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1.
盐井?五龙断裂是龙门山中央断裂北川?映秀断裂的南延部分,也是龙门山南段的三大控制性主干断裂之一。为了详细认识盐井?五龙断裂的构造几何学、运动学特征,在野外构造研究的基础上,运用磁组构方法对盐井?五龙断裂105块构造岩定向样品进行深入研究。野外构造解析表明断裂至少发生了韧性挤压剪切、脆?韧性逆冲和脆性挤压碎裂三期构造变形。磁组构研究显示构造岩磁组构样品的平均磁化率k_m值具有强磁化率和弱磁化率两种特征。磁组构形状参数T、磁面理F值、磁线理L值和T-P_J图解显示磁化率椭球体主要为压扁型,磁面理较磁线理发育,局部发育较强磁线理,进一步表明盐井?五龙断裂以挤压、剪切为主,伴有拉伸变形的整体特征,样品的P_J整体较大,显示出构造强变形磁组构特征。最小磁化率主轴Kmin方位表明盐井?五龙断裂北段和南段分别受到了NW-SE向和NEE-SWW向的挤压作用;Kmin方位和倾伏角表明北段晚一期的脆韧性变形主体为自NW向SE的较高角度的挤压逆冲剪切变形,局部伴有极小量的左行走滑特征。断裂南段早期韧性变形整体以自SWW向NEE的挤压逆冲剪切变形为主,上盘(西盘)远离主干断裂表现为左行走滑兼逆冲的运动学特征,下盘变形主要以逆冲剪切变形为主,走滑分量极小,并且自西向东韧性剪切变形具有相对强弱相间的特征。 相似文献
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论文通过宏-微观构造、磁组构、热液锆石和石英EBSD组构等,厘定鹰扬关韧性剪切带并讨论其构造意义。鹰扬关韧性剪切带具有宏-微观韧性变形组构,发育糜棱岩、拉伸线理、S-C组构、旋转碎斑系、书斜构造、压力影和石英的动态重结晶等。磁组构和宏-微观构造表明,鹰扬关韧性剪切带呈NNE向延伸超过40 km,宽2.5~8 km。糜棱C面理的极密点产状127°∠50°;磁面理的极密点产状107°∠83°。宏-微观构造研究表明,鹰扬关韧性剪切带具有早期左旋逆冲剪切,晚期右旋正滑剪切的运动学性质。石英EBSD组构表明,鹰扬关韧性剪切带具有晚期中低温变形(400~550℃)叠加于早期中高温变形(550~650℃)的特征。年代学研究表明,鹰扬关韧性剪切带早期左旋逆冲剪切的时代为(441.1±2.3)Ma,晚期右旋正滑剪切的时代应晚于420 Ma,区域构造应力由挤压转为伸展的时限为420 Ma。在磁组构、石英EBSD组构和热液锆石定年的基础上,结合区域地质资料,认为鹰扬关韧性剪切带形成于华夏陆块自SE向扬子陆块造山挤压的构造背景。早期造山挤压,产生压扁型应变和中高温左旋逆冲剪切;晚期造山后伸展,产生拉伸型应变和... 相似文献
3.
江南晚元古代碰撞造山带中段九岭山南缘断裂带的运动学研究揭示出三个不同时期的强烈构造变形作用。第一期从北向南仰冲推覆作用,对应一个晚元古代洋盆关闭,板块碰撞造山过程;第二期从SW向NE的左旋走滑动性剪切作用,对应一个早古生代华南地体的斜向拼贴增生活动;第三期从北向南的逆冲-推覆作用,对应一个印支构造期的侧向挤压机制。现代地表上的九岭古岛弧南缘断裂带,是一个以走滑剪切力学作用占优势的片麻状糜棱岩带。宏观韧剪组构和显微构造标志为这个断裂带提供了重要的运动学证据。 相似文献
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5.
