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藏南隆子—措美一带夹持于藏南拆离系(STDS)和雅鲁藏布江缝合带(IYS)之间。印度与欧亚大陆的碰撞作用形成了该地区特殊的构造样式,由近东西向展布的藏南拆离系主拆离带和洛扎、绒布—隆子两条断裂带、一系列倒转复式褶皱以及两个穹窿构造组成。始喜马拉雅期印度板块与欧亚大陆发生大规模陆—陆碰撞,导致特提斯喜马拉雅前陆盆地发生大规模缩短,沉积盖层以藏南拆离系为底界自北向南大规模逆冲推覆、褶皱;新喜马拉雅期高喜马拉雅结晶岩系自北向南挤出;藏南拆离系主拆离带和洛扎、哲古两条次级构造带上盘地层是自南向北伸展的产物。 相似文献
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北喜马拉雅穹隆带雅拉香波穹隆的构造组成和运动学特征 总被引:21,自引:0,他引:21
雅拉香波穹隆构造位于北喜马拉雅穹隆带,由上、下两个拆离断层分割成3个构造层。下拆离断层以韧性变形为主,其下的糜棱状片麻岩和花岗岩体形成穹隆核部即下构造层;上拆离断层以脆性变形为主,其上为低级变质的西藏沉积岩系及基性岩墙群(上构造层);千糜岩和糜棱状片岩构成上、下两拆离断层间的中构造层。穹隆构造内经历3期运动,第1和第2期的线理具有统一的北北西—南南东倾伏向,前者仅保存于局部下构造层,代表上盘向南南东的运动学特征,为早期构造变形,成因尚待查明;第2期为穹隆内主导线理,代表穹隆统一的上盘向北北西的运动。第3期低透入性线理向穹隆外侧倾伏,代表垮塌下滑运动。雅拉香波穹隆下构造层与高喜马拉雅岩系相似,下拆离断层为主拆离断层,中构造层可能为西藏沉积岩系底部经拆离作用形成,所以下拆离断层可能是分割高喜马拉雅结晶岩系与西藏沉积岩系的藏南拆离系在北喜马拉雅的出露。雅拉香波穹隆早期(距今14.5Ma±)可能经历了沿藏南拆离系的北北西向拆离,后期(距今13.5Ma±)因岩浆底辟和剥蚀反弹而发生穹隆作用。 相似文献
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藏南特提斯喜马拉雅前陆断褶带新生代构造演化与锑金多金属成矿作用 总被引:9,自引:1,他引:8
特提斯喜马拉雅前陆断褶带由近东西向展布的藏南拆离系主拆离带和洛扎、绒布-哲古两条断裂带及一系列倒转复式褶皱组成,是始喜马拉雅期印度板块与欧亚大陆发生大规模陆-陆碰撞,导致特提斯喜马拉雅前陆盆地发生大规模缩短、沉积盖层以藏南拆离系为底界自北向南大规模逆冲推覆、褶皱,以及新喜马拉雅期高喜马拉雅结晶岩系自北向南挤出导致藏南拆离系主拆离带和洛扎、哲古两条次级构造带上盘地层自南向北伸展的产物.特提斯喜马拉雅前陆断褶带内的锑金多金属矿床在空间上具有明显的分带性,自北向南依次构成沙拉岗-查拉普锑金成矿带、错美-隆子锑铅锌多金属成矿带和拉康-错那银铅锌成矿带,其间分别以绒布-哲古和洛扎两个次级断裂带为界.矿体主要受褶皱翼部近东西向层间破碎带和近南北向构造带控制,成矿类型为浅成低温热液型,成矿时代为新喜马拉雅期.成矿作用与新生代构造演化和新喜马拉雅期岩浆活动关系密切.在新喜马拉雅期高喜马拉雅结晶岩系向南挤出过程中,特提斯喜马拉雅前陆断褶带沿着始喜马拉雅期形成的逆冲推覆构造带发生自南向北伸展,诱发地壳部分熔融,形成的岩浆沿构造带侵位,并促使沿构造带下渗地下水循环对流.当这些循环的地下水与沿构造带上升的岩浆期后含矿热液混合时,成矿流体的物理化学条件发生改变,成矿物质沉淀形成沿褶皱翼部近东西向层间破碎带和近南北向构造带分布的似层状、脉状和透镜状锑金多金属矿床. 相似文献
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藏南定日地区主中央冲断层与藏南拆离系的特征及其活动时代 总被引:5,自引:0,他引:5
低喜马拉雅结晶杂岩构成了北北东向阿伦背斜的核部,该背斜东、西两翼由高喜马拉雅结晶杂岩组成,这两者之间的界线为主中央冲断层(MCT1)。MCT1原为向南逆冲的韧性断层,后遭受北北东向褶皱作用而转变为正断层。高喜马拉雅结晶杂岩顶部被藏南拆离系下部的韧性正断层所截,与其上覆的北坳组分开,北坳组顶部又被一脆性正断层将其与上覆的藏南特提斯沉积岩分开。这条韧性正断层称为STD1.其上部的脆性正断层称为STD2。独居石U-Th-Pb测年结果和构造分析表明,藏南定日地区的高喜马拉雅结晶杂岩就是借助这2条韧性断层MCT1与STD1在大约13 Ma时从藏南中下地壳折返至地壳浅部的,然后再遭受近南北向的褶皱作用。 相似文献
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藏南康马拆离断层的构造特征及其活动时代 总被引:1,自引:0,他引:1
藏南康马穹窿是北喜马拉雅片麻岩穹窿的经典代表,穹窿内发育上、下两条拆离断层并将穹窿分为三个构造层,其中上拆离断层分隔了上构造层未变质/轻微变质的特提斯喜马拉雅沉积岩系和中构造层的石榴石二云母片岩,而下拆离断层,即康马拆离断层,分隔了中构造层的石榴石二云母片岩和下构造层的片麻状二云母花岗岩。受康马拆离断层的影响,其上下两盘靠近拆离断层面处的岩石遭受强烈的韧性变形改造,形成了糜棱岩化石榴石二云母片岩和花岗质糜棱岩,宏观构造解析以及构造岩的显微构造分析表明,康马拆离断层经历了上盘向北的伸展拆离。本次研究采用40Ar/39Ar定年方法,选择拆离断层带内糜棱岩化石榴石二云母片岩中同变形新生白云母进行年代学测定,结果显示白云母40Ar/39Ar坪年龄为13.23±0.15 Ma,结合宏微观岩石矿物学分析,认为其代表了向北伸展拆离的变形时间,即康马拆离断层的活动时代,该时代与康马穹窿南部的藏南拆离系的活动时代一致,从年代学上暗示二者可能为同一条拆离断层,是在不同区域的出露,但该结论仍然需要更多地质、地球物理等方面的证据来证实。 相似文献
