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71.
72.
青藏块体及其周边地震活动 总被引:1,自引:0,他引:1
本文从青藏块体及其周边地区地震活动幕的划分入手,分析各期地震活动的图象特征,寻求本区地震发生的时空规律,探讨本区的地震活动与印度板块运动的内在联系,从而对今后本区地震活动的大形势进行了预测。 相似文献
73.
74.
新疆东准噶尔塔克扎勒—麦钦乌拉古缝合线的确定 总被引:1,自引:0,他引:1
本文通过构造分析及岩石学、地球化学研究,证实塔克扎勒—麦钦乌拉存在一条蛇绿混杂岩带,表现为在构造变形的砂泥质基质中分布若干个洋脊型和洋岛型的蛇绿岩碎块。该带两侧地壳厚度明显不同,大陆边缘增生方向相反,该带还是一条早古生代的生物群落界线,早石炭世两侧岛弧有较大的纬度差异(20°以上)。因此,塔克扎勒—麦钦乌拉蛇绿混杂岩带是古准噶尔大洋闭合的残骸,代表了西伯利亚板块和塔里木板块碰撞的缝合线构造带。 相似文献
75.
对于点苍山-石鼓变质带区域划分的意见 总被引:9,自引:7,他引:9
在以往的研究中,点苍山和哀牢山被认为是同一个变质带。对石鼓带的划分也有很大争议。本文通过岩石学和同位素年代学的研究,认为点苍山和石鼓变质带同为扬子基底的一部分,应属于滇东变质区。它们是在元谋-大红山群之上发育的一套中晚元古变质岩带,具陆内地台型火山-沉积的特点。 相似文献
76.
中生代期间,中国东部的构造演变具有从西向东不断发展,从南向北不断扩展的特点。正是这种从南向北的构造演变与潮湿气侯带由南向北的不断迁移相结合,决定了中生代聚煤作用不断地从南向北迁移。 相似文献
77.
A traverse through the western Kunlun (Xinjiang,China): tentative geodynamic implications for the Paleozoic and Mesozoic 总被引:13,自引:0,他引:13
The northern part of the western Kunlun (southern margin of the Tarim basin) represents a Sinian rifted margin. To the south of this margin, the Sinian to Paleozoic Proto-Tethys Ocean formed. South-directed subduction of this ocean, beneath the continental southern Kunlun block during the Paleozoic, resulted in the collision between the northern and southern Kunlun blocks during the Devonian. The northern part of the Paleo-Tethys Ocean, located to the south of the southern Kunlun, was subducted to the north beneath the southern Kunlun during the Late Paleozoic to Early Mesozoic. This caused the formation of a subduction-accretion complex, including a sizeable accretionary wedge to the south of the southern Kunlun. A microcontinent (or oceanic plateau?), which we refer to as “Uygur terrane,” collided with the subduction complex during the Late Triassic. Both elements together represent the Kara-Kunlun. Final closure of the Paleo-Tethys Ocean took place during the Early Jurassic when the next southerly located continental block collided with the Kara-Kunlun area. From at least the Late Paleozoic to the Early Jurassic, the Tarim basin must be considered a back-arc region. The Kengxiwar lineament, which “connects” the Karakorum fault in the west and the Ruogiang-Xingxingxia/Altyn-Tagh fault zone in the east, shows signs of a polyphase strike-slip fault along which dextral and sinistral shearing occurred. 相似文献
78.
华北板块南缘栾川群研究 总被引:7,自引:0,他引:7
栾川群出露于东秦岭北部。在栾川群分布区域,古华北板块不同时代的地层往南逆冲,构成北秦岭的太华推覆体。栾川群存在于该推覆体内部的特定逆冲岩席之中,沿这一逆冲岩席追索,确定古华北板块南缘的栾川群是连续沉积的,而受后期推覆构造的改造,栾川群在推覆体前缘的分布是断续相连的。根据地层之间的接触关系、岩浆活动、沉积作用的研究,对栾川群的划分提出了新的看法,认为栾川群由三川组、南泥湖组、煤窑沟组及大红口组构成。栾川群形成于震旦纪晚期,由湖坪及潮下斜坡等滨浅海沉积物构成。栾川群的岩浆岩为具双众数特征的岩套,具典型的大陆裂谷岩浆岩特征。并认为中元古代以来,古华北板块南缘处于裂陷拉张环境。早期的裂陷形成了熊耳群、汝阳群、官道口群及竞坪群,晚期裂陷的过程形成了栾川群、陶湾群,其进一步发育导致以二郎坪群为代表的洋壳生成。 相似文献
79.