萨勒巴斯推覆体中发育一套深层次变形构造组合和倒转递增变质带,其中糜棱岩、混合岩、混合花岗岩的成因关系对研究挤压造山背景下,地壳深层次变形作用和成岩作用具有特殊的意义。研究表明:在大型滑脱推覆系统中,存在糜棱岩—混合岩—混合花岗岩成岩系列;成岩过程为:韧性变形—剪切加热—部分熔融;控制成岩过程的主导因素为构造动力条件。这一成岩过程能导致稀土元素发生分异,出现重稀土元素有规律地亏损,变质作用pTt轨迹显示造山过程中逆冲推覆作用导致的地壳叠置加厚和剪切加热的典型热演化模式,变形、变质高峰期后,高角度逆冲作用导致变形岩石经历减压、降温的退变质作用,形成由南向北的倒转递增变质带。 相似文献
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襄樊——广济断裂西段的三里岗——三阳地区出露有构造混杂岩,以含蛇绿岩残块为特征,经历了复杂的构造变形和演化过程。不同区段的构造解析与对比表明,中生代以来该构造混杂岩带主要遭受了4期变形构造的叠加改造:1)高温塑性变形(D1),表现为蛇绿岩残块内部具网状强应变带和透镜状弱应变域相互交织的构造变形样式,强应变带形成以镁铁质糜棱岩为特征的高温韧性剪切带,显示深层次构造变形特征;2)逆冲推覆变形(D2),构造混杂岩带发育叠瓦状逆冲推覆构造和双冲构造,南界韧性剪切带是构造混杂岩带整体运移的主推覆面,发育长英质糜棱岩,形成于中等构造层次,岩石中发育镁铁质糜棱岩糜棱面理的褶皱构造,显示陆内逆冲推覆对先期高温塑性变形构造的叠加改造;3)韧脆性右行平移剪切(D3),形成构造混杂岩带内部浅层次构造变形,构造混杂岩带南侧的花山群钙质片岩揉皱变形,形成枢纽近直立的不对称褶皱,指示右行平移剪切变形;4)伸展正断层(D4),主要发育于构造混杂岩带北侧,呈NW——SE向展布,控制晚白垩世断陷盆地的形成与沉积充填。 相似文献
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北祁连山俯冲杂岩带的韧性剪切作用 总被引:5,自引:0,他引:5
北祁连山加里东褶皱带中的蓝片岩(包括蓝闪片岩和榴辉岩)产于原岩为中寒武统的典型蛇绿俯冲杂岩带之中,是北祁连古板块缝合线的标志之一。蓝片岩带中强烈的韧性剪切变形作用代表了本区古板块持续俯冲到碰撞过程中地壳深部层次的变形行为。构造分析表明,该蛇绿混杂岩带经历了早、晚两期韧性剪切变形的改造。其中早期韧性剪切变形(DF_1)与区域D_2变形幕有关,蓝闪片岩相矿物(蓝闪石、石榴子石、绿帘石和多硅白云母)是伴随变形叶理生长的同构造产物。晚期韧性剪切变形与区域D_3变形幕有关,伴随有绿泥石、冻蓝闪石等的出现和石英、方解石的动态重结晶作用。运动学指示标志,如拉伸线理、与拉伸线理平行的各种褶皱枢纽、同构造变斑晶的旋转、S-C组构及石英光轴组构等,都清楚地显示DF_1运动方向为南东-南南东,伴有左行旋转,晚期DF_2为由NE向SW的逆冲剪切,伴有右行旋转。方解石和石英光轴组构表明晚期逆冲剪切的古挤压应力方向为北北东-南南西。 相似文献
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本文选取秦岭商丹断裂带以南,南秦岭刘岭群以北的弧前沉积体为研究对象,研究扬子板块向北秦岭俯冲的运动学特征。这套弧前沉积体产状北倾,矿物拉伸线理为倾向线理,岩片强烈褶皱,断裂发育,表现出由北向南逆冲的运动学特征。利用糜棱岩与云母石英片岩中矿物变形温度计,结合石英C轴组构估算岩石变形温度集中在400℃~550℃之间。结合其所处的构造位置,本文认为这套强烈变形的岩石构造组合体形成于秦岭古岛弧弧前沉积背景,在扬子板块向北秦岭俯冲过程中,北秦岭沿着商丹带由北向南逆冲形成。后期又遭受商丹韧性剪切带左行走滑活动的改造。 相似文献
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桂东南那卜地区潭超单元及其围岩中,主期变形变质作用形成的韧性剪切带可分为2类:NE向右行走滑性质的韧性剪切带;NW向逆冲推覆性质的韧性剪切带。通过对以上2类韧性剪切带的构造样式、显微组构以有运动学特征等的综合分析表明,它们形成的构造应力是NE-SW向的,在这一应力的作用下,使早期NE向和NW向构造重新活动,从而构成了一种NE向走滑-NW向逆冲的相互转换程式,即NE向右行走滑性质韧性剪切带和NW向逆冲推覆性质韧性剪切带相互转换的韧性变形体系。 相似文献
10.
