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1.
《International Geology Review》2012,54(11):1735-1743
According to this article, there has been no extensive thrusting in the May range. On the basis of a study of the internal structure of the Silurian formations, which are found to be a rootless "allochthon," it is suggested that Middle Paleozoic uplifts were formed with abbreviated sections. The edges of these uplifts have indeed been overthrust on younger rocks (Middle Devonian to Middle Carboniferous) and thus form the elements of an imbricate thrust, not a nappe structure. — Author.  相似文献   

2.
柯坪冲断带位于塔里木盆地的西北缘, 是南天山南缘冲断系统的一部分。根据野外实际考察和地震剖面解释, 总结了该冲断带的构造变形特征:发育于古生界、以寒武系膏盐层为主滑脱层、叠瓦状冲断、暴露式冲断前锋、断层传播褶皱、前展式冲断、形成于上新世-第四纪。根据平衡剖面的恢复, 柯坪冲断带的构造缩短量最小为29.1%~40.7%。   相似文献   

3.
滇西西盟一带是保山—掸邦地块在我国境内的一个基底岩系出露地区。该地区的前泥盆纪变质岩系可划分成两个构造层,下部为元古代构造层,由变质深度达角闪岩相的怕可杂岩系组成,发育3期南北向的变形构造;上部为早古生代构造层,由低绿片岩相变质的王雅组、允沟组组成,发育两期呈南北向的变形构造。变形构造表明,西盟变质岩系的主期构造格架以怕可—老街子背形叠瓦垛为主导构造要素,由背驮式扩展的向东逆冲的盲逆冲断裂系组成,王雅—允沟反冲叠瓦扇是盲逆冲断裂系的盖层响应变形系统,并以向西逆冲的推覆构造为特征  相似文献   

4.
Abstract

Collision of the Kohistan island arc with Asia at ~100 Ma resulted in N-S compression within the Neo-Tethys at a spreading center north of the Indo-Pakistani craton. Subsequent India-Asia convergence converted the Neo-Tethyan spreading center into a short-lived subduction zone. The hanging wall of the subduction zone became the Waziristan, Khost and Jalalabad igneous complexes. During the Santonian- Campanian (late Cretaceous), thrusting of the NW IndoPakistani craton beneath Albian oceanic crust and a Cenomanian volcano-sedimentary complex, generated an ophiolite-radiolarite belt. Ophiolite obduction resulted in tectonic loading and flexural subsidence of the NW Indian margin and sub-CCD deposition of shelf-derived olistostromes and turbidites in the foredeep. Campanian-Maastriehtian calci- clastic and siliciclastic sediment gravity flows derived from both margins filled the foredeep as a huge allochthon of Triassic-Jurassic rise and slope strata was thrust ahead of the ophiolites onto the Indo-Pakistani craton. Shallow to intermediate marine strata covered the foredeep during the late Maastrichtian. As ophiolite obduction neared completion during the Maastrichtian, the majority of India-Asia convergence was accommodated along the southern margin of Asia. During the Paleocene, India was thrust beneath a second allochthon that included open marine middle Maastrichtian colored mélange which represents the Asian Makran-Indus-Tsangpo accretionary prism. Latérites that formed on the eroded ophiolites and structurally higher colored mélange during the Paleocene wei’e unconformably overlapped by upper Paleocene and Middle Eocene shallow marine limestone and shale that delineate distinct episodes of Paleocene collisional and Early Eocene post-collisional deformation.  相似文献   