丰城三溪峡——东乡石马岭推覆构造是扬子板块与华南板块的直接分界线 总被引:5,自引:0,他引:5
扬子板块与华南板以丰城三溪峡-东乡石马岭推覆构造分野。该推覆构造发育在萍乡-广丰深断裂与遂川-德兴深断裂的复合部位,具有可行-逆冲推覆性质。原地系统为扬子地层分区中元古界牛头岭组、高桥组和将军岭组,外来系统是华南地层分区新元古界源里组,分别相当于蓟县系修水组和青白口系上施组同期沉积。根据推覆变形形式、构造岩特征和变形程度,可将推覆体划分为包括糜棱岩亚带、糜棱岩化亚带在内的变形主带和劈理化带。韧性剪切变形与推覆变形同期产生,但影响范围更广泛。 相似文献
80.
Abstract: 3–D velocity images of the crust beneath the northern margin of the North China Plate have been constructed using P-wave travel time residuals of the latest earthquakes, with the data supplied by Chinese seismic networks.
The seismic image results indicate that there is a lateral heterogeneity in the crust beneath the northern part of the North China block. The velocity images of the upper crust show features closely related to the tectonic features on the surface. It can be seen from these velocity images of the vertical sections, and from the horizontal slice images at depths of 11 and 16 km that there exist East-West and North-East structures. The images indicate that the juncture zone of basin–and–range terrain is between the blue-colored high–velocity block corresponding to the Yanshan mountain range that developed during the Yanshan period in northwest Beijing and the green low-velocity area corresponding to the North China basin in southeast Beijing (Fig. 5). The juncture zone between high-velocity and low–velocity, and EW and NE fault zones have significant ore-control effects. From the chart of epicenters in the northern region of North China, we find that the epicenters of earthquakes are almost entirely distributed within the NE strip. Almost all major earthquakes took place in the transition strip between the high and low-velocity zones in the crust. The distribution of epicenters also reflects the strikes of known NE–faults. From the image sections along the latitude, we find that in the area between 114.0 E –118.0 E , there is a blue high-velocity block standing upright from the Moho to the upper crust (Fig. 6), from which can be deduced that some materials such as magma moved upward from the upper mantle during the history of its geological development. 相似文献
The seismic image results indicate that there is a lateral heterogeneity in the crust beneath the northern part of the North China block. The velocity images of the upper crust show features closely related to the tectonic features on the surface. It can be seen from these velocity images of the vertical sections, and from the horizontal slice images at depths of 11 and 16 km that there exist East-West and North-East structures. The images indicate that the juncture zone of basin–and–range terrain is between the blue-colored high–velocity block corresponding to the Yanshan mountain range that developed during the Yanshan period in northwest Beijing and the green low-velocity area corresponding to the North China basin in southeast Beijing (Fig. 5). The juncture zone between high-velocity and low–velocity, and EW and NE fault zones have significant ore-control effects. From the chart of epicenters in the northern region of North China, we find that the epicenters of earthquakes are almost entirely distributed within the NE strip. Almost all major earthquakes took place in the transition strip between the high and low-velocity zones in the crust. The distribution of epicenters also reflects the strikes of known NE–faults. From the image sections along the latitude, we find that in the area between 114.0 E –118.0 E , there is a blue high-velocity block standing upright from the Moho to the upper crust (Fig. 6), from which can be deduced that some materials such as magma moved upward from the upper mantle during the history of its geological development. 相似文献