西秦岭北缘新阳—元龙韧性剪切带作为西秦岭造山带与北祁连造山带之间的区域韧性构造边界,带内构造样式复杂多样,多期构造叠加,不同部位韧性变形强度不同,兼具左行、右行剪切特征,但以右行为主,宏观构造显示由NNE向SSW斜向逆冲特征,且多被后期构造改造。EBSD组构分析结果显示,石英C轴优选方位指示非共轴变形,显示明显的中温柱面a-中低温菱面-低温底面组构的右行剪切及不太明显的低温底面组构(偶见中低温组构)左行剪切特征;方解石C轴组构显示e1双晶滑移与r1平移滑动,兼具左行、右行剪切特征。组构特征反映该剪切带可能经历了中温—中低温—低温、以右行韧性走滑为主并曾出现过左行逆冲的复杂变形过程,综合分析推断该韧性剪切带经历了低绿片岩相—高绿片岩相—低角闪岩相韧性变形环境。区域对比分析认为,新阳—元龙韧性剪切带响应古生代构造演化的构造变形记录主要为2期:一是志留纪天水—武山洋闭合导致大规模NNE-SSW向的陆-弧或陆-陆碰撞逆冲造成的左行逆冲剪切变形;二是晚泥盆世—早石炭世秦祁结合部位强烈的大规模右行走滑拼贴运动形成的右行剪切变形和反"S"构造样式。 相似文献
11.
Quartz c axis fabrics and microstructures have been investigated within a suite of quartzites collected from the Loch Eriboll area of the Moine Thrust zone and are used to interpret the detailed processes involved in fabric evolution. The intensity of quartz c axis fabrics is directly proportional to the calculated strain magnitude. A correlation is also established between the pattern of c axis fabrics and the calculated strain symmetry.Two kinematic domains are recognized within one of the studied thrust sheets which outcrops immediately beneath the Moine Thrust. Within the upper and central levels of the thrust sheet coaxial deformation is indicated by conjugate, mutually interfering shear bands, globular low strain detrital quartz grains whose c axes are aligned sub-parallel to the principal finite shortening direction (Z) and quartz c axis fabrics which are symmetric (both in terms of skeletal outline and intensity distribution) with respect to mylonitic foliation and lineation. Non-coaxial deformation is indicated within the more intensely deformed and recrystallized quartzites located near the base of the thrust sheet by single sets of shear bands and c axis fabrics which are asymmetric with respect to foliation and lineation.Tectonic models offering possible explanations for the presence of kinematic (strain path) domains within thrust sheets are considered. 相似文献
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Fabric development during shear deformation in the Main Central Thrust Zone, NW-Himalaya, India 总被引:2,自引:0,他引:2
Quartz microfabrics and associated microstructures have been studied on a crustal shear zone—the Main Central Thrust (MCT) of the Himalaya. Sampling has been done along six traverses across the MCT zone in the Kumaun and Garhwal sectors of the Indian Himalaya. The MCT is a moderately north-dipping shear zone formed as a result of the southward emplacement of a part of the deeply rooted crust (that now constitutes the Central Crystalline Zone of the Higher Himalaya) over the less metamorphosed sedimentary belt of the Lesser Himalaya. On the basis of quartz c- and a-axis fabric patterns, supported by the relevant microstructures within the MCT zone, two major kinematic domains have been distinguished. A noncoaxial deformation domain is indicated by the intensely deformed rocks in the vicinity of the MCT plane. This domain includes ductilely deformed and fine-grained mylonitic rocks which contain a strong stretching lineation and are composed of low-grade mineral assemblages (muscovite, chlorite and quartz). These rocks are characterized by highly asymmetric structures/microstructures and quartz c- and a-axis fabrics that indicate a top-to-the-south sense that is compatible with south-directed thrusting for the MCT zone. An apparently coaxial deformation domain, on the other hand, is indicated by the rocks occurring in a rather narrow belt fringing, and structurally above, the noncoaxial deformation domain. The rocks are highly feldspathic and coarse-grained gneisses and do not possess any common lineation trend and the effects of simple shear deformation are weak. The quartz c-axis fabrics are symmetrical with respect to foliation and lineation. Moreover, these rocks contain conjugate and mutually interfering shear bands, feldspar/quartz porphyroclasts with long axes parallel to the macrosopic foliation and the related structures/microstructures, suggesting deformation under an approximate coaxial strain path.On moving towards the MCT, the quartz c- and a-axis fabrics become progressively stronger. The c-axis fabric gradually changes from random to orthorhombic and then to monoclinic. In addition, the coaxial strain path gradually changes to the noncoaxial strain path. All this progressive evolution of quartz fabrics suggests more activation of the basal, rhomb and a slip systems at all structural levels across the MCT. 相似文献
13.
