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1.
重庆綦江奥陶系五峰组中—下部的黑色页岩中发育有一系列主要由阶梯状断层和其间的小型褶皱构成的同生变形构造(contemporaneous deformed structures),并可大致分为3个构造层段。沉积后—固结成岩前所形成的同生变形构造层之上为正常沉积的黑色页岩层。另外,在贵州桐梓五峰组距底部2.3m左右的黑色页岩中也发育有与綦江地区相似的、以小型褶皱为主的同生变形构造层,且此同生变形构造层上下为斑脱岩层。同生变形构造的发现,表明渝南—黔北地区奥陶纪晚期(五峰期)的沉积盆地为非平坦的古地貌,且曾发生过多期可能与火山运动相关的构造运动。 相似文献
2.
地震变形构造主要包括小级别的张性或压性断层、不协调的软沉积物变形褶皱等,这些变形构造以震动变形作用为特点从而成为识别和定义地震岩的主要标志。在河北宣化一带的高于庄组第三段下部的白云质灰岩或灰质白云岩层之中,发育了极为典型的地震变形构造,包括层内断层、层内褶皱以及极为典型的碎裂角砾岩等。高于庄组第三段地震变形构造的发现,为探索和研究地震作用对沉积岩层的破坏和改造而区分于其他的事件沉积如海啸沉积和风暴沉积提供了极为重要的实例,也为更加深入理解高于庄组第三段非叠层石碳酸盐岩沉积序列的产出背景提供了重要资料。 相似文献
3.
龙门山中段山前带构造变形历史与物理模拟 总被引:2,自引:0,他引:2
龙门山冲断构造带具有NE分带、EW分段的构造变形特征。龙门山构造带中段逆冲推覆带是以出露彭灌杂岩及其前缘发育飞来峰为典型特征,变形以倾向北西的紧闭倒转-同斜褶皱为主;推覆-滑覆带变形强烈,发育一系列叠瓦状逆冲断层及相关的褶皱,及一系列由泥盆系至下三叠统碳酸盐岩构成的飞来峰,地腹发育厚皮构造,以叠瓦冲断构造为主;而前陆坳陷变形较弱,地表主要为SE倾伏的单斜,地腹则发育断层相关褶皱。通过构造物理模拟认为:1)龙门山中段构造变形受力边界主应力与断裂走向间的锐夹角为70°;2)变形样式总体为双滑脱层所控制的分层滑脱垂向叠加构造组合;3)构造变形过程具有3个阶段,早期须家河组沉积之后产生的滑脱断层垂向叠加,中期在遂宁组沉积期间和晚期在蓬莱镇组沉积期间及其后,发生滑脱断层垂向叠加,且控制沉积。 相似文献
4.
晚奥陶世五峰期上扬子海南缘的
同生变形构造形成机制 总被引:2,自引:0,他引:2
晚奥陶世上扬子海南缘以黑色碳质页岩为特征的五峰组笔石页岩段中见有由小型褶皱和层间阶梯状断层等构成的同生变形构造,其上下地层均为正常沉积的黑色页岩。同生变形构造开始于凯迪阶末期Dicellograptus complexus,结束于Paraorthograptus pacificus。在空间分布上表现为靠近滇黔桂古陆一侧的上扬子海盆内(古蔺—桐梓—松桃)的变形构造层以小型褶皱为特征;向海一侧(綦江—秀山)则逐渐过渡为以小型阶梯状断层为主,同时伴有小型褶皱,但川南长宁一带的五峰组中未发现有同生变形构造。同生变形构造在滇黔桂古陆向海一侧较近陆一侧发育,其变形强度逐渐增强,且由西向东同生变形构造的发育强度增强,表明扬子海在沿滇黔桂古陆的西侧可能为较平坦的古海底地貌,而东侧具有较陡的斜坡存在。在渝东南秀山,仅同生变形构造层内发育有地震事件成因的火焰状岩脉。另外,在桐梓地区,同生变形构造层的上、下与正常沉积的黑色页岩之间均见有斑脱岩层,因而推测火山喷发可能是导致变形构造形成的主要诱因。在火山事件引起地壳多期震荡的背景下,处于陡坡上的塑性泥(页)岩发生滑动形成同生变形构造。同时,奥陶纪末期是加里东运动的剧烈活动期,导致滇黔桂古陆西侧较为平坦,而东侧较陡的古海底地貌可能与奥陶纪晚期扬子陆块与华夏陆块发生的碰撞相关。 相似文献
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6.