5.
The Periadriatic foredeep (Italy) was generated by Neogene downbending of the Adria Plate under the Apennine Chain. The basin is filled with Plio-Pleistocene siliciclastic turbidites. Its substratum consists of the carbonate succession of the southwestern Adria Plate margin. The influence of the basin’s morphology on sedimentation and subsequent tectonic evolution is investigated in the Abruzzo sector of the foredeep (Cellino Basin). The substratum is composed of Messinian evaporites that dip towards the Apennines (W). A NNW component along the depocentral axis is divided into four blocks with different depths. The substratum was also affected by a Messinian extensional fault system, not involving the overlying Pliocene sequence. This morphology controlled the distribution of the turbidites in the lower part of the Cellino Basin. The Plio-Pleistocene compressional deformation of the foredeep produced an inner complex structure (Internal Structure), involving the foredeep substratum and an outer imbricate thrust system (Coastal Structure), detached over the faulted Messinian evaporites. This thrust system is parallel to the extensional faults, suggesting a strong influence of the substratum morphology on the development of the compressional structures. The overall structural setting was validated with a balanced cross-section. Out-of-sequence thrusting and non-coeval deformation within each thrust sheet characterize the local tectonic history.  相似文献   

6.
In the Appalachian thrust belt in Alabama, thrust sheets of Paleozoic strata generally strike northeastward and are imbricated northwestward; four transverse zones cross the regional strike of the thrust belt. The large-scale Pell City thrust sheet ends southwestward at an oblique lateral ramp within the Harpersville transverse zone, where the leading edge of the thrust sheet (the Pell City fault) curves abruptly 55° counterclockwise. The northwest-striking segment of the Pell City fault conforms to the geometry of an oblique lateral ramp in the footwall. Furthermore, the Pell City fault cuts up section in the hanging wall southwestward toward the transverse zone, indicating a hanging-wall lateral ramp emplaced over the footwall oblique lateral ramp.In the hanging wall adjacent to the northwest-trending segment of the Pell City fault, a pervasive train of upright, isoclinal folds (with 50% apparent shortening) trends N15°W, oblique to the regional translation direction. The fold train is limited to the southwestern part of the Pell City thrust sheet; farther northeast, the regional northeasterly strike prevails. The isoclinal folds in the hanging wall indicate contractional crowding perpendicular to the footwall oblique lateral ramp.  相似文献   

7.
The Gavarnie nappe is a feature of the Tertiary Pyrenean orogen and is shown to consist of at least two thrust sheets of Palaeozoic rocks which are overlain by a southward-dipping sequence of Cretaceous and Eocene sediments, showing folded thrust structures. The Gavarnie nappe covers a basement and Mesozoic cover-rock sequence which is exposed in the tectonic windows of La Larri and the Troumouse Cirque. Here, previously unrecognized thrusts involving basement were responsible for folding the overlying Gavarnie nappe. These basement-involved thrusts climb up section westwards giving a westward lowering of the Gavarnie thrust along strike. The structural evolution of the Gavarnie nappe in a region extending from Heas in France to the Valle de Pineta in Spain can be explained in terms of a piggy-back thrusting sequence. On a regional scale, thrust-tectonic models may be used to explain the double vergence of the Pyrenean chain where early southward-directed thrusting was responsible for structures in the South Pyrenean zone. A later northward-directed back thrusting event, or rotation of southward-directed thrust sheets by the stacking of lower thrust horses, can explain the steepness of structures in the axial zone and the northward-verging North Pyrenean thrust zone. Both models suggest that prior to the Pyrenean orogeny, some of the Hercynian structures in the axial zone were flatter lying, and have been rotated to their present steepness during the Pyrenean orogeny.  相似文献   

8.
The Sivas Basin extends over a major crustal structure underlying the contact zone between the Tauride and Pontide belts. The Kirsehir block, a continental crustal element lying between the main belts, introduces a subordinate suture in front of the Pontides—the Inner Tauride suture. The junction of the two main sutures occurs between Hafikand Imranli. Four structural zones have been considered. The northern basement of the basin, which includes both the Kirsehir continental crust and thrust sheets of ophiolite and pelagic sediments, forms an imbricate stack with an Eocene cover. The Eocene cover shows two distinct sequences: marine neritic and continental basalts overlying the Kirsehir basement, and deltaic and basinal deposits lying to the southeast. Southward tectonic stacking of the entire pile has occurred repeatedly since Oligocene time. The Sivas Basin proper is separated from the Kirsehir basement by the Kizilirmak Basin. This new structural unit consists of nearly undeformed, middle Miocene sandstones and conglomerates and a Pliocene lacustrine limestone.

