共查询到20条相似文献,搜索用时 421 毫秒
1.
超高压变质岩生成问题中解决低密度大陆地壳深俯冲力学机制是一个关键问题。虽然俯冲地幔岩石可以裹携十几千米乃至几十千米尺度的陆壳块体到超高压变质深度,大规模的陆壳深俯冲需要特殊的构造条件。新西兰南岛北端研究表明,俯冲大洋板块能携带宽度达150km左右的窄条陆壳克服浮力达到超高压变质深度,而大陆板块碰撞的主体则浮在岩石圈上形成走滑断层。苏鲁-大别可能曾存在类似的构造条件:苏鲁西侧俯冲海洋板片首先拖曳苏鲁陆壳俯冲到超高压变质深度;随后大别以西俯冲大洋板片拖曳大别至超高压变质深度,而陆壳浮力导致苏鲁陆壳停止俯冲,飘浮的陆壳被北推而形成郯庐断裂;秦岭陆陆碰撞造山后大别超高压陆壳也折返;秦岭作为典型造山带,虽然不排除零星超高压变质的可能,但不具备大规模超高压变质的条件。 相似文献
2.
Intraplate compressional features, such as inverted extensional basins, upthrust basement blocks and whole lithospheric folds, play an important role in the structural framework of many cratons. Although compressional intraplate deformation can occur in a number of dynamic settings, stresses related to collisional plate coupling appear to be responsible for the development of the most important compressional intraplate structures. These can occur at distances of up to ±1600 km from a collision front, both in the fore-arc (foreland) and back-arc (hinterland) positions with respect to the subduction system controlling the evolution of the corresponding orogen. Back-arc compression associated with island arcs and Andean-type orogens occurs during periods of increased convergence rates between the subducting and overriding plates. For the build-up of intraplate compressional stresses in fore-arc and foreland domains, four collision-related scenarios are envisaged: (1) during the initiation of a subduction zone along a passive margin or within an oceanic basin; (2) during subduction impediment caused by the arrival of more buoyant crust, such as an oceanic plateau or a microcontinent at a subduction zone; (3) during the initial collision of an orogenic wedge with a passive margin, depending on the lithospheric and crustal configuration of the latter, the presence or absence of a thick passive margin sedimentary prism, and convergence rates and directions; (4) during post-collisional over-thickening and uplift of an orogenic wedge. The build-up of collision-related compressional intraplate stresses is indicative for mechanical coupling between an orogenic wedge and its fore- and/or hinterland. Crustal-scale intraplate deformation reflects mechanical coupling at crustal levels whereas lithosphere-scale deformation indicates mechanical coupling at the level of the mantle-lithosphere, probably in response to collisional lithospheric over-thickening of the orogen, slab detachment and the development of a mantle back-stop. The intensity of collisional coupling between an orogen and its fore- and hinterland is temporally and spatially variable. This can be a function of oblique collision. However, the build-up of high pore fluid pressures in subducted sediments may also account for mechanical decoupling of an orogen and its fore- and/or hinterland. Processes governing mechanical coupling/decoupling of orogens and fore- and hinterlands are still poorly understood and require further research. Localization of collision-related compressional intraplate deformations is controlled by spatial and temporal strength variations of the lithosphere in which the thermal regime, the crustal thickness, the pattern of pre-existing crustal and mantle discontinuities, as well as sedimentary loads and their thermal blanketing effect play an important role. The stratigraphic record of collision-related intraplate compressional deformation can contribute to dating of orogenic activity affecting the respective plate margin. 相似文献
3.
A large-scale collision at a plate boundary is expected to play an important role not only in the deformation at the boundary but also in the motion of the plate carrying the buoyant material to be accreted. Possible changes in rates and directions of such motions may be calculated provided that certain assumptions are made about the nature of the driving forces. In this model we shall assume basically that:
- 1. (1) an oceanic plate is driven by slab pull and ridge push, being resisted by basal asthenospheric drag and slab resistance; and
- 2. (2) because of detachment, slab pull is lost upon collision.