通过岩芯观察,码头庄油田阜宁组发育了大量的同生小断层、液化岩脉、泥火山、震动液化扭曲变形、震动液化卷曲变形、自碎角砾岩等震积岩沉积构造,该类沉积构造属于软沉积变形构造,具有典型的震积岩沉积特征。首次在同期震积岩中发现同生微型正/逆断层发育,2种不同类型断层的发现,说明区内震积岩存在不同的应力环境,在滑塌体上部易形成微正断层,在滑塌体下部易形成微逆断层。认为前人对震积岩微同沉积断裂层、微褶皱变形层、碎块层、液化均一层4段分层的完整垂向序列可能过于理论化,并提出水平液化变形段、拉张段、滑脱段、沉积段、水平沉积变形段5段式震积岩立体发育模式。 相似文献
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8.
《现代地质》2016,(4)
生物礁是由原地的固着生物所建造的块状碳酸盐岩沉积。西沙海域自中新世以来发育了厚层生物礁地层。通过对最新全取心钻井西科1井岩心的宏观观察和微观分析,结合古生物及岩心测试成果,发现西科1井中新世和第四纪为主要造礁期,形成了两套分别以珊瑚藻和珊瑚为主要造礁生物的生物礁序列,底栖有孔虫为主要的附礁生物,而上新统为一套滩相沉积。生物礁序列发育骨架岩、粘结岩和障积岩三种礁相岩石,以骨架岩含量最高,非礁相岩石包括泥灰岩、颗粒灰岩和生物碎屑灰岩三种。白云岩地层以晚中新世到上新世早期最为发育,多为准同生白云石化作用所致,并受热液活动的影响。对生物礁序列的沉积分析,可为后期南海油气勘探以及生物礁储层分布研究提供一些基础材料。 相似文献
9.
北大巴山与志留纪火山作用相关的碳酸盐岩沉积学特征及形成环境 总被引:4,自引:1,他引:3
生物碎屑灰岩、生物礁是造山带内最为常见的岩石类型之一,它们可以形成于多种构造环境。研究这些岩石组合的结构组成及生物赋存状态可为古地理恢复及造山带演化提供依据。分布于北大巴山地区与富TiO2碱性火山岩紧密相关的碳酸盐岩组合长期以来被认为是被动陆缘台地相组合。该套碳酸盐岩组合主要由生物礁、生物碎屑灰岩、砂屑灰岩、泥质灰岩、角砾灰岩共同构成。砂屑灰岩及生物灰岩中常伴随有薄层凝灰岩夹层;同时这些碳酸盐岩中富含不同比例的火山碎屑成分,发育粒序层理、平行层理、波纹斜层理和滑塌构造。生物碎屑灰岩通常与凝灰质砂岩、泥岩构成韵律层,火山质碎屑在类岩石中主要表现为粒径0.5~3 mm的棱角状—次棱角状玄武岩和凝灰岩碎屑,具有近源沉积特征;生物礁中通常出现1~2.5 cm棱角状—次棱角状玄武岩碎屑,且在生物礁之间的砂岩夹层中含有丰富的0.5~1 mm的次圆状玄武岩碎屑;砂屑灰岩中含有棱角状—次棱角状玄武岩和辉石两类碎屑,其中辉石碎屑粒径通常为1~2 mm,同时该类岩石中还含有丰富的黄铁矿,这些黄铁矿通常因其粒径变化而发育粒序结构特征。角砾状灰岩可分别由砂屑灰岩、生物礁及生物碎屑灰岩构成,也可由三者共同构成,玄武岩碎屑仅出现于角砾状生物礁灰岩中。这些碳酸盐岩中的生物化石具有曾经历过明显的搬运改造特征,其中生物碎屑灰岩和砂屑灰岩中的化石碎屑以次圆状为主,生物礁中的生物化石平行于砂岩夹层分布且发生不同程度的压扁和挤压变形,岩石中普遍发育滑塌沉积构造。这些特征共同表明,该套碳酸盐岩与下伏的碱性玄武岩形成密切相关,二者共同构成了与现代大洋中典型洋岛/海山相一致的结构特征,且这些碳酸盐岩多沿着下伏玄武岩的周边沉积,具有深水—斜坡环境的沉积组合,同时因其中所包含的生物化石经历了一定距离搬运作用而发生再沉积,进一步表明这些生物发育时代可能要略微早于该套火山—沉积组合的形成时代。 相似文献
10.
