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1.
构造运动是控制分支河流体系发育的重要因素之一,其对沉积体系的控制作用一直是研究的热点与难点。前人对挤压、拉张、走滑等类型的盆地均有研究,但在挤压盆地边缘的冲断带中,冲断带对于沉积体系的控制作用研究较少,特别是对冲断带中常发育的分支河流体系(冲积扇)。为研究逆冲作用对分支河流体系的控制作用,通过Google Earth提供的全球地貌影像结合数字高程模型(Digital Elevation Model,DEM)等数据对塔里木盆地西北缘柯坪地区发育的分支河流体系(Distributive Fluvial System,DFS)进行测量研究与沉积学解析,探究盆地边缘逆冲断裂带的DFS几何形态发育特征及影响因素。在研究区内识别DFS共256个。柯坪地区发育的分支河流体系延伸长度范围为0.26~24.58 km,DFS面积范围为0.044~221.987 km2,物源区面积变化范围为0.1~290 km2,DFS坡度范围为0.011~0.182。柯坪地区分支河流体系上发育的河道主要是辫状河,河道下切程度有明显差异。决定柯坪地区分支河流体系发育的主要影响因素有物源供给,气候水文以及构造背景。物源区大小与DFS规模呈正相关;气候通过降雨量与蒸发量来影响DFS发育特征;水文则通过流域分布来影响DFS发育,分布在研究区内柯坪河流域的DFS,发育规模远大于流域外的;构造作用控制沉积区分布、可容空间的大小、坡度等,影响着DFS的分布与发育。研究结果表明:构造作用作为主要因素影响着柯坪地区DFS的分布与发育。在柯坪逆冲带,构造作用通过控制推覆体逆冲高低来影响DFS的大小与坡度。物源区大小也受地层抬升程度控制,地层出露越多,物源区一般越大。将柯坪地区以构造特征分为三个区,每个构造区的DFS具有明显差异。逆冲山前区的物源区域大,DFS规模最大,以扇形为主,坡度低,下切程度低;逆冲前缘区的物源区域较小,DFS规模变小,以长条形为主,坡度增加,下切程度增加;走滑断层区受断层影响,物源区与DFS规模明显变小,以扇形为主,平均坡度最大,平均延伸距离最小,下切程度显著。 相似文献
2.
燕山承德地区晚侏罗世盆地充填记录及对盆缘构造作用的指示 总被引:12,自引:2,他引:10
承德地区滦平—承德和大杖子—新城子晚侏罗世沉积盆地带分别与丰宁—隆化逆冲带和尚义—平泉逆冲带相邻。盆地充填的土城子组在垂向上可划分出三个主要由辫状河冲积平原及辫状河三角洲沉积体系组成的盆地相。沉积物岩屑和砾石成分统计表明 ,滦平—承德盆地北缘岩屑岩性相在垂向上表现出三个基底变质岩岩屑向上增多的旋回 ,而滦平—承德盆地南缘及大杖子—新城子盆地则由碳酸盐岩和碎屑岩岩屑表现出三个向上增多的旋回。盆地沉积学特征表明 ,滦平—承德盆地南北边缘分别受控于尚义—平泉北缘和丰宁—隆化逆冲带 ,而大杖子—新城子盆地受控于尚义—平泉南缘逆冲带。如果承德断层发生了长距离逆冲推覆活动 ,其活动时间绝非土城子组同沉积期和之后 ,应该发生于髫髻山组沉积之后和土城子组沉积之前。盆地中三个岩屑岩性相旋回和盆地相旋回共同地反映了盆缘逆冲带三次抬升剥露过程 相似文献
3.
Middle Miocene (Sarmatian) convergence created the fold and thrust belt of the Eastern Carpathians of Romania, which subsequently experienced post-collisional crustal deformation combined with calc-alkaline and alkalic-basaltic volcanism in late Miocene–Quaternary time. This deformation led to the rise of the Cǎlimani–Gurghiu–Harghita volcanic mountains and to the subsidence of the N–S-oriented intramontane Borsec/Bilbor–Gheorgheni–Ciuc and Braşov pull-apart basins, and the E-oriented monocline-related Fǎgǎraş basin. The regional drainage network is the composite of:
- (1) Older E-, SE- and S-flowing rivers, which cross the Carpathians, radiate towards the foreland and were probably established during the Middle Miocene (Sarmatian) collision event.
