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1.
北祁连山元古宙末-寒武纪主动大陆裂谷火山作用 总被引:10,自引:2,他引:10
北祁连山元古宙末-寒武纪大陆裂谷火山岩系为双峰式火山岩套,主要由基性与酸性火山岩组成。基性火山岩有磁性玄武岩与拉斑玄武岩两个岩浆系列,且富集LREE与LIL,其岩浆源区为与洋岛玄武岩源相似的富集地幔柱源。软流圈地幔柱上涌导致岩石圈地慢部分熔融,其熔体与地幔柱衍生熔浆混合,形成本区具有中等钕,锶同位素比值特点的基性岩浆。基性岩浆上侵至陆壳,引起下部陆壳深熔,产生长英质岩浆。地幔柱上隆促使大陆扩张,及至形成北祁连山元古宙末-寒武纪大陆裂谷。 相似文献
2.
Magmatism synchronous to the formation of passive margins of the North Atlantic is discussed. The main features and causes of the geochemical enrichment of the primary magmas at the margins have been established. This paper is based on the published data on the Norwegian-Greenland tectonotype of volcanic margins and the West Iberia-Newfoundland tectonotype of nonvolcanic margins. In the first tectonotype the hot rifting and active magmatism gave rise to the formation of a thick crust at the margin and the adjacent oceanic zone. The second tectonotype is characterized by cold amagmatic rifting and slow initial spreading, which led to the widespread occurrence of ancient continental complexes and serpentinized mantle rocks at the margin, as well as the thin and disturbed oceanic crust nearby. In order to characterize the magmatism and initial oceanic opening, the geological and geochemical data pertaining to the reference sections chosen for each margin were compared in detail. In particular, the geochemical and isotopic data on the flood basalts and suites of parallel dikes related to the pre- and synbreakup magmatic phases were involved for the Norwegian-Greenland region. The predominance of tholeiites enriched in lithophile elements and radiogenic isotopes, as well as a significant contribution of continental material to them, are typical of the volcanic margins. No less than two enriched magma sources for the lower part of the volcanic complex are suggested, whereas a depleted or slightly enriched source is established for the upper part. A more enriched source as compared with the volcanic margins of the Norwegian-Greenland region is suggested for the low-volume magmatic manifestations at the nonvolcanic Iberian margin. The tectonic settings of margins development and their relationships with the effect of deep plumes and the propagation of the extension zone toward the cold Atlantic lithosphere are discussed. 相似文献
3.
E. N. Melankholina 《Geotectonics》2011,45(4):291-301
The main features of the volcanic and nonvolcanic passive margins of the North and Central Atlantic are considered. The margins
are compared using rather well-studied reference tectonotypes as examples. The conjugate margins of the Norwegian-Greenland
region and the margins of West Iberia and Newfoundland are chosen as tectonotypes of volcanic and nonvolcanic margins, respectively.
The structural and magmatic features of the margins and their preceding history are discussed. A complex of interrelated attributes
is shown for each tectonotype. The Norwegian-Greenland region close to the Iceland plume is distinguished by narrow zones
of stretched continental crust, rapid localization of stretching with breakup of the continent, a high rate of subsequent
spreading, and intense magmatism with the formation of a thick new crust at the margin and the adjacent oceanic zone. The
Iberia-Newfoundland region, remote from the plumes, is characterized by wide zones of stretched continental crust, long-term
and diachronous prebreakup extension propagating northward, extremely restricted mantle melting during rifting and initial
spreading, and frequent occurrence of ancient crustal complexes and serpentinized mantle rocks at the margin. Crustal faults
and a thin tectonized oceanic crust appear along the margin under conditions of slow spreading. A model of hot and fast spreading
with a high degree of melting in the mantle is applicable to the Norwegian-Greenland region, whereas a model of cold and slow
amagmatic rifting with a long pre-breakup stretching and thinning of the lithosphere is appropriate to the Iberia-Newfoundland
margins. The differences in the development of the margins is determined by the interaction of many factors: deep temperature,
rheology of the underlying lithosphere, heterogeneities in the previously formed crust, and the duration and rate of stretching.
All of these factors can be related to the effect of deep plumes and propagation of the extension zone toward the segments
of the cold Atlantic lithosphere. Both types of margins also reveal similar features, in particular asymmetry. It is suggested
that the rotation forces superimposed on the general tectonomagmatic pattern controlled by plumes could have been the cause
of structural asymmetry. 相似文献
4.