The Sivas Basin proper corresponds to a fold-and-thrust belt involving an Oligocene deltaic plain with intervening large-scale evaporitic stages and subsequent lower Miocene shallow-marine deposits. Three distinct tectonic domains are considered—(1) an eastern A domain, characterized by a hinterland of deep imbricate and rare northward thrusts; (2) a transitional B domain, corresponding to a series of lateral thrust branches propagating to the southwest; this domain later was deformed by the (3) C domain, displaying a foreland-dip type of stacking. The Caldag-Tecer-Gurlevik ridge forms a structural entity of topographic highs along the southern margin of the Sivas fold-and-thrust belt. Three Eocene-cored anticlinoria arranged along an E-W relay zone fold a passive-roof composite allochthon including ophiolitic elements together with Upper Cretaceous to Eocene limestone and conglomerate. The sole of this allochthon consists of Oligocene gypsum. The Kangal Basin, a large syncline cored by Pliocene continental deposits, corresponds to the southernmost unit. The boundary with the Caldag-Tercer-Gurlevik ridge is partially concealed by a lower Miocene continental basin, overlain by a N-vergent thrust of a lower Mesozoic limestone of the Taurus platform. If the southeastward propagation of thrusting in the Sivas thrust belt and related northward thrusts at a variety of scales is considered to represent the main thrust over the undeformed Kizilirmak basin, a comparison with modern analog structural features and analog models yields a coherent interpretation of this basin in terms of its forearc-prism evolution. At a larger scale, the Sivas Basin should be considered as a piggyback basin developed along the northward-rotated rear of the Tauride wedge and the synchronous southward thrusting of the Kirsehir-Pontide wedge. At least in early Miocene time, the Inner Tauride and Erzincan sutures corresponded to a single intracontinental thrust zone along which part of the displacement of the southern front of the Tauride has been progressively transferred.  相似文献   

9.
南大巴山前陆冲断带构造样式及变形机制分析   总被引:35,自引:9,他引:26  
大巴山构造带位于秦岭造山带和四川盆地的过渡部位,形成于印支-燕山期,定型于喜山期。按照构造变形样式及其组合特征,从北东向南西可依次划分为北大巴山逆冲推覆构造带、南大巴山前陆褶皱-冲断带(又包括叠瓦断层带、断层-褶皱带和滑脱褶皱带等3个亚带)和四川盆地东北部低缓构造区等3个构造带(区)。南大巴山冲断带地表构造以类侏罗山式褶皱为显著特征,主要发育叠瓦断层系、断层相关褶皱、被动顶板双重构造、反冲断层系和冲起构造等变形样式。北东-南西向挤压应力和滑脱层是控制南大巴山及其前缘构造变形的主要因素,结合区域地质研究成果,建立了南大巴山及其前缘地区依次从震旦系-下寒武统-志留系-中下三叠统逐渐抬高的多层次滑脱前展模式。  相似文献   

10.
In Pennsylvania, the Taconic Orogeny lasted from 461 to 443 Ma as Cambro-Ordovician slope deposits were deformed into mountains edging the Laurentian craton at the same time that materials from an adjacent deep-water basin were being transported 50 –70 km across a carbonate platform into foreland basins. This paper focuses on shelf-edge hinterland features, mostly the Martic Zone as a folded, stack of imbricate thrust sheets of slope materials that corresponds to Vermont's Taconic Mountains and Southern Quebec's zone of Taconic allochthons. Work of the last century is summarized, corrected, and combined with a new 450 Ma radiometric date and fluid inclusion data from the Pequea Mine within the Martic Zone. These and abundant new graptolite and conodont dates in the foreland paint a revised Pennsylvania picture differing from the northern Taconic areas. Differences are: (1) transport of very large allochthonous masses of deep-water material, the Dauphin Formation, far across the carbonate platform, and (2) deformation migrating progressively across that platform during a 15 –20 m.y. period, incorporating it and its foreland cover into alpine-scale, recumbent folds and thrusts. The scenario has many analogies to Italy's modern Apennine Mountains minus the Latian volcanics.  相似文献   