(2) A more recent drainage system related to the contemporaneous development of the volcanoes and intramontaneous basins, which generally drains westward into the Transylvanian Basin since late Miocene time and has been capturing the older river system.
The older river drainage system has also been modified by Late Pliocene–Quaternary folding, thrusting and monoclinal tilting along the Pericarpathian orogenic front and by reactivated transverse high angle basement faults, which cross the Eastern Carpathian foreland. 相似文献
4.
Tomasz Salamon Tomasz Zieli&#x;ski 《Boreas: An International Journal of Quaternary Research》2019,48(3):695-712
In this paper, fluvial deposits of Middle Pleistocene age in the mountain‐foreland area of southern Poland (Eastern Sudetes and Western Carpathians) are studied in order to document the evolution of fluvial systems during the coldest stages of glacial periods when the Scandinavian Ice Sheet advanced far to the south. The focus is on fluvial response to climate change and glacial impact on river system behaviour. Also considered is the tectonic uplift of the mountain part of river catchments and its potential influence on the style of fluvial sedimentation in the fore‐mountain area. Three drainage basins that were active during the Elsterian and Saalian glaciations are investigated. Facies analyses are carried out on thick successions of braided river deposits covered with till or glaciolacustrine sediments, which result in a reconstruction of the fluvial activity synchronous with the ice‐sheet advance. The results suggest that fluvial activity declined prior to ice‐sheet advance into the fore‐mountain area. This climatically induced change is directly recorded in alluvial successions by upward‐decreasing bed thicknesses and grain sizes. River longitudinal profiles were shortened in front of the advancing ice sheet. The base level of the studied rivers, created by the ice‐sheet margin, rose in parallel with glacial advance. As a result, the successive reaches of rivers (degradational, transitional, aggradational) underwent shortening and moved upstream within the catchments. Moreover, tectonically induced local increases of river slopes may have influenced the depositional processes. 相似文献
5.
A foreland basin succession has been identified in the Frasnian of the Central Pyrenees. This succession comprises a carbonate-dominated transgressive system which recorded the cratonward migration of the foreland basin subsidence, and siliciclastic depocenters which recorded the progression of the thrust-fold deformation. The foreland basin system has always been maintained in deep-marine environments, i.e., at an underfilled depositional state. It was associated with a thrust wedge which descended toward a deep-marine hinterland, i.e., with a type of orogenic wedge usually related to subduction zones. The Frasnian foreland basin system differs from the one known in the Carboniferous which evolved to overfilled depositional state and was associated with a thrust wedge rising toward a mountainous hinterland. Consequently, the Hercynian orogeny in the Pyrenees seems to result first, from a Frasnian thrusting controlled by a subduction zone located north of the Pyrenees, and second, from a Carboniferous thrusting controlled by the surrection of a frontal thrust belt in the Pyrenees. The association of underfilled foreland basin systems and hinterland-dipping thrust wedges, as exemplified in the Frasnian of the Pyrenees, can be interpreted as illustrative of the initial stages of thrust-wedge growth in deep-marine settings. 相似文献
6.
The Indian subcontinent comprises accreted cratonic fragments that underwent subsequent rifting–subduction–collision processes along major mobile belts. It is also a storehouse of a prolonged history of crustal evolution involving repeated episodes of magmatism, volcanism, sedimentation, and metamorphism, and the formation of intracratonic and foreland basins. The geologic–geomorphic evolution of the Peninsula is recorded in relic faults/suture zones that confine Paleozoic, Mesozoic, and Cenozoic sedimentary basins and landforms. In addition, escarpments, plateaus, waterfalls, deltas, planation surfaces, and strandlines are either aligned parallel and/or formed over them. Asymmetric relief across the western–eastern parts of the Peninsula, orographic effect on the precipitation pattern and climatic zones provide important constrains on the geologic and geomorphic evolution of the region. Though extensive continental and coastal deposition occurred during Permo-Triassic