4.
《地学前缘(英文版)》2022,13(4):101399
The Pamir-Hindu Kush region at the western end of the Himalayan-Tibet orogen is one of the most active regions on the globe with strong seismicity and deformation and provides a window to evaluate continental collision linked to two intra-continental subduction zones with different polarities. The seismicity and seismic tomography data show a steep northward subducting slab beneath the Hindu Kush and southward subducting slab under the Pamir. Here, we collect seismic catalogue with 3988 earthquake events to compute seismicity images and waveform data from 926 earthquake events to invert focal mechanism solutions and stress field with a view to characterize the subducting slabs under the Pamir-Hindu Kush region. Our results define two distinct seismic zones: a steep one beneath the Hindu Kush and a broad one beneath the Pamir. Deep and intermediate-depth earthquakes are mainly distributed in the Hindu Kush region which is controlled by thrust faulting, whereas the Pamir is dominated by strike-slip stress regime with shallow and intermediate-depth earthquakes. The area where the maximum principal stress axis is vertical in the southern Pamir corresponds to the location of a high-conductivity low-velocity region that contributes to the seismogenic processes in this region. We interpret the two distinct seismic zones to represent a double-sided subduction system where the Hindu Kush zone represents the northward subduction of the Indian plate, and the Pamir zone shows southward subduction of the Eurasian plate. A transition fault is inferred in the region between the Hindu Kush and the Pamir which regulates the opposing directions of motion of the Indian and Eurasian plates. 相似文献
5.
The Qinling Orogenic belt has been well documented that it was formed by multiple steps of convergence and subsequent collision between the North China and South China Blocks during Paleozoic and Late Triassic times. Following the collision in Late Triassic times, the whole range evolved into an intracontinental tectonic process. The geological, geophysical and geochronological data suggest that the intracontinental tectonic evolutionary history of the Qinling Orogenic Belt allow deduce three stages including strike-slip faulting during Early Jurrassic, N-S compressional deformation during Late Jurassic to Early Cretaceous and orogenic collapse during Late Cretaceous to Paleogene. The strike-slip faulting and the infills in Early Jurassic along some major boundary faults show flower structures and pull-apart basins, related to the continued compression after Late Triassic collision between the South Qinling Belt and the South China Block along the Mianlue suture. Late Jurassic to Early Cretaceous large scale of N-S compression and overthrusting progressed outwards from inner of Qinling Orogen to the North China Block and South China Block, due to the renewed southward intracontinental subduction of the North China Block beneath the Qinling Orogenic Belt and continuously northward subduction of the South China Block, respectively. After the Late Jurassic-Early Cretaceous compression and denudation, the Qinling Orogenic Belt evolved into Late Cretaceous to Paleogene orogen collapse and depression, and formed many large fault basins along the major faults. 相似文献
6.
Spatial gaps in arc volcanism: The effect of collision or subduction of oceanic plateaus 总被引:2,自引:0,他引:2
One of the major processes in the formation and deformation of continental lithosphere is the process of arc volcanism. The plate-tectonic theory predicts that a continuous chain of arc volcanoes lies parallel to any continuous subduction zone. However, the map pattern of active volcanoes shows at least 24 areas where there are major spatial gaps in the volcanic chains (> 200 km). A significant proportion (~ 30%) of oceanic crust is subducted at these gaps. All but three of these gaps coincide with the collision or subduction of a large aseismic plateau or ridge.The idea that the collision of such features may have a major tectonic impact on the arc lithosphere, including cessation of volcanism, is not new. However, it is not clear how the collision or subduction of an oceanic plateau perturbs the system to the extent of inhibiting arc volcanism. Three main factors necessary for arc volcanism are (1) source materials for the volcanics—either volatiles or melt from the subducting slab and/or melt from the overlying asthenospheric wedge, (2) a heat source, either for the dehydration or the melting of the slab, or the melting within the asthenosphere and (3) a favorable state of stress in the overlying