Hornachos-Oliva region,Variscan belt,Iberian Peninsula)

On the southern border of the Central Iberian Zone there are two sectors with different styles of deformation. To the south-west, in the Hornachos sector, large-scale recumbent folds associated with ductile shearing can be seen. This shearing is characterized by a direction of movement parallel to the fold axes and can be correlated for 150 km along strike. The K-values of the strain ellipsoid range from 0.8 to 2.0. Stretching in the X direction, parallel to the recumbent fold axes, is more than 100%. To the north-east, in the Oliva sector, first-phase folds are upright and the strain intensity is lower than in the Hornachos sector. Metamorphic, geometric and kinematic considerations lead us to conclude that the shearing in the Hornachos sector is better explained as conjugate to a main shear zone along which the southern border of the Central Iberian Zone is moved onto the Ossa-Morena Zone. This main thrust is at present obliterated by a left-lateral extensional shear zone that affects a high pressure exotic unit located between the Central Iberian and the Ossa-Morena Zones. This high pressure unit constitutes a suture of the Variscan belt in the Iberian Peninsula.     

Recent Tectonic Structures in a Transect of the Central Betic Cordillera

—The Betic Cordillera has undergone recent Alpine deformations related to the Eurasian-African plate interaction boundary. Most of the present-day relief has been built up since Tortonian times, and is related to the development of folds and faults that are overprinted on older deformations, and some of the faults may be considered as out-of-sequence. The combination of geophysical and geological data makes it possible to determine the main features of the recent tectonic structures, or those recently active, in its central transect. The main fault is a crustal detachment that separates a footwall constituted by the Iberian Massif and a hanging wall formed by the rocks of the Betic Cordillera. While the footwall is practically undeformed, the hanging wall has been folded and faulted. The folds are mainly E-W to NE-SW and have larger sizes and higher related relieves towards the South. The reverse faults are mainly concentrated in the northern mountain front. However, normal faults affect the southern part of the Cordillera and are associated with the development of large asymmetrical basins such as the Granada Depression. In this setting, the slip along the crustal detachment is variable and should increase southwards. The model of the recent tectonics in the central transect of the Cordillera is compatible with the presence of an active subduction in the Alboran Sea, and contrasts notably with the setting of the eastern Betic Cordillera, mainly deformed by transcurrent faults.