共查询到18条相似文献,搜索用时 250 毫秒
1.
傅维洲 《吉林大学学报(地球科学版)》1996,(3)
概述了中国东北深震的时空分布、主应力优势方向以及深震区内的火山活动等特征。依据日本海沟到中国东北东部地震空间分布、震源机制解、俯冲板块的温度结构以及东北深震与海沟浅震的关联等大量资料,论述了中国东北深震是西太平洋板块高速度、小倾角向欧亚大陆下俯冲的结果。讨论了中国东北深震的板块构造意义。 相似文献
2.
笔者根据地壳表层地质构造和地震地质研究与地震测深和大地电磁测深成果,运用现代构造解析理论与方法,论证了汶川8.0级特大地震的深部构造环境,探讨了汶川8.0级特大地震震源区的地震断裂和震源断裂基本特征与相互关系,及其形成的地球动力学问题。笔者认为龙门山碰撞造山带深处隐伏壳幔韧性剪切带可能是汶川8.0级特大地震主震区的震源断裂,而地壳表层发育的映秀断裂带、北川断裂带和彭县—灌县断裂带等可能是汶川8.0级特大地震主震区的地震断裂,该区震源断裂与地震断裂既有显著区别,又有密切联系。研究表明,在印度板块与太平洋板块和菲律宾海板块对欧亚板块俯冲碰撞的动力学作用下,形成上扬子地块向青藏高原东缘碰撞—楔入以及青藏高原东缘向东仰冲,深部向东俯冲的动力学态势,造成龙门山碰撞造山带切割莫霍界面的壳幔韧性剪切带向中上地壳扩展,应力高度集中与能量快速释放破裂,从而引起汶川8.0级特大地震的发生,以及大型同震地表破裂带的形成。探索震源断裂与地震断裂区别与联系,对进一步研究地震机制与发震动力学以及防震减灾有重要意义。 相似文献
3.
2011 年3 月11 日日本东北地区太平洋海域发生Mw 9.0 级地震。日本海沟板块俯冲速率高,地震活动性强,因此研究
程度高,到目前为止已获得了覆盖日本海沟弧前区域的地震波剖面数据。本文利用8 条岩石圈结构剖面建立了日本海沟的
三维岩石圈结构模型。日本海沟岛弧地壳由上到下包含5 层:古近系-新近系-第四系海相沉积岩、白垩系海相沉积岩、
岛弧上地壳俯冲杂岩、岛弧下地壳和地幔楔;日本海沟北部还存在中地壳;洋壳是一个双层构造,上层为熔岩和席状岩墙群,
下层为堆晶辉长岩;陆壳和洋壳之间存在一个低速的板间层。本文在三维模型基础上讨论了俯冲板块的弯曲点和弯曲轴等
几何学特征,分析了日本海沟俯冲带的历史地震和日本东北Mw 9.0 级地震主震和余震的震源分布,日本东北地区的地震活
动与太平洋板块向日本岛弧下方的俯冲活动关系密切。 相似文献
4.
深源地震(deep earthquakes)对于研究地球内部结构及板块的运动、动力学机制等起着重要的作用。从和达清夫首次发现深源地震至今80多年的时间里深源地震得到了广泛关注,获得大批高质量的成果。但是,其成因机制至今仍然是未解之谜。目前,大家广泛接受以脱水脆裂为中源地震的成因机制,反裂隙断层为深源地震的成因机制。剪切失稳等机制也能对中源与深源地震的成因做出较好的解释,但仍需进一步的实验研究。中国东北珲春等地区位于环太平洋地震带上,也是中国唯一存在的深源地震带。对地表地质构造、矿物岩石物理学、深部探测和高温高压实验及数值模拟分析的综合研究是解决深源地震机制问题的有效途径。加强中国东北深源地震机理与西太平洋板块俯冲的研究,对进一步认识我国东部大地构造格局演化有着重要的深部背景意义。 相似文献
5.