lithosphere. The absence of any one of these features may cause a volcanic gap to form.There are several ways in which the collision or subduction of an oceanic plateau may affect arc volcanism. The clearest and most common cases considered are those where the feature completely resists subduction, causing local plate boundaries to reorganize. This includes the formation of new plate-bounding transform faults or a flip in subduction polarity. In these cases, subduction has slowed down or stopped and the lack of source material has created a volcanic gap.There are a few cases, most notably in Peru, Chile, and the Nankai trough, where the dip of subduction is so shallow that effectively no asthenospheric wedge exists to produce source material for volcanism. The shallow dip of the slab may be a buoyant effect of the plateau imbedded in the oceanic lithosphere.The cases which are the most enigmatic are those where subduction is continuous, the oceanic plateau is subducted along with the slab, and the dip of the slab is clearly steep enough to allow arc volcanism; yet a volcanic gap exists. In these areas, the subducted plateau may have a fundamental effect on the physical process of arc volcanism itself. The presence of a large topographic feature on the subducting plate may affect the stress state in the are by increasing the amount of decoupling between the two plates. Alternatively, the subduction of the plateau may change the chemical processes at depth if either the water-rich top of the plateau with accompanying sediments are scraped off during subduction or if the ridge is compositionally different. 相似文献
7.
Tectonomagmatic similarities between the modern Chilean flat-slab region and pre-Neogene magmatic episodes suggest that they represent analogues to flat subduction. Evolutionary patterns in each magmatic suite include (i) increasing La/Yb ratios and Sr-and Nd-isotopic enrichment through time, (ii) eastward-migration of magmatism after periods of transpressional/transtensional intra-arc deformation, and (iii) subsequent termination and virtual absence of main-arc activity for 5–10 Myr. These patterns may reflect slab shallowing followed by flat subduction and thickening of the overlying crust. If repeated, they require interchanging episodes of slab steepening. Increasing convergence rates force slab kinking and eventual failure of the oversteepened slab, followed by rebound of the slab tip (owing to lack of further slab pull), flat subduction and termination of subduction-related magmatism. Rapid subduction leads to shallow overriding of the detached slab fragment. Eclogitization of the gradually steepening slab tip at depth and subsequent slab pull permits asthenospheric corner flow and subduction-related magmatism. 相似文献
8.
大洋俯冲和大陆碰撞沿走向的转换动力学及流体-熔体活动的作用 总被引:2,自引:1,他引:1
为了深入探讨大洋俯冲和大陆碰撞沿走向的转换及其动力学特征,同时更好的理解俯冲-碰撞带的流体-熔体活动及其效应,我们建立了一系列三维空间的大尺度、高分辨率的动力学数值模型。模拟结果显示,在板块会聚过程中,流体-熔体活动可以降低周围岩石的流变强度及两个板块之间的耦合作用,并能够促进大陆碰撞带俯冲板块的断离。同时,俯冲-碰撞带的空间转换模型揭示其深部结构存在巨大的沿走向的差异性,大陆碰撞带发生俯冲板块断离,而大洋俯冲板块持续下插。并且上覆板块的地壳物质发生从陆-陆碰撞带向洋-陆俯冲带的侧向逃逸。这种三维空间中沿走向的差异性俯冲-碰撞模式与中-东特提斯构造带相吻合,并揭示其动力学机制。 相似文献
9.
Daniel A. Gregori Jose Kostadinoff Guillermina Alvarez Ariel Raniolo Leonardo Strazzere Juan C. Martinez Mercedes Barros 《地学前缘(英文版)》2013,4(6):693-708
The Preandean geological configuration of the eastern North Patagonian Massif is established through the use of geological and geophysical analysis.The positive gravity anomalies located near the Atlantic coast are due to 535 and 540 Ma old rocks belonging to the Pampean Orogeny (Precambrian-middle Cambrian),which are widely recognized in central and northern Argentina.The Famatinian Cycle (Ordovician-Devonian) is represented by a Silurian-Devonian marine basin equivalent to those of eastern-central Argentina and South Africa,and which was deformed at the end of the Devonian byan~E-W to WNW-ESE compressional event,part of the Famatinian Orogeny.Containing strong gravity gradients,the NW-SE belt is coincident with fault zones which were originated during the Gondwanide Orogeny.This event also produced NW-SE overthrusting of the Silurian-Devonian sequences and strike-slip faults that displaced blocks in the same direction.This deformation event belongs to the Gondwanide Orogeny that includes movements related to a counterclockwise rotation of blocks in northern Patagonia.The strong negative anomalies located in the western part of the area stem from the presence of rocks of the Jurassic Ca(n)adón Asfalto basin interbedded in the Marifil Complex.These volcaniclastic sequences show mild deformation of accommodation zones in a pre-Jurassic paleorelief. 相似文献
10.