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藏南洛扎地区洛扎断裂属于区域上定日—洛扎断裂的东段部分,是喜马拉雅造山带中一条重要的断裂,但其总体研究程度较低。运用地质填图和构造解析的方法研究了洛扎断裂的几何形态、运动表现和活动历史等,讨论其在喜马拉雅造山带构造格局形成中的意义。主要认识如下:(1)洛扎断裂现今主要表现为一条规模大的脆性-脆韧性断层,SWW—NEE走向,高角度倾向NNW。断层带内发育劈理带、断层泥、构造角砾岩等。运动性质主体表现为正断层。(2)洛扎断裂的南北两侧地块具有显著不同的变形特征,南侧为平缓的大型背斜-向斜构造,北侧为近NWW—SEE走向的倒转褶皱-断层构造。(3)洛扎断裂经历了多期活动,中生代正断活动,古近纪逆冲活动,中新世韧性伸展,中新世晚期逆冲活动以及上新世—第四纪正断活动。现今断层展示的更多是最后一期活动的形迹。(4)依据其规模大、多期活动性、两盘构造变形与沉积的系统差异性等肯定了其作为构造分区断层而存在。(5)洛扎断裂和藏南拆离断层(STD)在研究区均有出露,局部二者出露线近于重合,但洛扎断裂以高角度断面切割了平缓的STD。洛扎断裂是比STD具有更悠久地质历史的区域性断层,只是后者中新世以来的活动性更多受到关注。 相似文献
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本文采集藏南冲巴淡色花岗岩样品并进行系统的锆石LA-ICP-MS U-Pb和白云母~(40)Ar-~(39)Ar年代学分析。锆石U-Pb定年结果显示,冲巴淡色花岗岩年龄为12.4±0.4 Ma,处于前人划分的新喜马拉雅阶段与后喜马拉雅阶段分界处。结合淡色花岗岩沿藏南拆离系分布的特征,可将其归入新喜马拉雅阶段。冲巴淡色花岗岩为同构造侵位花岗岩,是藏南拆离系活动导致的构造减压熔融的产物,12.4±0.4 Ma的锆石U-Pb年龄代表了研究区藏南拆离系的活动时代。然而,这一活动时代明显滞后于喜马拉雅中西部地区,呈现自西向东启动时代和停止活动时代逐渐变晚的趋势;白云母~(40)Ar-~(39)Ar年代学分析表明,冲巴淡色花岗岩冷却年龄分别为9.11±0.25 Ma和9.62±0.10 Ma。锆石U-Pb和白云母~(40)Ar-~(39)Ar年代学计算表明,冲巴淡色花岗岩体从12.4 Ma到9.11 Ma发生了快速冷却剥露,冷却速率高达137~162℃/Ma,这一结果与前人通过变质P-T-t研究得到的快速折返的结论相吻合。综合前人研究成果,认为12.4~9.11 Ma的快速冷却事件可能与研究区藏南拆离系的大规模伸展拆离导致的构造剥露有关。 相似文献
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印度/亚洲碰撞形成的喜马拉雅增生地体由特提斯-喜马拉雅(THM)、高喜马拉雅(GHM)、低喜马拉雅(LHM)和次喜马拉雅(SHM)亚地体组成。通过喜马拉雅增生地体中变质基底和盖层的组成、变质演化、变形机制与形成时代的对比,确定高喜马拉雅(GHM)亚地体北缘的藏南拆离断裂(STD)向北延伸于特提斯-喜马拉雅(THM)亚地体之下,与形成在大于650°C温度、具有自南向北剪切滑移性质的康马-拉轨岗日拆离带(KLD)相连,深部地壳局部熔融、物质上涌造成的花岗岩侵位,使康马-拉轨岗日拆离带隆起,形成康马-拉轨岗日穹隆带。在高喜马拉雅(GHM)亚地体北部(普兰-吉隆-聂拉木-亚东一带)的变质基底与盖层之间发现EW向近水平的高喜马拉雅韧性拆离构造(GHD),以发育EW向拉伸线理、缓倾的糜棱面理及具有自西向东水平滑移为特征;而在GHM南部靠近主中央冲断裂(MCT)北侧发育具有挤压转换性质的韧性走滑-逆冲断层。高喜马拉雅亚地体从南到北具有由逆冲→斜向逆冲→EW向伸展→斜向伸展→SN向伸展的连续变形和转换的特征,是在现代喜马拉雅垂向挤出和侧向挤出的耦合造山机制下综合变形的响应。喜马拉雅地体中的东西向和南北向拆离构造的存在为喜马拉雅现代造山机制再讨论提供了基础。 相似文献
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The Ramgarh–Munsiari thrust is a major orogen-scale fault that extends for more than 1,500 km along strike in the Himalayan fold-thrust belt. The fault can be traced along the Himalayan arc from Himachal Pradesh, India, in the west to eastern Bhutan. The fault is located within the Lesser Himalayan tectonostratigraphic zone, and it translated Paleoproterozoic Lesser Himalayan rocks more than 100 km