深震等深线加深的梯度方向,反映了板块插入方向和板块俯冲力作用的主体方向;等深线凸进方向的动态变化,反映了贝尼奥夫带的偏转;日本海深源地震和我国东部地区浅震的个体(强震)和群体迁移,反映了深、浅部应力场强区的转移。这种转移的深层原因,可能与上地幔物质流流动方向变化有关。强区范围的圈定和转移规律,对地震的地点预报,具有重要意义。 相似文献
6.
7.
陈胜早 《大地构造与成矿学》2007,31(3):265-272
地震震源分布强烈依赖于构造环境的温度和压力条件。震源机制可使大陆地壳脆性-韧性转换带(下部稳定性过渡边界)的温压条件复杂化。该过渡边界伴随速度弱化作用(有震活动)向速度强化作用(无震活动)的转化。在岩石圈流变和壳幔动力学的基础上研究了与板块边界有关的地震活动,包括板缘地震和俯冲板片地震。俯冲带板缘地震的深度分布受约于脆性摩擦动力机制,而摩擦剪切机制不能满意地解释深震活动,包括俯冲板片地震。这是因为深震震源机制可能与高压、高温条件下的固一固相变有关,而用脆性破裂或摩擦作用来解释就不近合理。以理论与实验研究为依据,本文对与震源物理和震源分布有关的岩石圈流变特性进行了较为深入的论述。 相似文献
8.
俯冲带地震诱发机制:研究进展综述 总被引:4,自引:0,他引:4
俯冲带作为地球循环体系的关键部位,具有构造活跃、地震多发以及地质条件复杂等特征。基于震源位置,俯冲带地震既可划分为板间和板内地震,也可分为浅源、中源和深源地震。俯冲带内的浅源地震包括板间地震和浅源板内地震,而中源和深源地震皆属于板内地震。在地球浅部,温度与压力低,浅源地震是由岩石发生脆性破裂或沿着先存断层发生不稳定摩擦滑移造成的。随着深度增加,温度和压力的增加使得流行于浅部的脆性和摩擦行为在无水条件下被强烈抑制,岩石从而表现为可抑制地震的韧性行为,使得中-深源地震的诱发机制有别于常规的脆性行为。随着研究的逐渐深入,人们了解到中源地震的诱发机制主要是脱水或与流体相关的致脆以及塑性剪切失稳,而深源地震的成因主要是相变致裂。然而,中-深源地震很可能是两种或两种以上机制共同作用的结果。例如,在中源深度既可能是流体相关的致脆导致脱水源区的脆性围岩产生地震,亦可能是脱水的蛇纹岩本身可能在流体孔隙压的作用下作粘滑滑移,而前者比后者更为重要。孕震带宽度大于"反裂隙模型"预测的亚稳态橄榄石冷核宽度的深源地震可能是由第一阶段的相变致裂和第二阶段的塑性剪切失稳诱发,而孕震带的实际宽度与预测宽度相当的深源地震则可能仅由相变致裂引起。只要过渡带内名义无水矿物中的结构水能释放出来,脱水致脆同样可能触发一些深源地震;而塑性剪切失稳不仅能在中-深源地震触发后的扩展阶段起着主导作用,而且还能单独触发一些中-深源地震,因此能够解释大多数反复发生的中-深源地震活动。 相似文献
9.