and Early Cretaceous, only the downwarped grabens of Gondwana basins preserved the sedimentary records. Occurrences of extensive Cenozoic deposits offshore and Neogene–Holocene deltaic deposits along the entire east coast as opposed to the absence of comparable deltaic sequences in the west coast are linked to intense and recurrent episodes of denudation indicating first-order control of basement structures over landscape evolution.Inheritance and continuum of basement structures over climate, and landscape evolution of Peninsular India can also be witnessed by the unique and diverse drainage patterns of major rivers. While most of the major rivers follow a general easterly direction, the landscape morphology of their catchments indicates youthful character and tectonically active nature. The east flowing rivers show an asymmetry between the areal extents of drainage basin size and delta, whereas the west-flowing rivers are short and straight and their catchments are miniscule in comparison with the rivers flowing toward east. The Western Ghats Escarpment forms an orographic barrier and acts as the main divide between these two drainage systems. There is a disparity between the quanta of sediment discharge as well. In addition, the eastern and western parts of India, across the Western Ghats Escarpment, show significant differences in terms of climatic zones (humid to per-humid on the west while it is arid to subhumid on the east). The west coast is characterized by > 3000 mm/year annual rainfall, that often reaches > 5000 mm/year, dominance of SW monsoon winds, occurrence of narrow (< 60 km), rocky, crenulated and coastal cliffs and pocket beaches, and net southerly long shore sediment transport. In contrast, the east coast is characterized by several hundred kilometers wide deltaic low lands built by major rivers. These rivers show trellis to dendritic stream patterns and follow major basement faults that are associated with geologic–historic–recent seismic activity. The sedimentary basins and delta heads, strandlines, and active delta lobes whose western boundary is always limited by basement faults have shown activity since the formation of the Gondwanan supercontinent. The eastern coastal region is also different from the west in terms of active NE monsoon, long shore sediment transport (toward north), and the formation of extensive lagoon-beach barrier systems since Neogene that in turn continue to occur until recent.Here we propose a conceptual tectono-geomorphic model demonstrating the inheritance and continuum of Gondwanan structural trends on the transient landscape of Peninsular India. 相似文献
7.
Middle Miocene to Pliocene sedimentation on the NW Borneo margin has been interpreted as the product of one relatively large deltaic system, the Champion Delta. However, several lines of evidence indicate that the Champion system was not a simple, large delta; its drainage basin was too small, fluvial outcrops indicate multiple, relatively small rivers and outcrop studies indicate the same facies associations as the diverse, modern depositional systems. The number and location of rivers reaching the shoreline changed as rapidly subsiding footwall synclines, episodically active inversion anticlines and growth faults created an evolving structurally-generated topography that not only controlled drainage pathways, but also segregated Champion strata into thick, wave-dominant and tide-dominant successions. Although the principal rivers within the Champion system, the Limbang, Padas and Trusan Rivers, transport significant loads of coarse sediment, the intermittent proximal ponding of sand in local basins, as is currently occurring in Brunei Bay, resulted in a variable delivery of sand to the shelf edge. The number and distribution of shelf edge canyons also changed with time. Consequently, the spatial and temporal distribution of deepwater sand accumulations sourced from the Champion system are not solely related to relative sea level fluctuations; such accumulations should be smaller and more scattered than those sourced from a large shelf edge delta. Because the catchments of the Champion system’s principal rivers represent different provenances, the system’s deepwater sands may carry the signal of specific rivers. For example, mineralogical contrasts between in the main reservoir sands of the deepwater Gumusut and Kikeh fields suggest that the relative contributions of the principal rivers shifted with time with the Trusan and Limbang Rivers dominating sand supply for the youngest reservoirs at Gumusut. 相似文献
8.