E. N. Melankholina 《Geotectonics》2011,45(1):71-93
The tectonotype of nonvolcanic passive margins is discussed on the basis of data on the conjugate margins of West Iberia and
Newfoundland. Magmatic, structural, and historical aspects are considered. The Late Mesozoic structural elements related to
rifting and transition to spreading are considered, as well as the Early Mesozoic sedimentary basins that begin the history
of oceanic opening. The problem is set to determine the tectonic conditions of the early opening of the ocean in the framework
of the chosen tectonoptype. These conditions are compared with the setting at the volcanic margins. The formation of the conjugate
Iberia-Newfoundland margins is reconstructed as an asymmetric rift system developing in an almost amagmatic regime. All three
segments of the margins on both sides of the ocean reveal similar features of transverse zoning with zones of the tectonized
continental, transitional, and oceanic crust oriented nearly parallel to the margin. Special attention is called to the old
age of the continental crust and subcontinental mantle and the absence of newly formed crystalline crust; the stadial tectonic
and rheological evolution of the crust and lithospheric mantle; the specific features of the transitional zone; the serpentinization
and exhumation of mantle peridotites and their role in the development of detachment at the crust-mantle interface, related
listric faults and the Peridotite Ridge, attenuation of the medium, further localization of continental breakup, and the eventual
development of asymmetric conjugate margins. Two papers characterizing the tectonotypes of volcanic and nonvolcanic passive
margins ([2] and this paper) determine the line of further comparative analysis necessary for insights into the geodynamics
of ocean opening. 相似文献
5.
Laurent Geoffroy 《Comptes Rendus Geoscience》2005,337(16):575
Compared to non-volcanic ones, volcanic passive margins mark continental break-up over a hotter mantle, probably subject to small-scale convection. They present distinctive genetic and structural features. High-rate extension of the lithosphere is associated with catastrophic mantle melting responsible for the accretion of a thick igneous crust. Distinctive structural features of volcanic margins are syn-magmatic and continentward-dipping crustal faults accommodating the seaward flexure of the igneous crust. Volcanic margins present along-axis a magmatic and tectonic segmentation with wavelength similar to adjacent slow-spreading ridges. Their 3D organisation suggests a connection between loci of mantle melting at depths and zones of strain concentration within the lithosphere. Break-up would start and propagate from localized thermally-softened lithospheric zones. These ‘soft points’ could be localized over small-scale convection cells found at the bottom of the lithosphere, where adiabatic mantle melting would specifically occur. The particular structure of the brittle crust at volcanic passive margins could be interpreted by active and sudden oceanward flow of both the unstable hot mantle and the ductile part of the lithosphere during the break-up stage. To cite this article: L. Geoffroy, C. R. Geoscience 337 (2005). 相似文献
6.
Comparative tectonic analysis of passive margins of the Atlantic Ocean has been performed. Tectonotypes of both volcanic and nonvolcanic margins are described, and their comparison with other passive Atlantic margins is given. The structural features of margins, peculiarities of magmatism, its sources and reasons for geochemical enrichment of melts are discussed. The important role of melting of the continental lithosphere in the development of magmatism is demonstrated. Enriched EM I and EM II sources are determined for the lower parts of the volcanic section, and a depleted or poorly enriched source is determined for the upper parts of the volcanic section based on isotope data. The conclusions of the paper relate to tectonic settings of the initial occurrence of magmatism and rifting and breakup during the period of opening of the Mesozoic Ocean. It was found out that breakup and magmatism at proximal margins led only to insignificant structural transformations and reduction of the thickness of the ancient continental crust, while very important magmatic events happened later in the distal zone. New growth of magmatic crust at the stage of continental breakup is determined as a typical feature of distal zones of the margins under study. The relationship of development of margins with the impact of deep plumes as the source of magmatic material or a heat source only is discussed. Progradation of the zone of extension and breakup into the areas of cold lithosphere of the Atlantic and the formation of a single tectonomagmatic system of the ocean are under consideration. 相似文献
7.