日本列岛下太平洋俯冲板块的精细结构 总被引:1,自引:0,他引:1
尽管许多学者对日本列岛下的太平洋俯冲板块做了大量的研究,但板块内部的结构(比如板块厚度,板块内地震波速度随深度的变化以及洋壳的俯冲情况等)仍然不太清楚。利用日本地区密集台网收集到的中深和深发地震到时数据来探讨上述问题。采用三维射线追踪正演模拟法,首先利用333个远震计算得到了日本地区太平洋板块的厚度为85km;然后利用3283个地震(震源深度大于40km)的130227条P波到时进一步研究板块内部的精细结构。结果显示,沿深度方向6个地层段(间隔100km)内的速度扰动值分别为5.5%,4.0%,3.5%,2.5%,2.0%和6.0%,在40~500km范围内速度扰动随深度的增加而减小,这与温度随深度的变化情况相一致。当深度大于500km时,速度扰动突然增大到6.0%,分析认为该异常可能由发生在东亚大陆边缘下方的深发地震无法精确定位导致的。最后利用40~500km深度范围内的近震测试得到日本东北和北海道地区下方洋壳俯冲的深度均为110km,平均厚度分别为7.5km和5km,相对于一维模型的速度扰动分别为1%和-3%。这说明洋壳在俯冲到110km以深时,由于受温度和压力的影响,逐渐脱水、变质,直至与板块融合。通过分析震源与洋壳的位置关系,本研究认为北海道地区比东北地区下方的俯冲洋壳可能含有更多的流体(比如水),导致两地区洋壳内的速度相差如此之大。此外,因为日本南部与洋壳对应的区域多为海洋,观测台站较少,所以本研究无法测试得到该区域内的洋壳俯冲情况。 相似文献
10.
用震源机制分析长白山天池火山未来喷发的动力背景 总被引:1,自引:0,他引:1
把震源机制的分析结果和构造地质学的研究成果结合起来进行综合分析,来揭示长白山天池火山未来喷发的动力背景.深源地震的震源机制表明,西太平洋板块向我国大陆的俯冲作用,使研究区处于近E-W向的挤压状态.从浅源地震的震源机制分析发现,研究区平均最大主压应力方向为NEE-SWW向.构造地质学的研究显示,天池周边NWW向的断层在更新世晚期以来较发育.天池火山未来的喷发可能受西太平洋板块的俯冲作用及NWW向断裂的走滑活动控制.根据以上分析,提出了天池火山未来喷发的可能动力背景. 相似文献
11.
长白山火山的起源和太平洋俯冲板块之间的关系 总被引:6,自引:0,他引:6
近年来,尽管不同学科通过不同手段对长白山火山进行过广泛研究,然而,目前人们对它的起源仍不清楚。利用全球地震层析成像和区域层析成像结果,综合分析了长白山火山的起源。结果表明,它的起源既不同于夏威夷等板内热点火山,也不同于日本等岛弧火山,而是一种与太平洋俯冲板块在地幔转换带内的滞留和深部脱水等过程密切相
关的弧后板内火山。 相似文献
12.
We present the first seismic image of the upper mantle beneath the active intraplate Changbai volcano in Northeast Asia determined by teleseismic travel time tomography. The data are measured at a new seismic network consisting of 19 portable stations and 3 permanent stations. Our results show a columnar low-velocity anomaly extending to 400-km depth with a P-wave velocity reduction of up to 3%. High velocity anomalies are visible in the mantle transition zone, and deep-focus earthquakes occur at depths of 500–600 km under the region, suggesting that the subducting Pacific slab is stagnant in the transition zone, as imaged clearly by global tomography. These results suggest that the intraplate Changbai volcano is not a hotspot like Hawaii but a kind of back-arc volcano related to the deep subduction and stagnancy of the Pacific slab under Northeast Asia. 相似文献
13.