11.
雪峰山陆内造山带的构造特征与演化   总被引:49,自引:2,他引:47  
在对雪峰山的地质构造及其演化作了研究,并和阿尔卑斯式、阿巴拉契亚式的造山带和远程推覆体作了对比研究以后,作者认为:雪峰山地区的地质构造以具有多期,多层次的层滑构造为主要特色。其主要特征表现为在垂向剖面上有着多个区域性滑脱层,发育株罗山式褐挣矣逆冲叠瓦推覆构造,但它不是阿巴拉契式远程异地推覆体而是准原地型的。逆掩推覆虽然使原来沉积相带变窄,但并未破坏原来扬子地块东南边缘自北西向南东的由台地相--斜坡相--深水盆地相的沉积古地理格局,它是陆内造山带常见的构造样式,是在陆内裂陷的背景上由于裂谷关闭时陆块拼贴碰撞(即所谓软碰撞)和陆内俯冲产生的。雪峰山地区也发育伸展剥离和滑覆构造,伴随每一次挤压造山、地壳加厚的过程,在后造山期,也有地壳的隆升、地壳的拉伸和厚度减薄,它是深部岩石圈拆沉作用在地壳中的表现。  相似文献   

12.
Geologic mapping and U–Pb detrital zircon geochronologic studies of (meta)sedimentary rocks in the Damxung area (90 km north of Lhasa) of the southern Lhasa terrane in Tibet provide new insights into the history of deformation and clastic sedimentation prior to late Cenozoic extension. Cretaceous nonmarine clastic rocks 10 km southeast of Damxung are exposed as structural windows in the footwall of a thrust fault (the Damxung thrust) that carries Paleozoic strata in the hanging wall. To the north of Damxung in the southern part of the northern Nyainqentanglha Range (NNQTL), metaclastic rocks of previously inferred Paleozoic age are shown to range in depositional age from Late Cretaceous to Eocene. The metaclastic rocks regionally dip southward and are interpreted to have been structurally buried in the footwall of the Damxung thrust prior to being tectonized during late Cenozoic transtension. Along the northern flank of the NNQTL, Lower Eocene syncontractional redbeds were deposited in a triangle zone structural setting. All detrital zircon samples of Cretaceous–Eocene strata in the Damxung area include Early Cretaceous grains that were likely sourced from the Gangdese arc to the south. We suggest that the that newly recognized Late Cretaceous to Early Eocene (meta)clastic deposits and thrust faults represent the frontal and youngest part of a northward directed and propagating Gangdese retroarc thrust belt and foreland basin system that led to significant crustal thickening and elevation gain in southern Tibet prior to India-Asian collision.  相似文献   

13.
Granulite to upper amphibolite facies ductile thrusting in the Central Gneiss Belt, Grenville orogen, Ontario, represents the tectonic shortening of a continental-scale footwall beneath the thrust-emplaced Central Metasedimentary Belt, during the closure of a postulated back-arc basin (ca. 1.19-1.18 Ga). Break-back stacking in the footwall occurred at mid- to deep-crustal depths (ca. 35 km) within tectonically thickened (ca. 70 km) continental crust, and culminated with renewed thrusting at the base of the overlying Central Metasedimentary Belt (ca. 1.08-1.05 Ga).

The individual mylonite belts which constitute the ductile thrust zones, and the scale of penetrative deformation of the intervening crystalline thrust sheets, are comparable with the largest known examples of high-grade thrust belts elsewhere. They reflect the large-scale thermal and Theological boundary conditions of the deformation. Flow within individual thrust zones may reflect local boundary conditions, such as the rheological behaviour of older thrust sheets and the geometry of interfaces within the thrust stack.