The Xiong'er volcanic belt, covering an area of more than 60,000 km2 along the southern margin of the North China Craton, has long been considered an intra-continental rift zone and recently interpreted as part of a large igneous province formed by a mantle plume that led to the breakup of the Paleo-Mesoproterozoic supercontinent Columbia. However, such interpretations cannot be accommodated by lithology, mineralogy, geochemistry and geochronology of the volcanic rocks in the belt. Lithologically, the Xiong'er volcanic belt is dominated by basaltic andesite and andesite, with minor dacite and rhyolite, different from rock associations related to continental rifts or mantle plumes, which are generally bimodal and dominated by mafic components. However, they are remarkably similar to those rock associations in modern continental margin arcs. In some of the basaltic andesites and andesites, amphibole is a common phenocryst phase, suggesting the involvement of H2O-rich fluids in the petrogenesis of the Xiong'er volcanic rocks. Geochemically, the Xiong'er volcanic rocks fall in the calc-alkaline series, and in most tectono-magmatic discrimination diagrams, the majority of the Xiong'er volcanic rocks show affinities to magmatic arcs. In the primitive mantle normalized trace-element diagrams, the Xiong'er volcanic rocks show enrichments in the LILE and LREE, and negative Nb–Ta–Ti anomalies, similar to arc-related volcanic rocks produced by the hydrous melting of metasomatized mantle wedge. Nd-isotope compositions of the Xiong'er volcanic rocks suggest that 5–15% older crust has been transferred into the upper lithospheric mantle by subduction-related recycling during Archean to Paleoproterozoic time. Available SHRIMP and LA-ICP-MS U–Pb zircon age data indicate that the Xiong'er volcanic rocks erupted intermittently over a protracted interval from 1.78 Ga, through 1.76–1.75 Ga and 1.65 Ga, to 1.45 Ga, though the major phase of the volcanism occurred at 1.78–1.75 Ga. Such multiple and intermittent volcanism is inconsistent with a mantle plume-driven rifting event, but is not uncommon in ancient and existing continental margin arcs. Taken together, the Xiong'er volcanic belt was most likely a Paleo-Mesoproterozoic continental magmatic arc that formed at the southern margin of the North China Craton. Similar Paleo-Mesoproterozoic continental magmatic arcs were also present at the southern and southeastern margins of Laurentia, the southern margin of Baltica, the northwestern margin of Amonzonia, and the southern and eastern margins of the North Australia Craton, which are considered to represent subduction-related episodic outbuilding on the continental margins of the Paleo-Mesoproterozoic supercontinent Columbia. Therefore, in any configuration of the supercontinent Columbia, the southern margin of the North China Craton could not have been connected to any other continental block as proposed in a recent configuration, but must have faced an open ocean whose lithosphere was subducted beneath the southern margin of the North China Craton. 相似文献
8.
The subduction of spreading ridges creates a special geodynamic setting distinguished by the interference of convergent and
divergent boundaries between lithospheric plates and their long-term interaction accompanied by the formation of characteristic
geological complexes and structures. The available data on subduction of the contemporary Chile Ridge make it possible to
reconstruct such settings in the geological past. The subduction of the spreading ridge leads to uplift of the continental
margin, cut off the accretionary wedge by means of tectonic erosion, emplacement of a fold-thrust structure and longitudinal
strike-slip faults, and creates settings favorable for obduction of the young oceanic lithosphere. A lithospheric window expressed
in geological and geophysical features opens beneath the continental margin at the continuation of the ridge axis. The subduction-related
volcanic activity ceases above this window, giving way to specific proximal magmatism close to the boundary with the ocean and distal magmatism at a distance from this boundary. The proximal bimodal magmatism was related to the sources of tholeiitic basalts
characteristic of the ridge involved in subduction and to the partial melting of its oceanic crust and sediments. The distal
basaltic magmatism is a product of melting of the fertile oceanic asthenosphere ascending through the lithospheric window
with subsequent transformation of magma in the mantle wedge and the continental crust. The use of the Chilean tectonotype
for paleoreconstructions is limited by the diverse settings of ridge subduction. The Paleogene magmatism at the Pacific margin
of Alaska, where the kinematics of subduction was close to the Chilean subduction, is similar to the proximal igneous rocks
of Chile in composition and zoning, retaining some geological differences. Another aspect of the paleoreconstruction is discussed
on the basis of Jurassic and Cretaceous granitoids of the Ekonai Terrane of the Anadyr-Koryak System and terranes of southern
Alaska. These localities are known for a special, accretionary type of granitoids in the forearc region related to anatectic
magma formation without participation of the plunging ridge. Proceeding from comparison with the Chilean tectonotype, the
criteria for the identification of granitoids varying in their origin are considered. The effect of subducting ridges on continental
margins changed over geologic time and was subject to the rhythm of supercontinental cycles. 相似文献
9.