Climatic versus halokinetic control on sedimentation in a dryland fluvial succession 总被引:1,自引:1,他引:0
Fluvial systems and their preserved stratigraphic expression as the fill of evolving basins are controlled by multiple factors, which can vary both spatially and temporally, including prevailing climate, sediment provenance, localized changes in the rates of creation and infill of accommodation in response to subsidence, and diversion by surface topographic features. In basins that develop in response to halokinesis, mobilized salt tends to be displaced by sediment loading to create a series of rapidly subsiding mini‐basins, each separated by growing salt walls. The style and pattern of fluvial sedimentation governs the rate at which accommodation becomes filled, whereas the rate of growth of basin‐bounding salt walls governs whether an emergent surface topography will develop that has the potential to divert and modify fluvial drainage pathways and thereby dictate the resultant fluvial stratigraphic architecture. Discerning the relative roles played by halokinesis and other factors, such as climate‐driven variations in the rate and style of sediment supply, is far from straightforward. Diverse stratigraphic architectures present in temporally equivalent, neighbouring salt‐walled mini‐basins demonstrate the effectiveness of topographically elevated salt walls as agents that partition and guide fluvial pathways, and thereby control the loci of accumulation of fluvial successions in evolving mini‐basins: drainage pathways can be focused into a single mini‐basin to preserve a sand‐prone fill style, whilst leaving adjoining basins relatively sand‐starved. By contrast, over the evolutionary history of a suite of salt‐walled mini‐basins, region‐wide changes in fluvial style can be shown to have been driven by changes in palaeoclimate and sediment‐delivery style. The Triassic Moenkopi Formation of the south‐western USA represents the preserved expression of a dryland fluvial system that accumulated across a broad, low‐relief alluvial plain, in a regressive continental to paralic setting. Within south‐eastern Utah, the Moenkopi Formation accumulated in a series of actively subsiding salt‐walled mini‐basins, ongoing evolution of which exerted a significant control on the style of drainage and resultant pattern of stratigraphic accumulation. Drainage pathways developed axial (parallel) to salt walls, resulting in compartmentalized accumulation of strata whereby neighbouring mini‐basins record significant variations in sedimentary style at the same stratigraphic level. Despite the complexities created by halokinetic controls, the signature of climate‐driven sediment delivery can be deciphered from the preserved succession by comparison with the stratigraphic expression of part of the system that accumulated beyond the influence of halokinesis, and this approach can be used to demonstrate regional variations in climate‐controlled styles of sediment delivery. 相似文献
9.
构造活动盆地沉积层序形成过程模拟——以断陷和前陆盆地为例 总被引:5,自引:1,他引:4
应用二维层序地层模拟系统开展了构造活动盆地沉积层序的形成过程的动态模拟分析,揭示了同沉积断裂活动、湖平面变化及沉积物供给量变化相互作用对沉积层序形成的控制作用。模拟表明,快速的构造沉降、相对高的湖平面和大量的沉积物供给是形成相对深水扇三角洲的必要条件;而沉积物的供给量变小或构造沉降量加大时有利于形成近岸湖底扇或水下扇。模拟揭示出断陷湖盆陡坡边缘断裂形成的古地貌坡折控制着低水位域浊积扇或湖底扇的发育部位,同时对水进或高位域的三角洲前缘的沉积中心的分布具控制作用。断裂坡折带的构造沉降是控制可容纳空间变化的关键因素。在陆内前陆逆冲构造边缘,层序发育早期(底部)发育冲积扇和河流沉积,但由于相对快的构造沉降形成水进序列;在快速沉降的晚期沉降速率减小,碎屑体系向盆地方向推进,形成广泛河流三角洲沉积。由隐伏逆冲断裂形成的构造坡折带对低位域的分布具控制作用。在构造坡折带下的低位域砂体与上覆的水进域泥岩组合可形成重要的地层油气藏。 相似文献
10.
沙井子构造带位于塔里木盆地西北缘,是分隔阿瓦提凹陷和温宿凸起的边界断裂。它是塔里木盆地研究最薄弱的大型断裂构造带之一。根据系统、精细的地震资料解释,沙井子构造带存在3套断裂体系:深部楔状冲断构造、狭义沙井子断裂和浅部的伸张构造。深部楔状冲断构造形成于志留纪—泥盆纪,由北西倾向的主冲断层和南东倾向的反冲断层形成构造楔; 构造楔主要由前寒武纪变质岩组成,冲断前锋楔入于寒武系中部,造成上覆地层向温宿凸起方向的急剧抬升。狭义的沙井子断裂,即通常所说的沙井子断裂,为一条高角度基底卷入型挤压走滑断裂,形成于二叠纪末—三叠纪初,错断了早期的深部冲断楔。浅部的伸展构造形成于第四纪早-中期,为一系列较小规模的正断层,沿狭义沙井子断裂呈右步雁列状排列,构成左行剪切张扭性断裂带。深部的楔状冲断构造和浅部的伸展构造是本次研究的新发现。 相似文献
11.
祁连山北缘冲断带西段构造特征 总被引:6,自引:0,他引:6
祁连山北缘冲断带是中国较早发现油田的地区之一,近几年来该区油气勘探又获得进一步突破。文中根据近几年得到的地震、钻井、地面露头资料,结合前人研究成果,分析了祁连山北缘冲断带西段的构造特征。祁连山北缘冲断带具有中国西部山前冲断带的共同特征:构造主要定型于喜山期;断层相关褶皱、冲断构造体系发育;冲断带分段分带明显;构造复杂。除此之外,祁连山北缘冲断带西段也有独特的构造特征。由于不同性质盆地的叠合,冲断带走向方向地层组成变化大;冲断带的分段性受控于古构造格局;主要发育横向叠置的多重冲断构造体系。这些特征造成了北缘冲断带油气勘探的复杂性。 相似文献
12.