通过对红花生物礁露头的精细解剖和微相分析,研究了礁的内部构成和成礁模式。红花生物礁发育3期礁体旋回:礁A、礁B和礁C。礁A由生屑泥晶灰岩和骨架岩构成;礁B由生屑泥晶灰岩、粘结岩、骨架岩和生屑灰岩构成;礁C由粘结岩、骨架岩和生屑灰岩构成。红花生物礁造礁生物有钙质海绵、钙藻类、苔藓虫和水螅类,附礁生物为有孔虫、腕足类、双壳类、腹足类和棘皮动物等。单个礁体内,由下往上的生物演化为:腕足类+双壳类+有孔虫组合→钙藻类→钙质海绵+水螅类+钙藻类+苔藓虫组合→生物碎屑;岩性演化为:生屑泥晶灰岩→粘结岩→骨架岩→生屑灰岩。礁B的生屑滩内生屑间为泥晶充填,生屑分选、磨圆较好,是由相邻的高能生屑滩侵蚀搬运到礁B侧翼低能区沉积形成。3期礁都发育在碎屑滩上,礁A为低能环境下形成的礁,礁B和礁C在礁A形成的高地上成礁,为高能环境礁;单个礁体的完整成礁模式为:在浅滩之上,钙藻类大量生长、粘结吸附颗粒固结基底,钙质海绵和钙藻类在硬质基底上繁茂生长,形成具有抗浪格架的生物礁,礁体暴露水面死亡后遭波浪、水流改造形成生屑滩。 相似文献
11.
贵州独山中深盆统不整合的发现及其意义 总被引:1,自引:0,他引:1
黔南中泥盆统独山组鸡窝寨段底部存在的古风化壳层和其之上的底砾岩,为一次地亮相对上升、海平面下降的上升运动(独山抬升),表明独山组内存在着沉积间断。建议将此古风化壳之上的原"独山组鸡窝寨段"修订为"鸡窝寨组",代表中泥盆世晚期较独山组更大海侵的以碳酸盐岩为主的沉积。 相似文献
12.
K. M. Tomlinson C. J. L. Wilson R. Hazeldene E. M. Lohe 《Australian Journal of Earth Sciences》2013,60(4):421-444
Gold mineralization associated with quartz reefs is related to the structural history of the Early Devonian, Walhalla Group. These reefs are situated in the Walhalla Synclinorium, developed during the Middle to Late Devonian Tabberabberan Orogeny. A pervasive north‐south‐trending axial planar cleavage and two styles of folding were produced during regional east‐west compression. The first are upright, open to close folds with sub‐horizontal fold axes. The second are plunging inclined, close to tight folds with fold axes that plunge steeply to the north and south. An extensional event is associated with the emplacement of the Woods Point Dyke swarm and a set of normal faults that offset all earlier structures. High‐angle reverse faults, which post‐date the folding and the emplacement of the dykes, were utilized as conduits for hydrothermal fluids and preferentially localize mineralization to laminated quartz veins. En echelon vein arrays formed during initial stages of reverse faulting became deformed during prolonged shearing to produce ptygmatic veins. Laminated quartz veins within high‐angle reverse faults contain arsenopyrite and pyrite in vein margins and gold in fractures that cross‐cut continuous quartz crystals. Gold, galena, chalcopyrite and sphalerite may also be deposited adjacent to and within fractured arsenopyrite and pyrite. Late‐stage, cross faults developed in a regime of north‐south compression and post‐date the laminated quartz veins and mineralization. 相似文献
13.
