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20世纪90年代以来,人们正在探索建立一个统一的全球动力学体系及各圈层相互作用的热、物质运动机制。通过对地核、核幔边界、过渡带、岩石圈—软流圈地幔、地幔柱理论、壳幔边界和地壳内热、物质的交换和圈层流变运动方式等进行分析,讨论了地球各圈层之间存在的热与物质的交换机制以及底侵作用、拆沉作用和岩浆部分熔融作用等壳幔相互作用过程。认为壳幔作用过程表现为一种阶段式、递进式动力学和物理化学演化过程。壳幔相互作用不仅是大陆动力学演化的主要机制,而且与深部地幔的交代及上地壳变形、造山带、盆地形成和演化之间存在耦合过程。基于壳幔热和物质相互作用的研究可以对上地幔及更深层次的地质作用过程进行限定。 相似文献
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东北和华北地区上地幔成分和热状态对比及对中国东部岩石圈减薄的启示 总被引:3,自引:1,他引:3
地幔成分与其上覆地壳年龄存在相关关系,年龄越老,地幔越亏损玄武质组分。本文对产于东北和华北地区的尖晶石相橄榄岩包体的成分进行了统计分析,结果显示东北地区橄榄岩包体比华北地区包体更亏损玄武质组分。这说明东北岩石圈地幔比华北上地幔更难熔,但其上覆地壳年龄却远小于华北地区地壳的年龄。这种地壳年龄和地幔组分之间的解耦暗示东北和华北地区的岩石圈地幔形成之后发生了大规模的改造。华北地区的壳幔解耦与中生代岩石圈减薄和增生有关,而东北地区的壳幔解耦则是该区地壳的多期改造和中生代岩石圈减薄和增生等过程综合作用的结果。两地区地幔成分的差异显然与部分熔融程度的不同有关,但影响部分熔融程度的因素很多,目前尚不能确定。包体的平衡温度统计和地温线对比显示东北岩石圈的地温梯度低于华北的地温梯度,可能是东北地区岩石圈减薄的时间要早于华北地区,或者华北岩石圈减薄程度可能大于东北地区的结果,因此中国东部岩石圈减薄存在时空不均一性。 相似文献
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南海海盆区具有复杂的构造演化史,但目前对其深部结构的不对称性的研究和控制因素的探讨还存在不足.利用南海最新的重力数据和从27条地震剖面上获取的海盆范围沉积物精确数据计算了全海盆的剩余地幔布格重力异常(residual mantle Bouguer anomaly,RMBA),并反演了海盆的地壳厚度,运用Crust1.0数据进行了相关性分析.研究结果表明,南海海盆的残留扩张脊两翼在地形、RMBA和洋壳厚度上存在明显的不对称性,北翼比南翼有更多的海山分布、更低的RMBA值以及更厚的洋壳.这种明显的南北不对称性表明北侧比南侧有更高的地幔温度和更活跃的岩浆活动,反映了南海深部结构的不对称性.南海深部结构的不对称性可能与洋中脊向南的跃迁有关.洋脊跃迁导致在新老洋脊之间产生部分熔融,使扩张中心北侧产生更高的地幔温度,以及更强烈的岩浆活动,从而显示出更低的RMBA值和更厚的洋壳,并形成更多的后扩张期海山. 相似文献
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应用热爆裂质谱测量和高温熔融样品释气技术分别测定了山旺、栖霞和鹤壁新生代玄武岩中橄榄岩捕虏体中的橄榄石颗粒的流体和稀有气体组成。结果表明,鹤壁方辉橄榄岩具低于大气的~3He/~4He 比值0.778Ra 和大气成因的 Ne、Ar、Kr、Xe 组成。三个地区饱满地幔样品均以还原性流体为主,CO_2/~3He、N_2/~3He、N_2/Ar 比值分别为(0.62~4144)×10~9、(2631~64482)×10~6、269~73467。这些还原型流体偏离典型的幔源流体组成而表现出明显的碳和氮元素过剩,具有大气-地幔-壳源组份混合的特点,反映了大气和富含有机质的壳源组份在新生岩石圈上地幔中的影响。同时,这些饱满地幔样品的 Ne、Ar、Kr、Xe 具有大气属性,反映了大气型稀有气体在上地幔源区的广泛混染。其中,山旺和栖霞的~3He/~4He 比值分别为(2.91~3.07)Ra、(1.79~4.01)Ra,均高于大气低于 MORB,具有交代富集地幔的特点,而鹤壁则具有类似 MORB 的~3He/~4He 比值(7.03~7.05)Ra。这样的流体和稀有气体组成差别显示华北东部新生岩石圈地幔具亏损 MORB 型的特点并含壳源组份, 且其东缘所含壳源组份比例高于中部,说明华北东部新生岩石圈地幔中有俯冲洋壳组份的记录。 相似文献
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阐述了洋陆转化形成的洋内弧与初始弧的岩石组合序列及其地球化学特征,提出岩浆弧是由洋陆转化以及底侵的壳幔转化共同作用形成的认识,前弧环境是洋陆转化形成初生大陆的场所,由特征的类似洋中脊的洋内弧前弧玄武岩类构成。大陆的形成过程如下:从地幔中生长出洋壳,从洋壳中的洋陆转化生长出不成熟的弧陆壳,最后从弧陆壳底侵的壳幔转化中长出成熟的陆壳。这样,地壳的生长和形成主要通过岩浆增生作用来实现。 相似文献
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“三江”古特提斯地幔热柱——洋中脊玄武岩证据 总被引:26,自引:2,他引:26