Rifts and passive margins often develop along old suture zones where colliding continents merged during earlier phases of the Wilson cycle. For example, the North Atlantic formed after continental break-up along sutures formed during the Caledonian and Variscan orogenies. Even though such tectonic inheritance is generally appreciated, causative physical mechanisms that affect the localization and evolution of rifts and passive margins are not well understood.We use thermo-mechanical modeling to assess the role of orogenic structures during rifting and continental breakup. Such inherited structures include: 1) Thickened crust, 2) eclogitized oceanic crust emplaced in the mantle lithosphere, and 3) mantle wedge of hydrated peridotite (serpentinite).Our models indicate that the presence of inherited structures not only defines the location of rifting upon extension, but also imposes a control on their structural and magmatic evolution. For example, rifts developing in thin initial crust can preserve large amounts of orogenic serpentinite. This facilitates rapid continental breakup, exhumation of hydrated mantle prior to the onset of magmatism. On the contrary, rifts in thicker crust develop more focused thinning in the mantle lithosphere rather than in the crust, and continental breakup is therefore preceded by magmatism. This implies that whether passive margins become magma-poor or magma-rich, respectively, is a function of pre-rift orogenic properties.The models show that structures of orogenic eclogite and hydrated mantle are partially preserved during rifting and are emplaced either at the base of the thinned crust or within the lithospheric mantle as dipping structures. The former provides an alternative interpretation of numerous observations of ‘lower crustal bodies’ which are often regarded as igneous bodies. The latter is consistent with dipping sub-Moho reflectors often observed in passive margins. 相似文献
10.
A. A. Peyve 《Geotectonics》2010,44(1):60-75
The magmatic and tectonic activity of eastern South America and the western South Atlantic shows that extension of the continental
crust is the determinant factor of magmatism. Heating of the upper mantle is a necessary condition of its manifestation. Ascending
plume material is a source of additional heat. In the Early Mesozoic, Eastern Brazil was situated above a large, ascending
and probably ramifying plume, which has supplied heat and material since the Triassic, creating favorable conditions for continental
magmatism. Magmatic activity continued, gradually waning, until the Neogene as evidence for long-term retention of heat energy
beneath the continental lithosphere after the plume ascent. It has been shown that heated mantle material can be displaced
from the continent to the ocean for a significant distance beneath the lithosphere with the formation of linear tectonomagmatic
rises of the oceanic crust. The structural elements inherited certain directions on the continent and in the ocean, beginning
from the Neoproterozoic. These directions were reactivated and continued to control the younger structural grain and magmatic
activity. In Southeastern Brazil, these were the structural units striking in the southeastern (about 120° SE) and northeastern
directions parallel to the continent-ocean boundary. In Northeastern Brazil, the W-E- and N—S-trending structural units are
predominant. All these directions are manifested in oceanic structural units (Rio Grande, Vitória-Trindadi, Fernando de Noronha,
Pernambuco rises, etc.). 相似文献
11.