Emyr Williams 《Tectonophysics》1978,48(3-4)
In western Tasmania Eocambrian and Cambrian rock sequences accumulated in narrow troughs between and within Precambrian regions which became geanticlines. The largest trough is meridional and is flanked by the Tyennan Geanticline to the east and the Rocky Cape Geanticline to the west. Within this trough ultramafic and mafic igneous masses, some of which are dismembered ophiolites, occur below a structurally conformable but erosional surface. This surface is at the base of an early-Middle Cambrian turbidite sequence, which grades upward into a probable correlate of the Owen Conglomerate that ranges into the Ordovician. Fault-bounded areas of Rocky Cape strata occur at the eastern boundary of the sedimentary trough deposits. A considerable pile of mineralized calcalkalic volcanic material, in which granite was emplaced, accumulated between the sedimentary trough deposits and the Tyennan Geanticline. Movements along Cambrian faults near and parallel to the margin of the Tyennan Geanticline caused angular unconformities. Above the unconformities occur volcaniclastic sequences that pass conformably upward into shallow marine and terrestrial Owen Conglomerate, derived from the Tyennan Geanticline.The transgressive Owen Conglomerate and its correlates are followed conformably by shallow marine limestone, of Early to Late Ordovician age. These limestone deposits covered much of western Tasmania and are succeeded conformably by Silurian to Early Devonian beds of shallow-marine quartz sandstone and mudstone.Pre-Middle Devonian rocks of western Tasmania extend to the Tamar Tertiary trough. In the northeast of Tasmania, immediately to the east of the Tamar trough, are sequences of interbedded mudstone and turbidite quartz-wacke of the Mathinna Beds, ranging in age from Early Ordovician to Early Devonian.The Cambrian to Early Devonian rocks of Tasmania are extensively deformed and show flattened parallel folds. In western Tasmania the folds are dated as late-Early to early-Middle Devonian because fragments of the deformed rocks occur in undisturbed Middle Devonian terrestrial cavern fillings. Folds of the northeastern Tasmania Mathinna Beds are probably of the same age. This widespread Devonian deformation is correlated with the Tabberabberan Orogeny of eastern Australia.In western Tasmania the geanticlines of Cambrian times behaved as relatively competent blocks during the Devonian folding, which is of two main phases. In the earlier phase the competent behaviour of the Tyennan Block determined the fold patterns. In the north the dominantly later folds resulted from movement from the northeast. During this later Devonian phase the Tyennan Block yielded in a northwesterly trending narrow zone of folding.In northeast Tasmania the Mathinna Beds exhibit folds which indicate a tectonic transportation opposite in direction to that which resulted in the folds of similar age in western Tasmania.Granitic rocks, dated 375-335 m.y., were emplaced within the folded rocks of Tasmania with usually sharp, discordant contacts. Foliations in the batholiths of northeast Tasmania suggest post-intrusion deformations involving east—west flattening. The late deformations may be related to lateral movements along a fracture zone which brought the Mathinna Beds of northeast Tasmania into juxtaposition with the rocks of contrasting stratigraphical and structural characteristics of western Tasmania.Flat-lying Late Carboniferous and younger deposits rest unconformably on the older rocks. 相似文献
14.
本文以大量化石资料为基础,结合生物礁研究成果,重建了东昆仑造山带西段早-中二叠世礁相地层层序,确定了地层时代归属。礁相地层自下而上分为5个岩组。阿其克库勒组为陆块边缘碎屑陆棚之上的碳酸盐沉积和丘状生物礁建造,可建立Ting类Schwagerina-Eoparafusulina组合带和Chalaroschwagerina-Pseudofusulina Parafecunda组合带,对比为下二叠统的中上冲淡,查德尔塔格组为海侵期巨厚块状障壁礁碳酸盐岩,包含Ting类Mis-ellina claudiae组合和一个未定名组合,属中二叠世栖霞期,青石山组和碧云山组为同时异相沉积,前者以礁核相骨架灰岩为主,厚度巨大;后者为礁后-泻湖相黑色富有机质岩层,厚度较薄,二岩组同属Ting类Polydiexodina-Neoschwagerina组合带内Cancerllina liuzhiensis亚带、Neoschwagerina simplex亚带和Afghanella schencki亚带的层位,时代为中二叠世茅口早一中期,喀尔瓦组为类复理石相砂板岩平恶意泥丘灰岩,含Afghanella schencki亚带的Ting化石,地层时代与青石山组(或碧云山组)上部相当。 相似文献
15.
Bill Fitches 《Geological Journal》2011,46(4):364-373
On the Isle of Man, the Early Devonian Peel Sandstones and Early Carboniferous limestones have been deformed in places by folds, cleavage and other structures. The structures in the Peel Sandstones have been attributed to pre‐lithification deformation associated with slumping of the red beds. Here, they are re‐interpreted to be products of post‐lithification deformation, inferred from small‐scale structures and fabrics, which took place in a localized thrust zone. Compression was approximately NW–SE and translation towards the SE. That deformation may have also produced some of the late structures in the Lower Palaeozoic rocks of the island. The minimum age of these post‐Early Devonian structures is unknown but is probably pre‐Carboniferous: they may represent the mid‐Devonian Acadian deformation. The Carboniferous succession is folded in places and contains stylolites and stylolitic cleavage. A stress regime with E–W to WNW–ESE compression is inferred. These structures have orientations and morphologies shown to resemble those in neighbouring parts of southern Britain, where they are attributed mainly to mid‐ to late‐Carboniferous Variscan events. Alternatively, some or all of them might be products of late Mesozoic and Tertiary tectonics recognized elsewhere in the region. Copyright © 2010 John Wiley & Sons, Ltd. 相似文献
16.