“三江”特提斯巨型造山带由4条板块缝合带和夹于其间的微陆块和弧地体构成。在古特提斯洋闭合而成的澜沧江和金沙江缝合带内,均发育典型的蛇绿岩-蛇绿混杂岩和洋岛玄武岩(OIB)组合。OIB集中产出于大洋的特定区段(220-240N──澜沧江洋;240-270N──金沙江洋),形成于洋壳(MORB)顶部,并被浅水碳酸盐岩覆盖,OIB主要岩石类型为苦橄玄武岩、夏威夷岩和钾质粗面玄武岩,三者具特定的空间配置与时间演变规律。根据三江地区OIB时空展布规律、岩石组合特点、岩石地球化学特征、源岩化学估算及热幔柱实验成果,提出早古生代时期的澜沧江洋和金沙江洋岩石围下方分别出现地幔热拉,其直径约200-250km,具特定的不同于周围地幔的热-化学结构。地幔热柱的尾柱区高热物质熔融,产生苦橄质或苦橄玄武质熔浆,地幔热拉上涌,其冠形头部与周围地幔“混杂”而具化学分带,该区物质熔融,产生富Na和富K质OIB。 相似文献
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大洋地幔内部存在广泛的不均一性,其成因可有多种模式,其中俯冲循环作用对地幔组成的变化具有重要影响. 为明确各循环组分对亏损地幔的改造作用及其在富集源区中的相对贡献,系统总结了不同循环组分(远洋沉积物、俯冲洋壳、陆壳)的平均微量元素特征,计算了各循环组分在俯冲过程中经历的化学变化. 基于改造后的循环组分,开展与亏损地幔源区的混合和熔融模拟. 结果表明,HIMU型玄武岩可以由纯俯冲洋壳(≤10%)与亏损地幔(≥90%)混合形成的源区,经较低程度熔融(0.5%~1.5%)形成;而EMI型玄武岩可以由俯冲洋壳(≤10%)、俯冲剥蚀的下陆壳物质(≤3%)、亏损地幔(≥90%)混合形成的源区,经较低程度熔融(1%~2%)形成;EMII型玄武岩可以由俯冲洋壳(≤10%)、GLOSS-II(全球俯冲沉积物)或上陆壳物质(≤0.8%)与亏损地幔(≥90%)混合形成的源区,经较低程度熔融(1%~1.5%)形成. 相似文献
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西南次海盆位于南海渐进式扩张的西南端,共轭陆缘结构和残留扩张脊保留完整,是研究南海深部结构和动力学机制的关键区域。前期研究发现,西南次海盆洋陆过渡带较窄、同扩张断层发育、地震反射莫霍面不清晰、具有慢速扩张等特征。然而,由于不同探测方法获取的地壳结构具有多解性,使得西南次海盆洋陆转换过程、慢速扩张洋壳结构与增生模式以及龙门海山岩石性质与地幔成因机制等基础科学问题尚存争议。为此我们建议在西南次海盆开展地质取样获取海山岩石样品,确定其年龄与性质,分析扩张后海山形成的深部动力过程;并对关键构造部署高精度的地震反射/折射联合探测,结合岩石物理分析,对西南次海盆进行构造成像和物质组成参数正反演,以实现壳幔尺度的地震学透视,为探索西南次海盆洋陆转换过程和洋壳增生模式提供重要的地球物理证据,以丰富和完善南海的动力学演化模式。 相似文献
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Takeshi Hanyu Kenji Shimizu Takayuki Ushikubo Jun-Ichi Kimura Qing Chang Morihisa Hamada Motoo Ito HikaruIwamori Tsuyoshi Ishikawa 夏群科 《矿物岩石地球化学通报》2019,(2):216-216
正地球深部与表层间挥发性元素的交换一直是重要的地球科学问题。来自海水的挥发分通过热液蚀变作用进入大洋地壳,之后通过洋壳的俯冲作用进入上地幔。但是这些挥发分是否能够被带入更深的下地幔目前依然不清楚。Cl元素非常适合示踪俯冲物质中海水来源的挥发分。含有海水来源挥发分所形成的地幔源区具有很高的Cl含量,上地幔中Cl的不均一性被认为 相似文献
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The asthenosphere upwelled on a large scale in the western Pacific and South China Sea during the Cenozoic,which formed strong upward throughflow and caused the thermal structure to be changed obviously.The mathematical analysis has demonstrated that the upward throughflow velocity may have varied from 3×1011 to 6×1012 m/s.From the relationship between the lithospheric thickness and the conductive heat flux,the Hthospherie heat flux in the western Pacific should be above 30 mW/m2,which is consistent with the observed data.The huge low-speed zone within the upper mantle of the marginal sea in the western Pacific reflects that the upper mantle