Harro Schmeling 《Tectonophysics》2010,480(1-4):33-47
Active or passive continental rifting is associated with thinning of the lithosphere, ascent of the asthenosphere, and decompressional melting. This melt may percolate within the partially molten source region, accumulate and be extracted. Two-dimensional numerical models of extension of the continental lithosphere–asthenosphere system are carried out using an Eulerian visco-plastic formulation. The equations of conservation of mass, momentum and energy are solved for a multi-component (crust–mantle) and two-phase (solid–melt) system. Temperature-, pressure-, and stress-dependent rheologies based on laboratory data for granite, pyroxenite and olivine are used for the upper and lower crust, and mantle, respectively. Rifting is modelled by externally prescribing a constant rate of widening with velocities between 2.5 and 40 mm/yr. A typical extension experiment is characterized by 3 phases: 1) distributed extension, with superimposed pinch and swell instability, 2) lithospheric necking, 3) continental break up, followed by oceanization. The timing of the transition from stages 1) to 2) depends on the presence and magnitude of a localized perturbation, and occurs typically after 100–150 km of total extension for the lithospheric system studied here. This necking phase is associated with a pronounced negative topography (“rift valley”) and a few 100 m of rift flanks. The dynamic part of this topography amounts to about 1 km positive topography. This means, if rifting stops (e.g. due to a drop of external forces), immediate additional subsidence by this amount is predicted. Solidification of ascended melt beneath rift flanks leads to basaltic enrichment and underplating beneath the flanks, often observed at volcanic margins. After continental break up, a second time-dependent upwelling event off the rift axis beneath the continental margins is found, producing further volcanics. Melting has almost no or only a small accelerating effect on the local extension value (β-value) for a constant external extension rate. Melting has an extremely strong effect on the upwelling velocity within asthenospheric wedge beneath the new rift. This upwelling velocity is only weakly dependent on the rifting velocity. The melt induced sublithospheric convection cell is characterized by downwelling flow beneath rift flanks. Melting increases the topography of the flanks by 100–200 m due to depletion buoyancy. Another effect of melting is a significant amplification of the central subsidence due to an increase in localized extension/subsidence. Modelled magma amounts are smaller than observed for East African Rift System. Increasing the mantle temperature, as would be the case for a large scale plume head, better fits the observed magma volumes. If extension stops before a new ocean is formed, melt remains present, and convection remains active for 50–100 Myr, and further subsidence is significant. 相似文献
12.
被动大陆边缘:从大陆张裂到海底扩张 总被引:4,自引:0,他引:4
被动边缘是研究大陆张裂、破裂到海底扩张的关键。ODP103、149、173航次对伊比利亚-纽芬兰非火山型共轭边缘的研究,证实了洋陆过渡带和低角度拆离断层的存在,其中洋陆过渡带中广泛出现蛇纹岩化地幔橄榄岩,钻探结果支持不对称单剪模式。ODP104、152、163航次对挪威-格陵兰东南火山型共轭边缘的调查,揭示了典型的向海倾斜反射层(SDRS)的特征,反映了岩浆活动在边缘形成中的主导作用。为了进一步了解大陆从张裂到破裂到洋底扩张过程的一系列学术问题,需要在IODP阶段继续对共轭被动边缘以及包括冲绳海槽和南海在内的典型地区,通过钻探、采样和观测进行更深入的研究。 相似文献
13.
洋-陆过渡带是理解大陆岩石圈破裂和海底初始扩张的关键位置,但是在南海北部地区仍然存在关于相关地质过程的诸多疑问.通过近年开展的国际大洋发现计划航次以及深部地质地球物理探测,取得以下4个方面的认识.(1)南海北部的洋-陆边界一般与自由空间重力异常的正-负值过渡位置对应,而更加准确地限定需要结合反射、折射地震资料.稳定大洋岩石圈生成与大陆岩石圈最终破裂之间的洋-陆过渡边界的位置比以往认为的还应往深海盆方向移动.(2)洋-陆过渡带代表了远端带构造作用减弱和岩浆作用逐渐增强的区域.陆坡地壳发育扩张后岩浆底侵、洋-陆过渡带发育同破裂期岩浆喷出结构和侵入反射体.(3)在中生代的古俯冲带弧前区域,新生代的断裂沿着早期的构造开始活动,岩石圈多处发生强烈的共轭韧性剪切作用.随着大陆岩石圈的进一步拉伸减薄,部分靠陆一侧的裂谷中心停止张裂,成为夭折裂谷,以台西南盆地南部凹陷、白云凹陷、西沙海槽为代表,而南海陆缘异常伸展和最终破裂的地方集中在南侧裂谷中心.夭折裂谷下亦发现地幔蛇纹石化,进一步反映了较弱的同破裂岩浆活动.(4)南海初始洋壳的增生沿着大陆边缘走向具有显著的变化,南海东北部洋-陆过渡带下伏地幔明显抬升和部分蛇纹石化,地震纵、横波速度以及折射波衰减特征都支持此观点,反映南海东北部是一个贫岩浆型大陆边缘.未来,南海北部洋-陆过渡带有望成为南海“莫霍钻”的理想备选钻探区. 相似文献
14.