近期研究发现四川克拉通盆地内存在大型走滑断裂带,是断控油气藏勘探开发的有利新领域,走滑断裂的分布与成因对油气目标评价具有重要意义。本文在三维结合二维地震资料解释的基础上,分析走滑断裂的分布与成因类型,并探讨走滑断裂的形成机制。结果表明,川中三维地震工区发育北西向走向为主的大型板内走滑断裂系统;走滑断裂呈雁列、斜列的不连续的带状分布,断裂发育成熟度低,具有断裂样式的多样性与分层分布的差异性;四川盆地存在川中克拉通内走滑断层、川东南帚状走滑构造、川东调节走滑带、川东北楔入走滑带、川西北斜向冲断走滑带等5个地区发育5种类型走滑断裂带;走滑断裂形成于震旦系灯影组沉积晚期,受控于原特提斯洋俯冲背景下的斜向伸展作用,基底北西向先存断裂构造复活,形成了调节斜向伸展裂陷槽的川中板内走滑断裂系统。结果揭示克拉通盆地可能发育大型的板内走滑断裂系统,不同于常规的板缘与板内调节走滑断裂系统。 相似文献
11.
The Qinling Orogenic Belt in Central China is formed by an oblique continental collision between the North China and South China Blocks. In this review, we summarize the knowledge of the early Mesozoic magmatism, in combination with the coeval metamorphic characteristics, regional structural features and depositional history in the foreland and hinterland basins along the Qinling-Dabie Orogen. The early Mesozoic tectonic evolution of the Qinling is divided into four stages. Stage I (~250–235 Ma) is characterized by medium-K calc-alkaline magmatism in the western Qinling induced by slab roll-back. Meanwhile, ultrahigh-pressure metamorphism was triggered by continental subduction in the Sulu-Dabie, indicating a diachronous closure of the ocean. Stage II (~235–225 Ma) is recognized as a magmatic gap. Depositional variations of sedimentary facies and compressional deformations with an increased crustal thickness reflect the initial collision in the Qinling. Stage III (~225–210 Ma) is distinguished by a magmatic flare-up event. Abundant mantle-derived melts coupled with extensive crustal-derived melts were coeval with rapid uplift, strike-slip movement and regional crustal thickening in the Qinling as well as retrograde metamorphism in the Sulu-Dabie. The main tectonic driver was the propagating detachment of the subducted oceanic slab at gradually shallower depth from the Sulu-Dabie to the Qinling. Stage IV (~210–190 Ma) magmatism is dominated by high silica granites derived from metasedimentary rocks. The rapid denudation rates and extensional structures indicate gravitational collapse and regional delamination of the thickened crust. In addition to the strike-slip faults and block extrusion, the Qinling is characterized by asymmetric distribution patterns of magmatism and metamorphism, different melting mechanisms over time; diachronous depositions, differential uplift and non-uniform crustal thickening, and regional delamination of the thickened orogenic root. All these features are the result of the oblique collision, which is a common process in nature, and therefore could be applied to other orogens. 相似文献
12.