melts partially,flows regionally in the regional stress field,forms the upward heat flux at its bottom,and causes the change of the lithospheric thermal structure in the region.The numerical simulation result of the expansion and evolution in the South China Sea has demonstrated that in the early expansion,the upward throughflow velocity was relatively fast,and the effect that it had on the thickness of the lithosphere was relatively great,resulting in the mid-ocean basin expanding rapidly.After the formation of the ocean basin in the South China Sea,the upward throughflow velocity decreased,but the conductive heat flux was relatively high,which is close to the actual situation.Therefore,from the heat transfer point of view,this article discusses how the upward heat flux affects the lithospheric thermal structure in the western Pacific and South China Sea.The conclusions show that the upward heat throughflow at the bottom of the llthospheric mantle resulted in the tectonic deformation at the shallow crust.The intensive uplifts and rifts at the crust led to the continent cracks and the expansion in the South China Sea. 相似文献
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在中国区域大地构造研究中,对洋岛-海山/洋底高原的识别尚未引起足够重视.为深入研究中国大陆洋板块构造,系统回顾了洋岛-海山/洋底高原的基本概念、基本特征和增生造山过程.洋岛-海山/洋底高原是在海底扩张、大洋壳演化过程中由于地幔热点/柱作用形成的有异常厚度洋壳的区域,是大洋岩石圈的重要组成部分.洋岛-海山/洋底高原在垂向上具有典型的二元结构,下部以镁铁质、超镁铁质岩石为主,上部以碳酸盐岩建造为主.现今大洋盆地中大面积分布着正在演化中和正在俯冲的洋岛-海山,根据比较大地构造学原理,古洋岛-海山的存在指示古大洋盆地的存在,是研究造山带的重要载体.认为地史时期大洋盆地中有相当数量的洋岛、海山,在俯冲增生碰撞造山过程中保留下来的古洋岛-海山残块以构造岩片(块)形式夹持在俯冲增生杂岩中,随大洋盆地关闭;其作为缝合带的重要组成部分,是识别对接带的重要判别依据之一. 相似文献
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A. M. Nikishin 《Moscow University Geology Bulletin》2011,66(4):225-241
The Earth formed through a hot accretion process. Almost simultaneously, the core and the mantle were separated from each
other. At the final stages of the accretion process, the outer layer approximately 2000 km thick was molten, thus representing
a magma ocean. This magma ocean produced the primary crust of the Earth. Surface waters were precipitated from the atmosphere
and released from the crystallizing magma ocean. The plate tectonic processes started at around 4.3 to 4 Ga BP. In the Archean,
the overall tectonic mechanism was quite specific, due to substantially higher mantle temperature and thicker oceanic crust.