Numerical experiments reproduce the fundamental architecture of magma-poor rifted margins such as the Iberian or Alpine margins
if the lithosphere has a weak mid-crustal channel on top of strong lower crust and a horizontal thermal weakness in the rift
center. During model extension, the upper crust undergoes distributed collapse into the rift center where the thermally weakened
portion of the model tears. Among the features reproduced by the modeling, we observe: (1) an array of tilted upper-crustal
blocks resting directly on exhumed mantle at the distal margin, (2) consistently oceanward-dipping normal faults, (3) a mid-crustal
high strain zone at the base of the crustal blocks (S-reflector), (4) new ocean floor up against a low angle normal fault
at the tip of the continent, (5) shear zones consistent with continentward-dipping reflectors in the mantle lithosphere, (6)
the mismatch frequently observed between stretching values inferred from surface extension and bulk crustal thinning at distal
margins (upper plate paradox). Rifting in the experiment is symmetric at a lithospheric scale and the above features develop
on both sides of the rift center. We discuss three controversial points in more detail: (1) weak versus strong lower crust,
(2) the deformation pattern in the mantle, and (3) the significance of detachment faults during continental breakup. We argue
that the transition from wide rifting towards narrow rifting with a pronounced polarity towards the rift center is associated
with the advective growth of a thermal perturbation in the mantle lithosphere. 相似文献
15.
The history of the opening of the South Atlantic in Early Cretaceous time is considered. It is shown that the determining role for continental breakup preparation has been played by tectono-magmatic events within the limits of the distal margins that developed above the plume head. The formation of the Rio Grande Rise–Walvis Ridge volcanic system along the trace of the hot spot is considered. The magmatism in the South Atlantic margins, its sources, and changes in composition during the evolution are described. On the basis of petrogeochemical data, the peculiarities of rocks with a continental signature are shown. Based on Pb–Sr–Nd isotopic studies, it is found that the manifestations of magmatism in the proximal margins had features of enriched components related to the EM I and EM II sources, sometimes with certain participation of the HIMU source. Within the limits of the Walvis Ridge, as magmatism expanded to the newly formed oceanic crust, the participation of depleted asthenospheric mantle became larger in the composition of magmas. The role played by the Tristan plume in magma generation is discussed: it is the most considered as the heat source that determined the melting of the ancient enriched lithosphere. The specifics of the tectono-magmatic evolution of the South Atlantic is pointed out: the origination during spreading of a number of hot spots above the periphery of the African superplume. The diachronous character of the opening of the ocean is considered in the context of northward progradation of the breakup line and its connection with the northern branch of the Atlantic Ocean in the Mid-Cretaceous. 相似文献
16.
板块俯冲起始与大陆地壳演化 总被引:1,自引:0,他引:1
组成大陆地壳的物质主要来自两个地质过程:地幔柱活动和板块俯冲。目前大多数研究认为板块俯冲起始于30多亿年前。在板块俯冲起始之前,基性的初始地壳物质受热重熔是大陆地壳生长的主要方式,其中,地幔柱活动是关键。地幔柱不仅向地壳输送玄武质岩浆,同时导致已有玄武质岩石和沉积岩通过部分熔融向中酸性岩石转化。当原始岩石圈强度足够大时,地幔柱会导致岩石圈倾斜、破裂,产生下滑力,诱发板块俯冲。板块俯冲引发岩浆活动,产生大量的岩浆岩,如岛弧安山岩、弧后盆玄武岩等。这些岩浆岩通过喷发、侵位,再经由块体拼贴、增生等过程加入到大陆地壳,是大陆地壳生长的主要途径。同时,板内岩浆活动乃至地幔柱活动等也与板块俯冲有直接或者间接的联系。俯冲再循环物质促进地幔柱发育,也为大陆地壳的生长提供物源和热能。与此同时,大陆地壳不断风化剥蚀,其中一部分沉积物随俯冲板块再循环到地幔,而板块俯冲过程也通过俯冲剥蚀等过程,将仰冲盘岩石圈物质刮削带入地幔。这些是大陆地壳消减的主要途径。目前大陆地壳增生和消减基本处于动态平衡。 相似文献
17.
内蒙古喀喇沁早白垩世橄辉云煌岩岩筒 总被引:2,自引:0,他引:2
探寻地幔物质上涌的通道口,是大陆岩石圈研究所感兴趣的,它将为人们提供更多的岩石圈深部信息。本文报道的是在内蒙古喀喇沁黑龙潭火山颈中发现的橄辉云煌岩,其K-Ar同位素年龄为124Ma。火山活动明显受到中生代构造活动控制。火山岩的元素地球化学特征反映岩浆来自富集地幔,在源区存在陆壳的混染作用。 相似文献
18.