Field, microstructural, and anisotropy of magnetic susceptibility (AMS) or magnetic fabric studies were applied to identify the sequence and character of the Pan-African structures in the basement of Eastern Cameroon at both sides of the regional scale Bétaré-Oya Shear Zone (BOSZ). The NE-SW trending BOSZ separates older gneisses and migmatites towards SE (domain I) from the younger rocks of the Lom meta-volcano-sedimentary basin towards NW (domain II). In domain I, early, ductile compressional deformation occurred in two events, D1 and D2, under relatively high T conditions. During subsequent cooling, strain partitioned between the competent basement gneisses with only mild compression and the bordering shear zone (BOSZ) with intense simple shear-wrenching (D3). Strain in the less competent rocks of domain II is dominated by simple shear, strike-slip wrenching (D3), with an earlier stage of compressional deformation preserved only in some low strain pods.Magnetic fabrics (AMS) document a progressive change from oblate ellipsoids towards prolate ellipsoids in domain I, when proceeding from the south towards the BOSZ. Foliations are mostly steep but define a girdle with a pole plunging gently towards WSW. The magnetic lineations also plunge mostly towards WSW at shallow angles. These fabrics indicate a compression approximately normal to the BOSZ, which is also the SE margin of the Lom Basin. In the Lom metasediments (domain II), AMS ellipsoids are typically oblate. Foliations trend NE-SW with mostly steep dips. Magnetic lineations plunge gently NE or SW. This fabric with foliations mostly steep and subparallel with the major BOSZ, combined with generally subhorizontal lineations implies the BOSZ as a Pan-African strike–slip shear zone with a subordinate component of compression.At a larger scale, the area is part of a continent-scale shear zone, separating external Pan-African domains of compression along the northern margin of the Congo craton from internal domains dominated by high-angle strike–slip and transpressional deformation. Together with published data, the present study thus demonstrates that transpression is a regional phenomenon in the Pan-African orogen of central and eastern Cameroon. 相似文献
14.
It is suggested that the kinematic framework controls the orientation of crystallographic fabrics developed in plastically deformed quartzites. Important directions in this framework are those of the instantaneous stretching axes, and the flow plane and flow direction if these can be uniquely defined. Rotation of the crystal axes takes place at any instant of time dependent on the orientation of the grain relative to the stretching axes. Because of this dependence the skeletal outline* of a pattern of preferred orientation is sensitive to the closing stages of deformation. Thus fabrics measured in major movement zones cannot be related to early thrust or shear displacements without considering the effects of the geological history subsequent to those events.Nevertheless, asymmetric fabrics in movement zones may allow determination of the shear direction and sense of shear. Asymmetry in the intensity distribution is less susceptible to modification than asymmetry in the fabric skeleton, and may remain as a persistent measure of the sense of shear in mylonites subjected to coaxial deformation after non-coaxial events. However, fabric asymmetry need not always be related to the deformation history, and effects related to the population of initial grain-orientations must be considered, as well as the influence of recrystallization and grain growth.A problem of scale is involved in extrapolating the movement picture inferred from the behaviour of a few hundred crystal grains to larger dimensions. This question is also encountered when trying to specify deformation paths in mesoscopic shear zones. It is difficult to obtain simple shear experimentally because of the role discontinuities play in deformation. In certain cases in natural shear zones the quartz grains may be subjected to a coaxial deformation path while the bulk deformation is progressive simple shear. Caution must therefore be exercised when attempting to use quartz fabrics to infer characteristics of the bulk kinematics or movement picture applicable during deformation. 相似文献
15.