The normal plate tectonics acted during the Proterozoic and Phanerozoic with the periodic assembly of continents, which are
known as supercontinent cycles. 相似文献
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The structural setting beneath the Ligurian Sea resuJts from several tectonic events reflected in the nature of the crust. The central-western sector, called the Ligurian basin, is part of the northwestern Mediterranean. It is a marginal basin that was generated in Oligocene-Miocene time by subduction of the Adriatic plate beneath the European plate and by the eastward drift of the Corsica-Sardinia block. The eastern sector belongs to the Tyrrhenian basin system and is characterized by extensional activity which since Tortonian time superimposed an earlier compressional regime. Our effort has been addressed in particular towards simplifying the complex nature of the crust of the Ligurian basin by modelling its genesis using uniform extension and sea-floor depth variation with age. In the rift stage of the basin's evolution, the initial subsidence reaches the isostatic equilibrium level of the asthenosphere by a thinning factor of 3.15. The additional passive process, corresponding to the cooling of the lithosphere since 21 Ma, leads to a total tectonic subsidence of 3.4 km, representing the boundary of the extended continental crust. For values up to 4.1 km a transitional-type crust is expected, whereas for higher tectonic subsidence values a typical oceanic crust should exist. After setting these constraints, the boundaries of the different crust types have been drawn based on total tectonic subsidence observations deduced from bathymetry and post-rift sediment thickness. Although there is a general agreement with the previous reconstructions deduced from other experimental data, the oceanic realm has wider extent and more complex shape. The northernmost part of this realm shows crust of sub-oceanic type altemating basement highs with lower subsidence values. The observed surface heat flux is consistent with the predicted geothermal held in the Alpine-Provençal continental margin and in the oceanic domain. However, a characteristic thermal asymmetry is clearly visible astride the basin, due to the enhanced heat flux of the Corsica margin. Even if the uniform extension model accounts well at a regional level for the present basement depth, a remarkable tectonic subsidence excess has been found in the Alpine-Provençal continental margin. This evidence agrees with the reprise in compression of the margin; the direction of the greatest principal stress is N120°E on average. 相似文献
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CENOZOIC TECTONIC EVOLUTION AND GEODYNAMICS OF KEKEXILI BASIN IN NORTHERN QINGHAI—XIZANG PLATEAU 相似文献
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《Journal of African Earth Sciences》2010,56(5):257-264
The integrated use of geological, geophysical, and geochemical data from Eastern Tunisia onshore and offshore samples indicate a crustal thinning induced from the Tethyan rifting. This is responsible for the subsequent evolution of the North African passive margin during the Late Cretaceous, and the creation of the fold–thrust belt and associated foreland deformations. This thinned crust was an area of mantle upwelling that favoured the increase of isotherms, the uprise of basalt magma, and the circulation of hydrothermal fluids. The Cretaceous magmatism generated a major hydrothermal event characterised by the circulation of hot fluids along faults and a relatively high heat flow in the basin. Temperature elevation and hydrothermal conditions led to alteration of basalts and generated a new mineral equilibrium around the enclosing sedimentary deposits. 相似文献
17.