toward the foreland. The Ramgarh–Munsiari thrust is always located in the proximal footwall of the Main Central thrust. Northern exposures (toward the hinterland) of the thrust sheet occur in the footwall of the Main Central thrust at the base of the high Himalaya, and southern exposures (toward the foreland) occur between the Main Boundary thrust and Greater Himalayan klippen. Although the metamorphic grade of rocks within the Ramgarh–Munsiari thrust sheet is not significantly different from that of Greater Himalayan rock in the hanging wall of the overlying Main Central thrust sheet, the tectonostratigraphic origin of the two different thrust sheets is markedly different. The Ramgarh–Munsiari thrust became active in early Miocene time and acted as the roof thrust for a duplex system within Lesser Himalayan rocks. The process of slip transfer from the Main Central thrust to the Ramgarh–Munsiari thrust in early Miocene time and subsequent development of the Lesser Himalayan duplex may have played a role in triggering normal faulting along the South Tibetan Detachment system. 相似文献
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Peloponnesus in the south-western part of the Aegean is formed by a heterogeneous pile of alpine thrust sheets that was reworked
by normal faulting from Upper Miocene to recent times. Upper Miocene–Lower Pliocene extension in Mt Parnon was accommodated
by several mappable brittle detachment faults that exhibit a top-to-the-NE-ENE sense of shear. The hanging wall of the detachments
comprises a number of highly tilted fault blocks containing abundant evidence of intense internal deformation by normal faulting
and layer-parallel shearing contemporaneous with faulting. These fault blocks are remnants of a cohesive extensional block
that slipped to the NE-ENE and broke up along high-angle normal faults that sole into or are cut by the detachments. The largest
part of this block is located at the eastern edge of the metamorphic core forming the hanging wall of East Parnon high-angle
normal fault that excised part of the aforementioned detachments. The lowermost metamorphic Unit of the nappe-pile does not
seem to be affected by the previous extensional episode. Upper plate reconstruction shows that various units of the nappe-pile