西秦岭勉略带陆内构造变形研究 总被引:12,自引:3,他引:9
秦岭造山带勉略缝合带是古特提斯洋盆向北俯冲形成的华北与华南最后拼接带。这个主缝合带俯冲-碰撞过程中以由北向南的一系列韧性逆冲推覆构造为特征,形成由前泥盆系、泥盆-石炭系和蛇绿混杂岩等不同构造岩片叠置的复杂构造带,碰撞时代从245Ma一直延续到230Ma左右。最近,作者对勉略缝合带内发育的韧性和脆性左行走滑剪切变形进行了研究,结果表明这些顺造山带的左行韧性走滑剪切变形带的变形时代为223±2Ma,与碰撞后花岗岩所确定的碰撞后构造环境的起始时间(225Ma)一致,显示这些韧性走滑剪切变形带是勉略带陆内变形初期变形产物。亦即华北、扬子大陆碰撞之后很快就转入陆内变形阶段,并且是以顺造山带的侧向走滑位移为主要变形方式。勉略带内顺造山带的脆性左行走滑断层的发育,表明这种顺造山带的侧向位移过程从深部到地壳浅层是一致的。因此,大陆碰撞在直接碰撞之后很快转变为顺造山带的侧向走滑位移为主的陆内变形,这种位移可能表现为两个大陆碰撞后的相对走滑,或是碰撞带中强烈变形部分顺造山带的侧向挤出,从而消减了正向碰撞所造成的地壳缩短和增厚。 相似文献
13.
Slab behaviour and its surface expression: new insights from gravity modelling in the SE-Carpathians 总被引:1,自引:0,他引:1
We use lithosphere-scale gravity models to calculate gravity anomalies resulting from oceanic subduction, continental collision, slab steepening, delamination, and break-off. Local isostasy was assumed for determining vertical movements caused by mass changes related to these tectonic processes. Our results show that subduction is accompanied by basin subsidence on the upper plate caused by the heavy lithospheric root of the subducting slab. The basin evolution goes parallel with the slab evolution and shows considerable modifications when the processes at depth change (slab steepening, delamination, break-off). Characteristic gravity anomaly curves were acquired for the different tectonic scenarios. These curves together with other data (e.g. basin evolution on the upper and the lower plate) were used for the reconstruction of the tectonic evolution of the SE-Carpathians which includes Tertiary subduction and collision followed by slab steepening and delamination. 相似文献
14.
缝合带是两个板块之间的分隔带,其规模和形态在不同类型的造山带中多有不同。本文从缝合带和缝合面的定义出发,以典型造山带为案例探讨缝合面的变形及其对造山带结构解析、沉积盆地性质判别的影响。俯冲阶段的主滑脱面是一个没有厚度的应变带,在碰撞后又作为增生杂岩的底界得以保留。这一界面严格区分了上盘和下盘沉积盆地之间的物源亲缘性,因而将之定义作为缝合面可有效帮助解析造山带不同位置盆地的性质。蛇绿岩带、高压变质岩带和大型断裂等线状要素仅能用以大致限定缝合带的位置,而不能用以精确限定缝合面的位置。不同于俯冲阶段相对平直的主滑脱面,缝合面的形态可以在碰撞过程中、甚至碰撞后被逆冲推覆和走滑所改造。在阿尔卑斯、喜马拉雅、东准噶尔等典型造山带中,缝合面都经历了向着前陆方向的远距离推覆及褶皱变形,这一变形的缝合面经历风化剥蚀过程后,在地表的形态呈复杂的指状交叉的特征,甚至由于飞来峰和构造窗的出现而呈现多个出露点。而在双向俯冲系统中,缝合面天然具有Z型的特征,经历后期变形后其形态会更加复杂。在苏鲁-大别造山带,多期次的后期变形叠加在早期的线状缝合面之上,特别是走滑断裂将包括缝合面在内的造山带切割为不连续的断夹块,极大地改造了缝合面在地表的出露形态。综上,在解析造山带结构,特别是进行沉积大地构造研究时,缝合面的复杂形态必须要得到重视。错误的缝合面位置可能造成错误盆地性质判断。 相似文献
15.