Restoration of the thickness of erosionally removed crustal overburden by break-back thrusting may retard the rates of exhumation and cooling of a mid- to deep-crustal thrust stack.  相似文献   


14.
Surface and subsurface data are integrated to characterize the structural architecture of the Marathon fold and thrust belt in west Texas. Multiple detachment levels are present within the thrust belt and result in distinct structural domains. In addition to the basal décollement, whose stratigraphic position varies along strike, we recognize a regionally extensive detachment zone in the late Mississippian to early Pennsylvanian lower Tesnus Formation. The Lower Tesnus Detachment forms a structural domain boundary that can be observed along strike in the surface data and at depth in the subsurface. The stratigraphic intervals above and below this detachment exhibit characteristic patterns of deformation. The Lower Tesnus Detachment is folded by imbrication and the formation of duplexes in the early Mississippian to Ordovician section, suggesting that the detachment may have initially formed as a perched décollement in the foreland that was subsequently exploited as a roof thrust in a duplex system as deformation progressed in a break-forward sequence and older strata were incorporated into the toe of the allochthonous wedge. The structural model presented here for the Marathon region may be applicable across much of the Ouachita orogenic system.  相似文献   

15.
Recent mapping and seismic survey reveal that intensive compression during the Early Cenozoic in the Qiangtang block of the central Tibetan Plateau formed an extensive complex of thrust sheets that moved relatively southward along several generally north-dipping great thrust systems. Those at the borders of the ~450 km wide block show it overrides the Lhasa block to the south and is overridden by the Hohxil-Bayanhar block to the north. The systems are mostly thin-skinned imbricate thrusts with associated folding. The thrust sheets are chiefly floored by Jurassic limestone that apparently slid over Triassic sandstone and shale, which is locally included, and ramped upward and over Paleocene-Eocene red-beds. Some central thrusts scooped deeper and carried up Paleozoic metamorphic rock, Permian carbonate and granite to form a central uplift that divides the Qiangtang block into two parts. These systems and their associated structures are unconformably overlain by little deformed Late Eocene-Oligocene volcanic rock or capped by Miocene lake beds. A thrust system in the northern part of the block, as well as one in the northern part of the adjacent Lhasa block, dip to the south and appear to be due to secondary adjustments within the thrust sheets. The relative southward displacement across this Early Cenozoic mega thrust system is in excess of 150 km in the Qiangtang block, and the average southward slip-rate of the southern Qiangtang thrusts ranged from 5.6 mm to 7.4 mm/a during the Late Eocene-Oligocene. This Early Cenozoic thrusting ended before the Early Miocene and was followed by Late Cenozoic crustal extension and strike-slip faulting within the Qiangtang block. The revelation and understanding of these thrust systems are very important for the evaluation of the petroleum resources of the region.  相似文献   

16.
The lateral variability of structural elements in the collision zone of the Cretaceous-Paleocene Achaivayam-Valagin island arc with the northeastern Asian margin is considered. The similarity and difference of Eocene collision structural elements in the north and the south of Kamchatka are shown. In northern Kamchatka, the continent-arc boundary is traced along the Lesnaya-Vatyn Thrust Fault, which completed its evolution about 45 Ma ago. The thin, near-horizontal allochthon of this thrust, composed of island-arc rocks, overlies the deformed but unmetamorphosed terrigeneous sequences of the Asian margin. The general structure of this suture in the Kamchatka Isthmus and southern Koryakia is comparable with the uppermost subduction zone, where a thin lithospheric wedge overlaps intensely deformed sediments detached from the plunging plate. In southern Kamchatka (Malka Uplift of the Sredinny Range), the arc-continent collision started 55–53 Ma ago with thrusting of island-arc complexes over terrigenous rocks of continental margin. However, the thickness of the allochthon was much greater than in the north. Immediately after this event, both the autochthon and lower part of allochthon were deformed and subsided to a significant depth. This subsidence gave rise to metamorphism of both the autochthon (Kolpakov and Kamchatka groups, Kheivan Formation) and lower allochthon (Andrianovka and Khimka formations). The anomalously fast heating of the crust was most likely related to the ascent of asthenospheric masses due to slab breakoff, when the Eurasian Plate was plunging beneath the Achaivayam-Valagin arc.  相似文献   