were affected by high-angle normal faults that linked to detachment faults in the weaker layers. Since the Middle-Upper Pliocene
further exhumation of the metamorphic rocks has resulted in the formation of high-angle normal faults overprinting Neogene
extensional structures and cut the entire nappe-pile. This new fault system tilted the earlier extensional structures and
produced a NE-SW coaxial deformation of Mt Parnon. 相似文献
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《Journal of Asian Earth Sciences》2009,34(5-6):303-322
Analysis of fault system in the high-P/T type Sambagawa metamorphic rocks of central Shikoku, southwest Japan, shows that conjugate normal faults pervasively developed in the highest-grade biotite zone (upper structural level) in three study areas (Asemi river, Oriu and Niihama areas). These conjugate normal faults consist of NE–SW to E–W striking and moderately north-dipping (set A), and NNW–SSE striking and moderately east dipping (set B) faults. The fault set A is dominant compared to the fault set B, and hence most of deformation is accommodated by the fault set A, leading to non-coaxial deformation. The sense of shear is inferred to be a top-to-the-WNW to NNW, based on the orientations of striation or quartz slickenfibre and dominant north-side down normal displacement. These transport direction by normal faulting is significantly different from that at D1 penetrative ductile flow (i.e. top-to-the-W to WNW). It has also been found that these conjugate normal faults are openly folded during the D3 phase about the axes trending NW–SE to E–W and plunging west at low-angles or horizontally, indicating that normal faulting occurred at the D2 phase. D2 normal faults, along which actinolite breccia derived from serpentinite by metasomatism sometimes occurs, perhaps formed under subgreenschist conditions (ca. 250 °C) in relation to the final exhumation of Sambagawa metamorphic rocks into the upper crustal level. The pervasive development of D2 normal faults in the upper structural level suggests that the final exhumation of Sambagawa metamorphic rocks could be caused by “distributed extension and normal faulting (removal of overburden)” in the upper crust. 相似文献
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青藏高原东西向伸展及其地质意义 总被引:30,自引:4,他引:30
