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41.
“八五”-“九五”期间秦岭的多项研究中,主要取得以下新认识:①创立了抽拉-逆冲岩片构造新理论,丰富和发展了岩石圈板块或壳块运动方式的多样性;②发现了东西向的秦岭造山带从显生宙以来有南北向的隆升带和沉积盆地,特别是太白、宝鸡-佛坪-汉南隆升带的发现,将从根本上改变秦岭乃至中国中东部构造格架的认识;③南北向沉积盆地转变为东西向造山带的Ⅱ型造山带,深部构造岩片抽拉-逆冲推覆在中(新)生代陆相沉积盆地之上所形成的Ⅲ型造山带,为地壳表层增添了两种新型的造山带;④提出秦岭造山带中存在3类沉积盆地,3种盆-山转换,3个发展阶段及3种型式(Ⅰ、Ⅱ、Ⅲ)的造山带;⑤重新厘定商丹带、勉略带和二郎坪带的构造属性、形成时代,首次提出秦岭受3种体制,4个发展阶段的新观点,由抽拉构造形成的陆内造山带是秦岭最重要的划时代发展阶段;⑥提出立交桥式结构观点;⑦发现了一批前震旦系变质地层结晶岩系,重新厘定了一些地层的时代,特别是西秦岭、西成铅锌矿田中元古代地层的发现和超大型厂坝矿床产于其中,有重大的理论和实际意义;⑧提出准浊流态流体的新概念;⑨提出中国和秦岭大地构造发展演化的新全球动力学理论。 相似文献
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板块碰撞造山模式难以解释造山作用在时间上的“滞后”和在空间上的“差位”现象,大量研究表明山脉隆升的动力来自深部,因此,探索深部地质过程的物理和化学机制及其导致的能量再分配是认识山脉隆升动力学机制的关键,若干线索表明地幔中的核反应中可能在岩石圈动力学演化过程中起过不可忽视的作用,通过分析U,Th等元素的地球化学性质及其在深变质过程中的行为,认为伴随板块俯冲发生的陆壳物质向地幔的再循环有可能在办流圈顶部形成富含U,Th,K等放射性亲石元素和碳质(石墨)的地质体,通过理论上的论证和对Oklo天然核反应堆遗迹的反演表明这些地质体可能有一部分具备了形成石墨核反应堆的条件。这种反应堆在亚临界状态下的断续运行有可能为其上方岩石圈中的岩浆作用提供热源,进入超临界状态时将可能导致深部核爆炸,成为地震,火山爆发和岩石圈破裂的动力来源,据此建立的山脉隆升的动力学初步模式,可以解释造山带的形成,高原的隆升,深源地震及其前兆的成因和金刚石及其相关岩石地壳浅部置位的机制。 相似文献
44.
燕山式板内造山作用在北京西山的 总被引:6,自引:0,他引:6
尽管在造山模式、成因机制方面存在分歧,但板内造山作用及其表现特征在现阶段业已引起众多学者的关注并进行了深入研究。受到燕山式板内造山带研究思路和成果的启示,经对比研究认为,北京西山地区在大地构造位置、大地构造属性及大地构造演化等方面具有板内造山的特征;逆冲推覆构造、变质核杂岩及独特的区域构造组合样式等构成了该区燕山式板内造山的基本地质构造要素;基于北京西山的地质实践,提出了对用板内造山的观点在该区深入研究若干新方向。 相似文献
45.
A Special Orogenic-type Rare Earth Element Deposit in Maoniuping, Sichuan, China: Geology and Geochemistry 总被引:8,自引:0,他引:8
Denghong WANG Jianmin YANG Shenghao YAN Jue XU Yuchuan CHEN Guangping PU Yaonan LUO 《Resource Geology》2001,51(3):177-188
Abstract: The Maoniuping REE deposit is the second largest light rare earth elements deposit in China, explored recently in the northern Jinpingshan Mountains, a Cenozoic intracontinental orogenic belt in southwestern China. It is a vein-type deposit hosted within, and genetically related to, carbonatite-alkalic complex. Field investigation and new geochemical data of the carbonatites from the carbonatite-alkalic complex support an igneous origin for the Maoniuping carbonatites and related REE mineralization. Carbonatite itself carries rare earth elements which were enriched by hydrothermal solution.
It is known that most of the REE deposits related to carbonatite-alkalic complexes were formed in relatively stable tectonic setting such as cratonic or rifting environment. The Maoniuping deposit, however, was formed during the processes of Cenozoic orogeny. Although the Maoniuping deposit is located in the north sector of the Panxi paleo-rift zone, the rift had been closed before early Cenozoic and evolved into an intracontinental orogenic belt, i.e., the Jinpingshan Orogen, which was formed since later Mesozoic to early Cenozoic. Geochronological and geochemical data also prove that the Maoniuping REE deposit was formed in an intracontinental orogenic belt instead of rift system or stationary block.
The Maoniuping REE deposit is similar to the Mountain Pass REE deposit in many respects such as the high contents of bastnaesite and barite, the low content of niobium, and the common occurrence of sulfides. The discovery of the Maoniuping deposit and other REE deposits during the past two decades suggest a good potential for prospecting REE deposits along the alkalic complex belt located on the eastern side of the Qinghai–Xizang–West Sichuan Plateau. 相似文献
It is known that most of the REE deposits related to carbonatite-alkalic complexes were formed in relatively stable tectonic setting such as cratonic or rifting environment. The Maoniuping deposit, however, was formed during the processes of Cenozoic orogeny. Although the Maoniuping deposit is located in the north sector of the Panxi paleo-rift zone, the rift had been closed before early Cenozoic and evolved into an intracontinental orogenic belt, i.e., the Jinpingshan Orogen, which was formed since later Mesozoic to early Cenozoic. Geochronological and geochemical data also prove that the Maoniuping REE deposit was formed in an intracontinental orogenic belt instead of rift system or stationary block.