Deepwater fold and thrust belt classification,tectonics, structure and hydrocarbon prospectivity: A review 总被引:1,自引:0,他引:1
Deepwater fold and thrust belts (DWFTBs) are classified into near-field stress-driven Type 1 systems confined to the sedimentary section, and Type 2 systems deformed by either far-field stresses alone, or mixed near- and far-field stresses. DWFTBs can occur at all stages of the Wilson cycle up to early stage continent continent collision. Type 1 systems have either weak shale or salt detachments, they occur predominantly on passive margins but can also be found in convergent-related areas such as the Mediterranean and N. Borneo. Examples include the Niger and Nile deltas, the west coast of Africa, and the Gulf of Mexico. Type 2 systems are subdivided on a tectonic setting basis into continent convergence zones and active margin DWFTBs. Continent convergence zones cover DWFTBs developed during continent–arc or continent–continent collision, and those in a deepwater intracontinental setting (e.g. W. Sulawesi, Makassar Straits). Active margins include accretionary prisms and transform margins. The greatest variability in DWFTB structural style occurs between salt and shale detachments, and not between tectonic settings. Changes in fold amplitude and wavelength appear to be more related to thickness of the sedimentary section than to DWFTB type. In comparison with shale, salt detachment DWFTBS display a lower critical wedge taper, more detachment folds, long and episodic duration of deformation and more variation in vergence. Structures unique to salt include canopies and nappes. Accretionary prisms also standout from other DWFTBs due to their relatively long, continuous duration, rapid offshore propagation of the thrust front, and large amount of shortening. In terms of petroleum systems, many similar issues affect all DWFTBs, these include: the oceanward decrease in heat flow, offshore increase in age of mature source rock, and causes of trap failure (e.g. leaky oblique and frontal thrust faults, breach of top seal by fluid pipes). One major difference between Type 1 and Type 2 systems is reservoir rock. High quality, continent-derived, quartz-rich sandstones are generally prevalent in Type 1 systems. More diagenetically reactive minerals derived from igneous and ophiolitic sources are commonly present in Type 2 systems, or many are simply poor in well-developed turbidite sandstone units. However, some Type 2 systems, particularly those adjacent to active orogenic belts are partially sourced by high quality continent-derived sandstones (e.g. NW Borneo, S. Caspian Sea, Columbus Basin). In some cases very high rates of deposition in accretionary prisms adjacent to orogenic belts, coupled with uplift due to collision, results in accretionary prism related fold belts that pass laterally from sub-aerial to deepwater conditions (e.g. S. Caspian Sea, Indo-Burma Ranges). The six major hydrocarbon producing regions of DWFTBs worldwide (Gulf of Mexico, Niger Delta, NW Borneo, Brazil, West Africa, S. Caspian Sea) stand out as differing from most other DWFTBs in certain fundamental ways, particularly the very large volume of sediment deposited in the basins, and/or the great thickness and extent of salt or overpressured shale sdetachments. 相似文献
13.
西北干旱区第四纪盆地主要是在中、新生代盆地基础上发展而成,一般可分为前山带山间断拗盆地和山前断拗盆地两大类,前者规模较小,后者规模较大,居主导地位。盆地构造形式大部分为单斜式不对称盆地,又可划分为单列型单斜式盆地和多列型单斜式盆地,包括部分地下隐伏盆地,形成盆地系统。盆地构造主要受区域深大断裂和新构造作用控制,具有明显的方向性和规律性。每条河流一般要流经2~3个盆地,形成由盆地系统构成的一个统一的水文系统。全流域的水循环系统和水资源系统,均受盆地系统的制约。因此,研究干旱区第四纪盆地系统,对合理开发利用水资源具有重要意义。 相似文献
14.
The closure of the western part of the Neotethys Ocean started in late Early Jurassic. The Middle to early Late Jurassic contraction
is documented in the Berchtesgaden Alps by the migration of trench-like basins formed in front of a propagating thrust belt.