东西和南北向伸展是青藏高原最显著的地质特征之一。南北向伸展形成的东西走向伸展构造,主要包括藏南拆离系(STDS),和沿喀喇昆仑—嘉黎断裂带(KJFZ)发育的正断层体系。东西向伸展形成数目众多的南北走向伸展构造,它们切割青藏高原几乎所有的东西走向构造单元,包括羌塘地块、KJFZ和STDS等,说明东西向伸展以整体形式发生并同时波及整个青藏高原,而不是由以KJFZ和STDS为边界的不同地块的不均匀挤出所致。南北走向伸展构造在地表呈之字形,为南北向挤压形成的追踪张断裂;剖面上表现为被后期高角度正断层叠加的拆离断层,拆离断层形成于中-晚中新世而高角度正断层形成于上新世及以后。导致拆离断层的东西向伸展可能是南北向挤压的变形分解,后期高角度正断层作用可能是高原隆升后的垮塌所致。东西向伸展是控制青藏高原新生代浅色花岗岩和盆地形成的主要因素。 相似文献
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Analysis of fault system in the high-P/T type Sambagawa metamorphic rocks of central Shikoku, southwest Japan, shows that conjugate normal faults pervasively developed in the highest-grade biotite zone (upper structural level) in three study areas (Asemi river, Oriu and Niihama areas). These conjugate normal faults consist of NE–SW to E–W striking and moderately north-dipping (set A), and NNW–SSE striking and moderately east dipping (set B) faults. The fault set A is dominant compared to the fault set B, and hence most of deformation is accommodated by the fault set A, leading to non-coaxial deformation. The sense of shear is inferred to be a top-to-the-WNW to NNW, based on the orientations of striation or quartz slickenfibre and dominant north-side down normal displacement. These transport direction by normal faulting is significantly different from that at D1 penetrative ductile flow (i.e. top-to-the-W to WNW). It has also been found that these conjugate normal faults are openly folded during the D3 phase about the axes trending NW–SE to E–W and plunging west at low-angles or horizontally, indicating that normal faulting occurred at the D2 phase. D2 normal faults, along which actinolite breccia derived from serpentinite by metasomatism sometimes occurs, perhaps formed under subgreenschist conditions (ca. 250 °C) in relation to the final exhumation of Sambagawa metamorphic rocks into the upper crustal level. The pervasive development of D2 normal faults in the upper structural level suggests that the final exhumation of Sambagawa metamorphic rocks could be caused by “distributed extension and normal faulting (removal of overburden)” in the upper crust. 相似文献
16.
叠合盆地断裂上、下盘油气差异聚集效应及成因机理 总被引:12,自引:4,他引:12
断裂沟通叠合盆地不同层位、不同时代的烃源岩和生储盖组合,成为连接烃源岩和各种圈闭的重要渠道,导致形成了多种类型与断裂有关的油气藏。断裂上、下盘油气聚集差异现象十分普遍。通过剖析松辽盆地、柴达木盆地典型断裂带油气藏成藏条件,认为其根本原因是由于断裂上、下盘具有不同的地质特征和油气运聚成藏条件,它们往往具有互为消长的关系。油气富集在断裂的上盘还是聚集在断裂的下盘,主要取决于:断裂的作用,断距与储、盖层的厚度关系,断裂倾角,区域盖层之下断裂断开烃源岩或油气层的层数,断裂形成或活动时期与主力烃源岩排烃高峰时期的关系等 8个主要因素。 相似文献
17.