平坦俯冲及其成矿效应的研究进展、实例分析与展望 总被引:7,自引:4,他引:3
平坦俯冲是指上覆大陆板块之下大洋板片低角度近水平俯冲(俯冲角度<10°),全球10%的俯冲带为平坦俯冲.前人研究表明,安第斯许多大型-超大型斑岩铜矿和浅成低温热液型金矿与平坦俯冲具有直接的成因联系.同时平坦俯冲对造山作用、地震灾害、构造变形、壳幔相互作用等均具有重要的影响,因此开展平坦俯冲研究具有重要意义.本文主要从以下方面系统总结了平坦俯冲研究成果,包括平坦俯冲的主要表现、地质时期俯冲类型的转变、平坦俯冲的演化过程、平坦俯冲形成的可能机制,分析探讨平坦俯冲与增生型造山带之间可能联系、平坦俯冲与斑岩铜矿床的关系、以及平坦俯冲与洋中脊俯冲(板片窗)的区别,并介绍分析了北美Laramide造山带和华南中生代花岗岩带两个可能的平坦俯冲实例,最后给出平坦俯冲及其成矿效应的几点结论,并对我国今后开展相关研究提出了一些思考与展望,指出中亚造山带尤其是哈萨克斯坦巴尔喀什斑岩铜矿带及邻区和班公湖-怒江斑岩铜矿带构成两个潜在的古平坦俯冲发育区,斑岩铜矿极具潜力. 相似文献
16.
对郯庐断裂系研究的最新进展作了介绍。郯庐断裂是多期活动、性质多次转换的巨型断裂。最初的启动时间在晚三叠世末,与南北大陆的碰撞有着直接的关系。早期以走滑(左行)运动为主,伴随挤压和拉伸,范围限于华北地块内部。断裂纵向伸展的高峰期为白垩纪到早始新世,这一时期也是裂陷作用最强的时期。始新世以来以挤压作用为主。东亚走滑断裂系各组成断裂性质复杂,不能以中生代左行平移运动简单概括。走滑断裂系的发展和演化与同时期大陆边缘所处的地球动力学环境,也就是与南北大陆的碰撞和古大洋板块的持续俯冲关系密切。新生代以来的构造事件使中生代的构造发生强烈变形变位改造。 相似文献
17.
俯冲带作为板块构造最为重要的标志之一,是地球最大的物质循环系统,被称为“俯冲工厂”.俯冲作用是驱动和维持板块运动的重要动力引擎.一个完整的俯冲带发育海沟、增生楔、弧前盆地、岩浆弧、弧后盆地(或弧背前陆盆地)等基本构造单元.在一些特殊情况下(如洋脊俯冲、年轻洋壳俯冲、海山俯冲),则可形成一些特殊的俯冲带结构(如平板俯冲、俯冲侵蚀),导致岩浆弧、增生楔、弧前盆地等不发育甚至缺失.俯冲大洋板片可滞留于或穿越地幔过渡带进入下地幔甚至到达核幔边界,把地壳物质带入到地球深部,并通过地幔柱活动上升到浅部.俯冲带是构造活动强烈的区域,存在走滑、挤压、伸展等变形及其构造叠加.俯冲带海沟可向大洋或大陆方向迁移,岛弧及增生楔等也随之发生迁移,使俯冲带上盘发生周期性挤压和伸展,形成复杂的古地理格局.微陆块、岛弧、海山/洋底高原等地质体在俯冲带发生增生时,可阻塞先存的俯冲带,造成俯冲带跃迁或俯冲极性反转,在其外侧形成新的俯冲带.俯冲带深部精细结构、俯冲起始如何发生、板块俯冲与地幔柱的深部关联机制等是当前俯冲带研究中值得关注的前沿问题.开展俯冲带地球物理深部探测、古缝合带与现今俯冲带对比研究、俯冲带动力学数值模拟是解决上述科学问题的重要途径. 相似文献
18.