Cretaceous crustal thinning in North Africa: Implications for magmatic and thermal events in the Eastern Tunisian margin and the Pelagic Sea 总被引:2,自引:0,他引:2
H. Mattoussi Kort D. Gasquet M. Ikenne N. Laridhi Ouazaa 《Journal of African Earth Sciences》2009,55(5):257-264
The integrated use of geological, geophysical, and geochemical data from Eastern Tunisia onshore and offshore samples indicate a crustal thinning induced from the Tethyan rifting. This is responsible for the subsequent evolution of the North African passive margin during the Late Cretaceous, and the creation of the fold–thrust belt and associated foreland deformations. This thinned crust was an area of mantle upwelling that favoured the increase of isotherms, the uprise of basalt magma, and the circulation of hydrothermal fluids. The Cretaceous magmatism generated a major hydrothermal event characterised by the circulation of hot fluids along faults and a relatively high heat flow in the basin. Temperature elevation and hydrothermal conditions led to alteration of basalts and generated a new mineral equilibrium around the enclosing sedimentary deposits. 相似文献
18.
YINFuguang PANGuitang LIXingzhen 《大地构造与成矿学(英文版)》2003,27(1):145-155
After Rodinia supercontinent was disintegrated in Late Proterozoic, an ocean, namely, Tethys Ocean, occurred between Gondwana continental group and Pan-Cathaysian continental group from Late Proterozoic to Mesozoic. From Early Paleozoic to Mesozoic, Tethys Ocean was subducted toward Pan-Cathaysian block group, which results in backarc expansion, arc-land collision and forearc accretion. When the backarc basin expands and reaches the small oceanic basin, ophiolite melange will be generated. As accretion had already occurred in the south of the continental margin in the earlier stage, the succeeding backarc expansion and the frontal arc position were migrated toward south correspondingly. Therefore, multiple ophiolite belts and magmatic rock belts occurred, and show a trend of decreasing age from north toward south. As the continental margin was split and migrated toward south and reached a high latitude position, i.e., with the shortening and subduction of oceanic crust, the sedimentary bodies at high latitude was accreted continuously toward low latitude area together with the formation of oceanic island, mixing of cold-type and warm-type organism was generated. Moreover, blocks split and separated from Pan-Cathaysian or Gondwana continental group cannot traverse the oceanic median ridge and joins with another continental block. As a result, the Kunlun belt on the SW margin of the Pan-Cathaysian land was resulted from the multi-arc orogenesis such as the backarc seabed expansion, arc-arc collision, arc-land collision oceanic bed, and the continuous southward accretion process. 相似文献
19.
The 2-D density modeling of the sublatitudinal deep seismic sounding profile in the Tsushima Basin (Sea of Japan) was performed.
The available data allow us to presume that the opening of the Tsushima Basin took place under conditions of an anomalously
heated mantle that fostered emplacement of mantle material into the basinal crust and basin/continental margin transition
zone of the Korean Peninsula attended by formation of the oceanic crust. The increased (relative to the normal oceanic crust)
thickness of the basinal crust was conditioned by the accumulation of a large amount of terrigenous material and volcanogenic
rocks in the upper part of the crust and underplating of mantle material in the crustal base. 相似文献
20.
V. V. Zuev V. A. Semenov E. A. Shelekhova S. K. Gulev P. Koltermann 《Doklady Earth Sciences》2012,445(2):1006-1010
In this work, we evaluate the impact of terminated oceanic heat flux in the North Atlantic and Barents Sea on the Northern Hemisphere climate in January by numerical experiments with a coupled model of atmospheric general circulation and a thermodynamic model of the upper mixed layer of the ocean. We analyze the variations in the atmospheric circulation and near-surface temperature. We found that the termi-nation of the oceanic heat flux leads to a depression in atmospheric centers of action in the Northern Hemi-sphere (by 3?C5 hPa) and a significant cooling over the continents with the strongest temperature decrease down to ?10°C in northwestern Eurasia. 相似文献