Brittle and ductile deformation of alternating layers of Devonian sandstone and mudstone at Cape Liptrap, Victoria, Australia, resulted in upright folds with associated fold accommodation faults and multiple fracture sets. Structures were mapped at the Fold Stack locality at Cape Liptrap using high-resolution aerial photographs acquired by a digital camera mounted on an unmanned aerial vehicle (UAV). Subsequent photogrammetric modelling resulted in georeferenced spatial datasets (point cloud, digital elevation model and orthophotograph) with sub-cm resolution and cm accuracy, which were used to extract brittle and ductile structure orientation data. An extensive dataset of bedding measurements derived from the dense point cloud was used to compute a 3D implicit structural trend model to visualise along-strike changes of Devonian (Tabberabberan) folds at the Fold Stack locality and to estimate bulk shortening strain. This model and newly collected data indicate that first generation shallowly south-southwest plunging upright folds were gently refolded about a steeply plunging/subvertical fold axis during a Devonian low-strain north–south shortening event. This also led to the local tightening of first generation folds and possibly strike-slip movement along regional scale faults. In order to distinguish fractures associated with Devonian compression from those that formed during Cretaceous extension and later inversion, we compared the five fracture sets defined at Cape Liptrap to previously mapped joints and faults within the overlying sedimentary cover rocks of the Cretaceous Strzelecki Group (Gippsland Basin), which crop out nearby. An east-southeast trending fracture set that is not evident in the Strzelecki Group can be linked to the formation of Devonian folds. Additionally, hinge line traces extracted from the Fold Stack dataset are aligned parallel to a dominant fracture set within the overlying cover sediments. This suggests that basement structures (folds and coeval parallel faults) have an important influence on fault and joint orientations within Cretaceous cover rocks. 相似文献
17.
The Northern, Central, and Southern zones are distinguished by stratigraphic, lithologic, and structural features. The Northern Zone is characterized by Upper Silurian–Lower Devonian sedimentary rocks, which are not known in other zones. They have been deformed into near-meridional folds, which formed under settings of near-latitudinal shortening during the Ellesmere phase of deformation. In the Central Zone, mafic and felsic volcanic rocks that had been earlier referred to Carboniferous are actually Neoproterozoic and probably Early Cambrian in age. Together with folded Devonian–Lower Carboniferous rocks, they make up basement of the Central Zone, which is overlain with a angular unconformity by slightly deformed Lower (?) and Middle Carboniferous–Permian rocks. The Southern Zone comprises the Neoproterozoic metamorphic basement and the Devonian–Triassic sedimentary cover. North-vergent fold–thrust structures were formed at the end of the Early Cretaceous during the Chukchi (Late Kimmerian) deformation phase. 相似文献
18.
The shape of the frontal part of the Himalaya around the north-eastern corner of the Kumaun Sub-Himalaya, along the Kali River valley, is defined by folded hanging wall rocks of the Himalayan Frontal Thrust (HFT). Two parallel faults (Kalaunia and Tanakpur faults) trace along the axial zone of the folded HFT. Between these faults, the hinge zone of this transverse fold is relatively straight and along these faults, the beds abruptly change their attitudes and their widths are tectonically attenuated across two hinge lines of fold. The area is constituted of various surfaces of coalescing fans and terraces. Fans comprise predominantly of sandstone clasts laid down by the steep-gradient streams originating from the Siwalik range. The alluvial fans are characterised by compound and superimposed fans with high relief, which are generated by the tectonic activities associated with the thrusting along the HFT. The truncated fan along the HFT has formed a 100 m high-escarpment running E–W for ~5 km. Quaternary terrace deposits suggest two phases of tectonic uplift in the basal part of the hanging wall block of the HFT dipping towards the north. The first phase is represented by tilting of the terrace sediments by ~30 ° towards the NW; while the second phase is evident from deformed structures in the terrace deposit comprising mainly of reverse faults, fault propagation folds, convolute laminations, flower structures and back thrust faults. The second phase produced ~1.0 m offset of stratification of the terrace along a thrust fault. Tectonic escarpments are recognised across the splay thrust near south of the HFT trace. The south facing hill slopes exhibit numerous landslides along active channels incising the hanging wall rocks of the HFT. The study area shows weak seismicity. The major Moradabad Fault crosses near the study area. This transverse fault may have suppressed the seismicity in the Tanakpur area, and the movement along the Moradabad and Kasganj–Tanakpur faults cause the neotectonic activities as observed. The role of transverse fault tectonics in the formation of the curvature cannot be ruled out. 相似文献