Due to ophiolite obduction these basins propagated from the outer shelf area (=Hallstatt realm) to the interior continent
(=Hauptdolomit/Dachstein platform realm). The basins were separated by nappe fronts forming structural highs. This scenario
mirrors syn-orogenic erosion and deposition in an evolving thrust belt. Active basin formation and nappe thrusting ended around
the Oxfordian/Kimmeridgian boundary, followed by the onset of carbonate platforms on structural highs. Starved basins remained
between the platforms. Rapid deepening around the Early/Late Tithonian boundary was induced by extension due to mountain uplift
and resulted in the reconfiguration of the platforms and basins. Erosion of the uplifted nappe stack including obducted ophiolites
resulted in increased sediment supply into the basins and final drowning and demise of the platforms in the Berriasian. The
remaining Early Cretaceous foreland basins were filled up by sediments including siliciclastics. The described Jurassic to
Early Cretaceous history of the Northern Calcareous Alps accords with the history of the Western Carpathians, the Dinarides,
and the Albanides, where (1) age dating of the metamorphic soles prove late Early to Middle Jurassic inneroceanic thrusting
followed by late Middle to early Late Jurassic ophiolite obduction, (2) Kimmeridgian to Tithonian shallow-water platforms
formed on top of the obducted ophiolites, and (3) latest Jurassic to Early Cretaceous sediments show postorogenic character. 相似文献
15.
Claudio Corrado Lucente 《Sedimentary Geology》2004,170(3-4):107-134
The Marnoso–arenacea basin was a narrow, northwest–southeast trending, foredeep of Middle–Late Miocene age bounded to the southwest by the Apennine thrust front. The basin configuration and evolution were strongly controlled by tectonics.
Geometrical and sedimentological analysis of Serravallian turbidites deposited within the Marnoso–arenacea foredeep, combined with palaeocurrent data (turbidite flow provenance, reflection and deflection), identify topographic irregularities in a basin plain setting in the form of confined troughs (the more internal Mandrioli sub-basin and the external S. Sofia sub-basin) separated by an intrabasinal structural high. This basin configuration was generated by the propagation of a blind thrust striking northwest to southeast, parallel to the main trend of the Apennines thrust belt.
Ongoing thrust-induced sea bed deformation, marked by the emplacement of large submarine landslides, drove the evolution of the two sub-basins. In an early stage, the growth and lateral propagation of a fault-related anticline promoted the development of open foredeep sub-basins that were replaced progressively by wedge-top or piggy-back basins, partially or completely isolated from the main foredeep. Meanwhile, the depocenter shifted to a more external position and the sub-basins were incorporated within an accretionary thrust belt. 相似文献
16.
中国南天山西部冲断褶皱系前缘区的运动学特征 总被引:17,自引:0,他引:17
南天山冲断褶皱系是中-上新世以来形成的以薄皮滑脱为主的冲断构造,冲断作用导致了盆地内及周缘区古-新生界的碎屑岩和碳酸盐岩地层发主形变。本文对该冲断系前缘区 (巴音库鲁提北部至喀什地区 )的运动学特征进行了研究。南天山冲断褶皱系从平面上分出了六个冲断褶皱带。从剖面上划分出两种不同的冲断体系。冲断系的前锋为盲冲结构的构造三角带。冲断作用导致前锋区中新世以来层系变形、抬升并出露地表,本区有两个区域性的主滑脱面,冲断作用及断层相关褶皱的形成是冲断层沿主滑脱面向前陆方向逐渐推进的结果。同时发育的次级冲断层导致冲断褶皱带的复杂化。文章同时指出,南天山冲断褶皱系的冲断扩展顺序为逆序。这与塔里木盆地南缘西昆仑山前冲断带的活动方式相反,暗示着南天山构造带的运动学特征是独特的。利用平衡地质剖面的方法,在综合地质和地球物理资料的基础上,作出本区的构造横剖面图并进行了平衡恢复,从而得出南天山冲断褶皱系前缘区上新世以来的南北缩短率为30 %,缩短量为 5 0km,缩短速率为 9- 10mm/a。 相似文献
17.