The shortening direction in rocks deformed in collision or subduction zones is not directly related to the plate-convergence vector; rather, it is perpendicular to the collision zone or subduction zone, even in cases where plate convergence is oblique. The component of convergence parallel to the subduction/collision zone is expressed by strike-slip displacement in the arc region behind the subduction zone. Such strike-slip shear zones have been recognized in the Seven Devils terrane of northeastern Oregon and adjacent Idaho. One of these (the Oxbow shear zone consisting of cataclasite, mylonite, and ultra-mylonite) trends northeasterly from Oxbow, Oregon to Cuprum, Idaho. The original rock types of the shear zone were plagiogranite, gabbro, diabase, bassalt, and keratophyre. The age of the mylonitization is constrained by 40Ar/39Ar dates as Late Triassic. Meso- and microscopic structures (textures and quartz c-axes fabrics) indicate that the shear zone was formed by left-lateral, strike-slip motion. A minimum left-lateral displacement of 65 km has been estimated, but the true displacement may have been much larger. The Oxbow shear zone is interpreted as an intra-arc strike-slip zone of the Seven Devils terrane, related to left-oblique plate convergence during the Triassic. 相似文献
19.
Matthew E. Brueseke Jeffrey A. Benowitz Alexander T. Bearden Michael Everett Mann Daniel P. Miggins 《地学学报》2023,35(1):49-57
Distinguishing the initiation of actual collision from flat-slab subduction of oceanic buoyant highs along convergent margins is elusive because both can lead to inboard deformation and disrupt magmatic arcs. Volcanoes with nascent tear magmatic signatures provide a means to document both the occurrence and timing of actual oceanic buoyant high collision. There is a ~40-year debate on when the true collision of the Yakutat plateau began in Alaska. Three newly identified ca. 1 Ma volcanoes with a north-to-south trench perpendicular orientation, nascent tear geochemical signatures, overlaying an imaged Yakutat slab tear, provide constraints on the timing of Yakutat collision and slab tearing. The ca. 1 Ma slab tear is coincident with Yakutat slab segmentation, northern continental Aleutian Arc rejuvenation, cessation of Wrangell Arc magmatism, increased collisional zone exhumation and eastern Yakutat trench abandonment. The documentation of nascent slab tear volcanoes may help resolve similar debates in other convergent margin settings. 相似文献
20.
斑岩Cu-Mo-Au矿床:新认识与新进展 总被引:59,自引:0,他引:59
斑岩型矿床作为一种最重要的铜钼和铜金矿床类型一直得到人们的普遍重视 ,近些年来又取得了重要研究进展 ,主要体现在 5个方面 :①岛弧和陆缘弧是斑岩型矿床产出的重要环境 ,但大陆碰撞造山带也具有产出斑岩型矿床的巨大潜力。按矿床产出的构造环境 ,可以分为弧造山型斑岩矿床和碰撞造山型斑岩矿床 ;②弧造山型含矿斑岩主要为钙碱性和高钾钙碱性 ,而碰撞造山型含矿斑岩则主要为高钾钙碱性和橄榄安粗质 (shoshonitic)。两种环境的含矿斑岩多具有埃达克岩 (adakite)岩浆亲合性 ,但前者主要来源于俯冲的大洋板片 ,后者主要来源于碰撞加厚的下地壳。大洋板片的部分熔融缘于俯冲角度的平缓化 ,而加厚下地壳的熔融起因于俯冲大陆板片的断离 (slabbreakoff) ;③在弧造山环境 ,大洋俯冲板片的膝折 (kink)或撕裂 (slabtear)不仅导致俯冲角度变缓 ,而且引起弧地壳耦合变形 ,产生切弧断裂 ,控制斑岩铜系统的时空分布。俯冲板片撕裂引发软流圈上涌 ,诱发大洋板片熔融 ,产生含矿岩浆 ;④在碰撞造山环境 ,大陆俯冲板片的裂离导致软流圈上涌 ,向下地壳注入新生物质 ,并诱发下地壳物质熔融 ,产生含矿岩浆。碰撞后地壳伸展形成横切碰撞带的正断层系统 ,为斑岩侵位提供运移通道 ,并导致岩浆流体大量分凝和铜钼金淀积。不论 相似文献