Models of continental flood basalt (CFB) formation are evaluated by examining their implications for the setting, mainly temperature and depth, of melting which is assumed to result from adiabatic decompression. Most attractive is the model of melting in upwelling bodies (probably plume heads) rising to the base of the continental lithosphere. This constrains the melting to 120–150 km or deeper (continental lithospheric thickness) and thus the plume potential temperatures to ≥ 300 °C higher than ambient mantle. The primary melts should be hot, MgO-rich, modified during ascent, and assimilate components of the lithosphere, which can provide the continental-like geochemical signature of many CFB. Circulation within the upwellings and presence of eclogite patches also influence magma generation and composition. Dehydration melting when plumes heat the lowermost lithosphere can generate CFB only if the source region contains ca. 15% hydrous minerals beneath the entire area covered by flood volcanics, which is difficult to justify. On the other hand, assimilation of “continental” chemical components from large parts of the lithosphere does not require such extreme metasomatism. Decompression melting under strongly thinned rifted lithosphere requires lower potential temperatures of the rising material and lesser modification of the primary magmas than the plume head model of CFB formation. Available observations do not support the contemporaneity of flood volcanism with rifts having the required sizes and histories, but more information is needed to further test this model. On the other hand, magma production can assist rift initiation and lithospheric rupture, so subsequent thinning can explain the common formation of volcanic rifted margins immediately following CFB emplacement. Ancient LIP should record the same processes as seen in young CFB. 相似文献
19.
Continental flood basalts (CFBs), thought to preserve the magmatic record of an impinging mantle plume head, offer spatial and temporal insights into melt generation processes in large igneous provinces (LIPs). Despite the utility of CFBs in probing mantle plume composition, these basalts typically erupt fractionated compositions, suggestive of significant residence time in the continental lithosphere. The location and duration of residence within the lithosphere provide additional insights into the flux of plume-related magmas. The NW Ethiopian plateau offers a well-preserved stratigraphic sequence from flood basalt initiation to termination, and is thus an important target for study of CFBs. This study examines modal observations within a stratigraphic framework and places these observations within the context of the magmatic evolution of the Ethiopian CFB province. Data demonstrate multiple pulses of magma recharge punctuated by brief shut-down events, with initial flows fed by magmas that experienced deeper fractionation (lower crust). Broad changes in modal mineralogy and flow cyclicity are consistent with fluctuating changes in magmatic flux through a complex plumbing system, indicating pulsed magma flux and an overall shallowing of the magmatic plumbing system over time. The composition of plagioclase megacrysts suggests a constant replenishing of new primitive magma recharging the shallow plumbing system during the main phase of volcanism, reaching an apex prior to flood basalt termination. The petrostratigraphic data sets presented in this paper provide new insight into the evolution of a magma plumbing system in a CFB province. 相似文献
20.
甘肃龙首山岩带西井镁铁质岩体成因及其构造意义 总被引:2,自引:0,他引:2
西井岩体位于北祁连造山带以北,阿拉善地块西南缘的龙首山隆起带。以往的研究多以沿龙首山断裂分布的镁铁-超镁铁质岩带作为和金川岩体相关的岩浆事件进行,而本次选择西井镁铁质岩体进行了精确的地质年代学和地球化学研究,确定了西井岩体岩性主要为橄榄辉石岩和辉长岩,成岩时代为 (421.0±9.0) Ma,可以和北祁连高压变质带榴辉岩年龄相对应;εNd(t)为4.06~5.52,(87Sr/86Sr)i为0.704 548~0.707 575,具有地幔岩石圈特征;微量元素及其同位素计算表明西井岩体经历了约10%的下地壳物质混染。据此得出西井岩体及其龙首山岩带早志留世镁铁质侵入岩体成因模式为:祁连洋壳连续俯冲过程中洋壳与陆壳分离,热的软流圈物质持续冲击地幔岩石圈的底部;由于热传导效应,大地热流沿着地幔岩石圈上升,使得80 km深度的湿的橄榄岩层发生熔融,产生玄武质岩浆作用,玄武质岩浆上升过程中与下地壳物质发生约10%混染,形成西井岩体及其龙首山镁铁超镁铁质岩带。 相似文献