The Maoniuping REE deposit is similar to the Mountain Pass REE deposit in many respects such as the high contents of bastnaesite and barite, the low content of niobium, and the common occurrence of sulfides. The discovery of the Maoniuping deposit and other REE deposits during the past two decades suggest a good potential for prospecting REE deposits along the alkalic complex belt located on the eastern side of the Qinghai–Xizang–West Sichuan Plateau. 相似文献
46.
Geometric and kinematic analysis was performed in an area located in the central part of the Seridó Belt (NE Brazil), where supracrustal rocks affected by polyphase deformation are well exposed. The first event recognized in this area (and regionally known as the D2 deformation) is characterized by top to the south thrust tectonics while a second one (D3 deformation) is marked by upright folds, strike-slip or transpressive shear zones and the development of flower structures. Major pegmatite swarms were emplaced during and late as regards the second event (dated ca. 580 Ma), being part of the Brasiliano orogeny; similar dyke swarms are known from the Nigerian Shield. These pegmatite swarms provide reliable kinematic markers of the late evolutionary stage of the Neoproterozoic Trans-Sahara-Borborema collisional belt. Mineralogical, geometric and kinematic features support two stages of pegmatite emplacement during the strike-slip event: (i) older, syn-D3 homogeneous pegmatites intruded mostly along lithological and structural discontinuities, such as foliation surfaces; (ii) late, D3 heterogeneous pegmatites were emplaced along tension gashes and other dilation structures. The heterogeneous pegmatites are economically more important, being exploited for precious metals and stones, as well as industrial minerals. 相似文献
47.
Collision orogeny at arc-arc junctions in the Japanese Islands 总被引:1,自引:0,他引:1
Abstract In the Japanese Islands, collision tectonics are operating at arc-arc junctions in three regions: Hokkaido, Central Japan and Kyushu. Hokkaido is situated at the junction of the Kuril and Northeast Japan Arcs. The Kuril fore arc sliver collides with the Northeast Japan Arc, and the lower crust of the Kuril Arc thrusts upon the fore arc of the Northeast Japan Arc in Hokkaido. Outcrops of the lower crust are observed in the Hidaka Mountains in the fore arc of the junction area. Central Japan is in the juncture area among the Northeast Japan, Izu-Bonin, and Southwest Japan Arcs. The Izu-Bonin arc is colliding against the Honshu mainland, which has been bent by the collision. Kyushu is a juvenile collision area between the Southwest Japan and Ryukyu Arcs. The fore arc of the Southwest Japan Arc is starting to underthrust beneath the Kyushu islands along the Bungo Strait, where shallow seismicity within the crust is active in terms of the collision. Collision tectonics are observed at most of the arc-arc junctions in the circum-Pacific orogenic belts and may be an important process contributing to the relatively rapid growth of new continental crust in subduction zones. 相似文献
48.
49.
A. Deutsch R. A. F. Grieve M. Avermann L. Bischoff P. Brockmeyer D. Buhl R. Lakomy V. Müller-Mohr M. Ostermann D. Stöffler 《International Journal of Earth Sciences》1995,84(4):697-709
The occurrence of shock metamorphic features substantiates an impact origin for the 1.85 Ga old Sudbury Structure, but this has not been universally accepted. Recent improvements in knowledge of large-scale impact processes, combined with new petrographic, geochemical, geophysical (LITHOPROBE) and structural data, allow the Sudbury Structure to be interpreted as a multi-ring impact structure. The structure consists of the following lithologies: Sudbury Breccia —dike breccias occurring up to 80 km from the Sudbury Igneous Complex (SIC); Footwall rocks and Footwall Breccia — brecciated, shocked crater floor materials, in part thermally metamorphosed by the overlying SIC; Sublayer and Offset Dikes, Main Mass of the SIC and Basal Member of the Onaping Formation (OF) — geochemically heterogeneous coherent impact melt complex ranging from inclusion-rich basal unit through a dominantly inclusion-free to a capping inclusion-rich impact melt rock; Grey Member of OF — melt-rich impact breccia (suevite); Green Member of OF — thin layer of fall back ejecta; Black Member of OF — reworked and redeposited breccia material; Onwatin and Chelmsford Formations — post-impact sediments. Observational and analytical data support an integrated step-by-step impact model for the genesis of these units. Analysis of the present spatial distribution of various impact-related lithologies and shock metamorphic effects result in an estimated original rim-to-rim diameter of the final crater of 200 or even 280 km for the Sudbury Structure, prior to tectonic thrusting and deformation during the Penokean orogeny. 相似文献
50.
Studies of the deformation styles, formation types and isotopic age data indicate that the Altaides has successively experienced 5 stages of orogeny: (1) the Kanas orogeny forming the angular unconformity between the Baihaba Formation (O_3) and the Habahe Group (Z-O_2); (2) the Daqiao orogeny (S_3-D_(1-2) giving rise to the early Hercynian quasi-aulacogen extensional continental crust of the area; (3) the Altay orogeny (middle-late Hercynian) leading to the oblique intracontinentai collision and the formation of large shear arc-shaped thrust system and representing a strong orogeny stage; (4) the pan-Altay orogeny (latest Hercynian-Indosinian) resulting in the uplifting and erosion of the mountains as a whole; (5) the Himalayan movement causing the rejuvenation of fault systems and block uplift of the Aitaides since the Cenozoic. 相似文献