17.
Detailed mapping and structural analysis of three large-scale culminations (Sumeini and Asjudi half-windows and Haybi-Hawasina window) in the Oman Mountains shows a considerably more complex history of deformation than a simple foreland (or downward) sequence of thrust development. Early thrusting processes tended to create a regular stacking order of imbricate slices and major thrust sheets, complying with the “rules’ of thrust propagation, assembled progressively downwards and forwards in the direction of translation. ‘Out-of-sequence’ thrusts can also be demonstrated in places by truncation of footwall structures (folds, imbricate slices, etc.), gross strain differences between thrust sheets, downward-facing structures in footwall units and elimination of thrust sheets beneath. Late stage thrusts frequently cut up-section through the previously assembled stack putting previously younger, lower thrust sheets over previously older, higher ones. Many of the culminations in the northern and central Oman Mountains were formed by ramping associated with this late-stage leap-frog rethrusting event.  相似文献   

18.
鄂尔多斯西缘北段大型陆缘逆冲推覆体系   总被引:5,自引:0,他引:5       下载免费PDF全文
鄂尔多斯西缘北段是一个自中生代末以来形成的、结晶基底和早古生代大陆边缘沉积盖层同时卷入的巨型陆缘逆冲推覆构造体系。根据区域地层发育、变形岩石属性、冲断层几何学以及它们与联冲断层的关系,大体上可以分为不同形成阶段的3个冲断层构造组合,包括9个次级构造单元(B1—B7,BN,BS)。受冲断层运动自西向东的一致推进,整体呈现一个局部被近东西走向联冲断层切错、向东凸出的弧形:前端为陆缘褶皱冲断带;中部表现为一系列"原地"或"异地"推覆体和冲断席,发育低角度滑脱层和双冲构造;后部又被最晚期的冲断体叠置。侏罗-白垩纪为逆冲推覆构造的主要发展阶段,经历了3期主要的冲断层作用。第Ⅰ期发生在侏罗纪末,沿阿拉善—华北两类不同性质结晶基底之间的主滑脱面发生大规模冲断层作用,形成桌子山—岗德尔山褶皱冲断带。第Ⅱ期冲断层作用的持续位移,形成了具有上、下两个构造层的石嘴山—尖山大型异地推覆体,主滑脱面为石炭纪煤系地层,其中发育典型的双冲构造。新生代(距今65Ma)以来,印度—欧亚板块挤压碰撞和青藏高原早期向北推挤,加剧了鄂尔多斯西缘逆冲推覆构造的进一步发育,第Ⅲ期冲断层作用在东部陆缘褶皱冲断带形成了苏海图反冲构造的同时,在西部将异地推覆体下部的奥陶系再次推至地表。第Ⅰ期和第Ⅱ期冲断层作用累计位移幅度可能达到60~80km,第Ⅲ期冲断层作用的位移幅度为8km。相邻冲断席之间位移矢量的差异,通过近东西走向的联冲断层得到了调整。  相似文献   

19.
李刚  刘正宏 《世界地质》2009,28(4):451-459
内蒙古西部狼山温更逆冲断层发育在温更侏罗纪沉积盆地西北边界, 是一条规模较大的逆冲断裂构造带。断层倾向北西, 上盘由太古宙-元古宙变质地层和古生代深成侵入体构成, 下盘为侏罗纪沉积, 由北西向南东方向逆冲。断层切割改造了早-中侏罗世沉积地层, 被早白垩世沉积地层覆盖, 表明了逆冲断层形成在下中侏罗统沉积之后白垩系固阳组沉积之前。断层带同构造石英脉中流体包裹体的分析结果表明, 断层形成于5.5~6 km浅部地壳构造层之上, 温度为195℃~210℃, 围压为50 ~60 MPa, 断层带的宏观和显微构造显示断层以脆性变形机制为主。  相似文献   

20.
闽北仁寿地区逆冲推覆构造   总被引:2,自引:0,他引:2  
逆冲推覆构造发育于闽北变质岩中,由一系列规模不等向南东倾的叠瓦状逆冲推覆断层及其上盘的推覆岩席组成,由南燕向北西方推覆,往逆冲方面可分为上,下2个逆冲推覆构造系,是前展式逆冲推覆构造,作用时期发生于印支期-燕山期。  相似文献   

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