Quartz fabrics in shear-zone mylonites: Evidence for a major imprint due to late strain increments 总被引:1,自引:0,他引:1
Maurice Brunel 《Tectonophysics》1980,64(3-4)
Geometrical relations between quartz C-axis fabrics, textures, microstructures and macroscopic structural elements (foliation, lineation, folds…) in mylonitic shear zones suggest that the C-axis fabric mostly reflects the late-stage deformation history. Three examples of mylonitic thrust zones are presented: the Eastern Alps, where the direction of shearing inferred from the quartz fabric results from a late deformation oblique to the overall thrusting; the Caledonides nappes and the Himalayan Main Central Thrust zone, where, through a similar reasoning, the fabrics would also reflect late strain increments though the direction of shearing deduced from quartz fabric remains parallel to the overall thrusting direction. Hence, the sense of shear and the shear strain component deduced from the orientation of C-axis girdles relative to the finite strain ellipsoid axes are not simply related nor representative of the entire deformation history. 相似文献
16.
龙门山冲断带北段前锋带新生代构造变形 总被引:3,自引:0,他引:3
龙门山北段前锋构造的地震剖面解释和前缘盆地内沉积地层的磁组构研究表明前锋构造中发育两期构造挤压作用,即整体强烈的晚三叠世变形和由北向南逐渐减弱的弱新生代构造变形。受这两期构造挤压作用的控制,龙门山北段前锋构造中发育上、下两套构造层,地表构造为晚三叠世时期形成,而深部隐伏构造则形成于新生代。北部的矿山梁和天井山构造几何学上表现为一个双重构造,浅层是一个晚三叠世形成的断层转折褶皱;深层是新生代形成的多个逆冲岩片叠置所构成的隐伏堆垛背斜;南部的青林口和中坝构造主体表现为叠瓦状逆冲,前锋构造是断层转折褶皱和断层传播褶皱。新生代构造冲断位移量以及造成早期构造抬升由北向南逐渐减小,反映新生代变形强度由北向南的减弱。磁组构研究表明新生代变形从龙门山冲断带边缘到盆地内部,磁组构从铅笔状磁组构到初始变形磁组构并逐渐过渡到沉积磁组构。由南向北磁组构由初始变形磁组构转变为铅笔状磁组构,说明应变越来越强,从而进一步证明了龙门山前锋新生代构造的弱变形作用和变形强度的北强南弱分布特征。 相似文献
17.
中天山北缘大型右旋走滑韧剪带研究 总被引:22,自引:4,他引:18
中天山北缘是一个近 EW向的大型右旋走滑韧剪带。宏、微观构造尺度的运动学研究表明 ,该带经历过至少二期韧性变形作用。第一期为从南向北的逆冲推覆韧剪变形 ,时代为中—晚志留世 ,以米什沟剖面为代表 ,对应于早古生代洋壳从北向南俯冲及稍后吐哈陆块朝中天山岛弧的碰撞事件。第二期为沿 EW方向的右旋走滑韧性变形 ,其构造形迹广泛分布于中天山北缘带各个地段 ;北天山石炭纪火山岩已卷入该期构造活动 ,走滑时代为晚石炭世—早二叠世 ,对应于晚石炭世塔里木与西伯利亚两大板块碰撞造山诱发的陆内变形、走滑剪切。走滑带中新生白云母 4 0 Ar/39Ar年龄为 ( 2 69± 5) Ma。剪切面理、拉伸线理、矿物韧剪构造、石英 C轴组构提供了构造运动学证据 ;地层不整合及同位素测年值提供了变形时间证据。二叠纪以后的构造事件也影响到中天山北缘带 ,但只有脆性变形形迹 ,无韧性剪切。最后对本区古生代构造演化进行了讨论 相似文献
18.