古董山断裂构造带位于塔里木盆地西部的巴楚隆起上,走向北西-南东,延伸140 km左右。基于地震剖面的详细解释,识别出4期构造变形:寒武-奥陶纪正断层、二叠纪正断层、中新世冲断层、上新世-更新世冲断层及其伴生的正断层。中新世基底卷入型冲断层是古董山构造带的主控断裂构造,构成断裂带的主体,构造变形样式为断层传播褶皱。寒武-奥陶纪正断层形成复式地垒,隐伏于中新世主干断层之下。二叠纪正断层可能伴生有岩浆活动。先存的正断层和岩浆岩对古董山中新世断裂活动具有明显的控制作用;后期的断裂活动,即上新世-更新世逆冲断层和正断层,对中新世形成的断裂构造有改造作用。古董山断裂带东南端与玛扎塔格构造带西端交汇,但两者不是同一条断裂带。 相似文献
18.
《Journal of Asian Earth Sciences》1999,17(5-6):683-702
The Thakkhola–Mustang graben is located at the northern side of the Dhaulagiri and Annapurna ranges in North Central Nepal. The structural pattern is mainly characterised by the N020–040° Thakkhola Fault system responsible for the development of the half-graben. A detailed study of the substrate and the sedimentary fill in several outcrops indicates polyphased faulting:-pre-sedimentation faulting (Miocene), with a mainly NNW–SSE to N–S compressional stress expressed in the substratum by N020–040° and N180–N010° sinistral and N130–140° dextral conjugate strike-slip faults;-syn-sedimentation faulting (Pliocene–Pleistocene), characterised by a W–E to WNW–ESE extensional stress and tectonic subsidence of the half-graben during the Tetang period (Pliocene probably), followed by a doming of the Tetang deposits and a short period of erosion (cf. Pliocene planation surface and unconformity between the Tetang and Thakkhola Formations); the Thakkhola period (Pleistocene) is characterized by a W–E to WNW–ESE extensional stress and a major subsidence of the half graben;-post-sedimentation recurrent extensional faulting and N–S and NE–SW normal faults in the late Quaternary terrace formations.Geodynamic interpretation of the faulting is discussed in relation to the following:
- 1.the geographic situation of the Thakkhola–Mustang half-graben in the southern part of Tibet and its setting in the Tethyan series above the South Tibetan Detachment System (STDS);
- 2.the geodynamic conditions of the convergence between India and Eurasia and the dextral east–west shearing between the High Himalayas and south Tibet;
- 3.the possible relations between the sinistral Thakkhola and the dextral Karakorum strike-slip faults in a N–S compressional stress regime during the Miocene.
19.
D. A. KELLETT D. GRUJIC C. WARREN J. COTTLE R. JAMIESON T. TENZIN 《Journal of Metamorphic Geology》2010,28(8):785-808
The South Tibetan detachment system (STDS) in the Himalayan orogen is an example of normal‐sense displacement on an orogen‐parallel shear zone during lithospheric contraction. Here, in situ monazite U(–Th)–Pb geochronology is combined with metamorphic pressure and temperature estimates to constrain pressure–temperature–time (P–T–t) paths for both the hangingwall and footwall rocks of a Miocene ductile component of the STDS (outer STDS) now exposed in the eastern Himalaya. The outer STDS is located south of a younger, ductile/brittle component of the STDS (inner STDS), and is characterized by structurally upward decreasing metamorphic grade corresponding to a transition from sillimanite‐bearing Greater Himalayan sequence rocks in the footwall with garnet that preserves diffusive chemical zoning to staurolite‐bearing Chekha Group rocks in the hangingwall, with garnet that records prograde chemical zoning. Monazite ages indicate that prograde garnet growth in the footwall occurred prior to partial melting at 22.6 ± 0.4 Ma, and that peak temperatures were reached following c. 20.5 Ma. In contrast, peak temperatures were reached in the Chekha Group hangingwall by c. 22 Ma. Normal‐sense (top‐to‐the‐north) shearing in both the hangingwall and footwall followed peak metamorphism from c. 23 Ma until at least c. 16 Ma. Retrograde P–T–t paths are compatible with modelled P–T–t paths for an outer STDS analogue that is isolated from the inner STDS by intervening extrusion of a dome of mid‐crustal material. 相似文献