祁连山北缘冲断带的特征与空间变化规律 总被引:3,自引:0,他引:3
祁连山北缘冲断带是中国西部一条十分重要的新生代冲断带,它的研究不仅对探讨青藏高原新生代隆升过程和板内造山作用具有重要的意义,而且对酒泉盆地南缘的油气勘探也具有重要的意义。在大量野外地质调查、地震资料解释和钻井资料分析的基础上,开展祁连山北缘冲断带的特征与空间变化规律研究。祁连山北缘冲断带具有多层次的逆冲结构,包括浅层的远距离冲断系统、中层的近距离冲断系统和深层的原地冲断系统,其中原地冲断系统又可划分为原地隐伏和原地显露冲断系统。冲断带变形特征自西向东可分为三段。酒泉盆地南缘的冲断带是一水平位移量较大的、沿着至少三个滑脱面由南而北产生收缩变形的薄皮冲断系统,原地隐伏冲断系统发育很宽。榆木山南缘—民乐盆地南缘西段的冲断带中发育较宽的原地显露冲断系统,而原地隐伏冲断系统较窄。民乐盆地南缘东段—武威盆地南缘发育宽度较大的原地显露冲断系统,由三叠系、石炭系—二叠系、奥陶系、寒武系和岩体组成的冲断片相互叠置,形成冲断带宽广的"显露式"前锋,原地隐伏系统不发育。祁连山北缘冲断带的变形量由西往东逐渐减小。酒西坳陷旱峡剖面构造缩短率为55.1%;民乐盆地魏拉达坂构造剖面缩短率最大为43.4%;武威盆地天桥沟—西马河构造剖面缩短率最大为40.4%。祁连山北缘冲断带西段的变形时期大致开始于9Ma,并以"前展式"向北扩张,变形时间向北变新,前锋断层开始活动时间约为8.3Ma。 相似文献
18.
The Amazonian lowlands of Peru are composed of the Subandean Zone (foreland), the Marañón Basin (foredeep) and the Iquitos Geanticline (Brazilian Craton). The Subandean Zone includes the Subandean Thrust and Fold Belt (STFB) to the west, which crops out mostly in the foothills, and the Subandean Tilted Block Zone (STBZ) to the east, which is principally exposed in the Amazonian lowlands of central Peru. The main trends of river belts are related to structural style. Main rivers in the STFB are antecedent, and secondary drainage is subsequent. In the STBZ, river basins are channelized, parallel to structural grain. The special asymmetric pattern of the Subandean drainage network depends on these two juxtaposed structural regions. As a result, fluvial migration in Peruvian lowlands is more controlled and limited by neotectonics than previously supposed. 相似文献
19.
Structural Traps in Detachment Folds: a Case Study from the ‘Comb- and Trough-like’ Deformation Zone/s, East Sichuan, China 总被引:1,自引:0,他引:1
WANG Zongxiu ZHANG Jin LI Tao ZHOU Xingui MA Zongjin TANG Liangjie XIAO Weifeng YAN Xili 《《地质学报》英文版》2012,86(4):828-841
Detachment structures occur widely in the crust, and it is the commonest and most important deformation type developed in the region between orogenic belts and basins. The ‘comb-like’ and ‘tough-like’ fold belts in eastern Sichuan are caused by multi-layer detachment. The duplex structure is the most important deformation style in the region, exhibiting different characteristics from typical detachment structures. Different deformation styles, scales, and shortenings resulting from independent deformations of various detachment systems would lead to the phenomenon whereby most of the topographical heights in the region do not correspond to the structural heights in depth. Based on systematic structural analysis and combined with practical oil/gas prospecting, four types of structural traps are described from eastern Sichuan Province, which are: detachment and thrust trap; detachment folding trap; fault-flat blocking trap; and detachment layer trap. Meticulous studies on the deformation and distribution of detachment layers in the eastern Sichuan Province will contribute to oil/gas prospecting and selection of potential regions of marine-origin oil/gas prospecting in South China. 相似文献
20.
Many mountain belts exhibit significant along‐strike variation in structural style with changes in the width of the orogen, the geometry and kinematics of the crustal‐scale thrust system, and the degree of partitioning between pro‐ and retro‐wedge deformations. Although the main factors controlling first‐order structural style are understood, the cause of these lateral variations remains to be resolved. Here we focus on the Pyrenees, characterized by significant lateral variation in structural style with a thrust system involving more and thinner thrust sheets in the eastern section than in the western part. Similarly, the prior Mesozoic rifting event was characterized by significant lateral variation in structure. We integrate available geological and geophysical data with forward lithospheric scale numerical models. We show that lateral variation in crustal strength attributed to inherited Variscan crustal composition accentuated during Mesozoic rifting explains the variation in structural style observed during Pyrenean mountain building. 相似文献