《Geodinamica Acta》2013,26(3-4):299-316
Western Anatolia (Turkey) is a region of widespread active N-S continental extension that forms the eastern part of the Aegean extensional province. The extension in the region is expressed by two distinct/different structural styles, separated by a short-term gap: (1) rapid exhumation of metamorphic core complexes along presently low-angle ductile-brittle normal faults commenced by the latest Oligocene-Early Miocene period, and; (2) late stretching of crust and, consequent graben evolution along Plio-Quaternary high-angle normal faults, cross-cutting the pre-existing low-angle normal faults. However, current understanding of the processes (tectonic quiescence vs N-S continental compression) operating during the short-time interval is incomplete. This paper therefore reports the results of recent field mapping and structural analysis from the NE of Küçük Menderes Graben—Kiraz Basin—that shed lights on the processes operating during this short-time interval. The data includes the thrusting of metamorphic rocks of the Menderes Massif over the Mio-Pliocene sediments along WNW-ESE-trending high-angle reverse fault and the development of compressional fabrics in the metamorphic rocks of the Menderes Massif. There, the metamorphic rocks display evidence for four distinct phases of deformation: (1) southfacing top-N ductile fabrics developed at relatively high-grade metamorphic conditions, possibly during the Eocene main Menderes metamorphism (amphibolite facies) associated with top-N thrust tectonics (D1); (2) top-S and top-N ductile gentle-moderatley south-dipping extensional fabrics formed at relatively lower-grade metamorphic (possibly greenschist facies) conditions associated with the exhumation of Menderes Massif along presently low-angle normal fault plane that accompanied the first phase of extension (D2); (3) moderately north-dipping top-S ductile-brittle fabrics, present configuration of which suggest a thrust-related compression (D3); and (4) south-facing approximately E-W-trending brittle high-angle normal faults (D4) that form the youngest structures in the region. It is interpreted that D4 faults are time equivalent of graben-bounding major high-angle normal faults and they correspond to the second phase of extension in western Anatolia. The presence of thrust-related D3 compressional fabrics suggests N-S compression during the time interval between the two phases of extension (D2 and D4). The results of the present study therefore support the episodic, two-stage extension model in western Anatolia and confirm that a short-time, intervening N-S compression separated the two distinct phases. 相似文献
19.
LIU Junlai TANG Yuan XIA Haoran GUO Qiang TRAN My Dung CAO Shuyun WU Hujun WU Wenbin ZHANG Zhaochong ZHAO Zhidan 《《地质学报》英文版》2010,84(6):1377-1390
<正>The Ailaoshan-Red River(ASRR) shear zone is one of the major Southeast Asian tectonic discontinuities that have figured the present tectonic framework of the eastern Tibet.Several metamorphic massifs are distributed linearly along the shear zone,e.g.Xuelongshan,Diancangshan, Ailaoshan and Day Nui Con Voi from north to south.They bear a lot of lines of evidence for the tectonic evolution of the eastern Tibetan at different crustal levels in different tectonic stages.Controversy still exists on the deformation structures,microstructures and their relationship with metamorphisms along the ASRR.In this paper detailed microstructural and EBSD(Electron Backscattered Diffraction) fabric analysis of some highly sheared granitic rocks from different massifs along the ASRR are conducted.High temperature structures and microstructures are preserved in unsheared gneisses,in weakly sheared xenoliths or in some parts of the highly sheared rocks(mylonites).Several types of high temperature quartz c-axis fabrics show symmetrical patterns or transitions from symmetrical to asymmetrical patterns.The former are attributed to coaxial deformation during regional shortening in an early stage of the Indian-Eurasian tectonic interaction and the latter are related to the transitions from coaxial compression to noncoaxial shearing during the post-collisional ASRR left lateral shearing. 相似文献
20.
通过野外地质调查、室内显微组构分析和磁组构测量,在桂北三门地区厘定出一条大型韧性剪切带;并利用热液锆石U-Pb定年约束其变形时代.三门韧性剪切带发育密集的透入性片理、旋转碎斑系、拉伸线理、眼球构造、书斜构造、A型褶皱、波状消光、机械双晶、核幔构造和S-C组构等宏观和微观韧性变形特征.磁各向异性度(P值)显示其走向呈NNE向,倾向呈NWW向.运动学指向显示早期具有左旋逆冲剪切,晚期具有右旋正滑剪切的运动学性质.磁化率椭球体扁率(E值)显示岩石变形以压扁型应变为主,暗示运动学方向以左旋逆冲剪切为主.镁铁质糜棱岩的热液锆石U-Pb定年结果为441±2 Ma,代表三门韧性剪切带的变形时代.在磁组构、运动学和年代学研究的基础上,结合区域地质资料,认为该韧性剪切带是华南加里东期华夏陆块由SE向NW逆冲到扬子陆块受阻后反冲作用的产物.这一认识揭示了扬子陆块和华夏陆块碰撞拼合的方式和时代,为深化华南加里东构造运动的认识提供了新的资料. 相似文献