《Gondwana Research》2010,17(3-4):401-413
We present new pieces of evidence from seismology and mineral physics for the existence of low-velocity zones in the deep part of the upper mantle wedge and the mantle transition zone that are caused by fluids from the deep subduction and deep dehydration of the Pacific and Philippine Sea slabs under western Pacific and East Asia. The Pacific slab is subducting beneath the Japan Islands and Japan Sea with intermediate-depth and deep earthquakes down to 600 km depth under the East Asia margin, and the slab becomes stagnant in the mantle transition zone under East China. The western edge of the stagnant Pacific slab is roughly coincident with the NE–SW Daxing'Anling-Taihangshan gravity lineament located west of Beijing, approximately 2000 km away from the Japan Trench. The upper mantle above the stagnant slab under East Asia forms a big mantle wedge (BMW). Corner flow in the BMW and deep slab dehydration may have caused asthenospheric upwelling, lithospheric thinning, continental rift systems, and intraplate volcanism in Northeast Asia. The Philippine Sea slab has subducted down to the mantle transition zone depth under Western Japan and Ryukyu back-arc, though the seismicity within the slab occurs only down to 200–300 km depths. Combining with the corner flow in the mantle wedge, deep dehydration of the subducting Pacific slab has affected the morphology of the subducting Philippine Sea slab and its seismicity under Southwest Japan. Slow anomalies are also found in the mantle under the subducting Pacific slab, which may represent small mantle plumes, or hot upwelling associated with the deep slab subduction. Slab dehydration may also take place after a continental plate subducts into the mantle. 相似文献
14.
Deep slab subduction and dehydration and their geodynamic consequences: Evidence from seismology and mineral physics 总被引:14,自引:9,他引:5
We present new pieces of evidence from seismology and mineral physics for the existence of low-velocity zones in the deep part of the upper mantle wedge and the mantle transition zone that are caused by fluids from the deep subduction and deep dehydration of the Pacific and Philippine Sea slabs under western Pacific and East Asia. The Pacific slab is subducting beneath the Japan Islands and Japan Sea with intermediate-depth and deep earthquakes down to 600 km depth under the East Asia margin, and the slab becomes stagnant in the mantle transition zone under East China. The western edge of the stagnant Pacific slab is roughly coincident with the NE–SW Daxing'Anling-Taihangshan gravity lineament located west of Beijing, approximately 2000 km away from the Japan Trench. The upper mantle above the stagnant slab under East Asia forms a big mantle wedge (BMW). Corner flow in the BMW and deep slab dehydration may have caused asthenospheric upwelling, lithospheric thinning, continental rift systems, and intraplate volcanism in Northeast Asia. The Philippine Sea slab has subducted down to the mantle transition zone depth under Western Japan and Ryukyu back-arc, though the seismicity within the slab occurs only down to 200–300 km depths. Combining with the corner flow in the mantle wedge, deep dehydration of the subducting Pacific slab has affected the morphology of the subducting Philippine Sea slab and its seismicity under Southwest Japan. Slow anomalies are also found in the mantle under the subducting Pacific slab, which may represent small mantle plumes, or hot upwelling associated with the deep slab subduction. Slab dehydration may also take place after a continental plate subducts into the mantle. 相似文献
15.
Yonghong Duan Dapeng Zhao Xiankang Zhang Shaohong Xia Zhi Liu Fuyun Wang Li Li 《Tectonophysics》2009,470(3-4):257-266
Three-dimensional P-wave velocity structure beneath the Changbai and other intraplate volcanic areas in Northeast Asia is determined by inverting 1378 high-quality P-wave arrival times from 186 teleseismic events recorded by 61 broadband seismic stations. Low-velocity (low-V) anomalies are revealed beneath the Changbai, Longgan, Xianjindao volcanoes. High-velocity (high-V) anomalies are found in the mantle transition zone, where deep-focus earthquakes under Hunchun occur at depths of 500–600 km. The high-V anomaly reflects the deep subduction of the Pacific slab under NE Asia which may have contributed to the formation of the Changbai, Longgang, Xianjindao and Jingpohu intraplate volcanoes. A low-V anomaly is also revealed in the mantle transition zone, which may have a close relationship with the occurrence of deep earthquakes under the Hunchun area. Our results support the Big Mantle Wedge (BMW) model by Zhao et al. [Zhao, D., Lei, J., Tang, Y., 2004. Origin of the Changbai volcano in northeast China: evidence from seismic tomography, Chin. Sci. Bull. 49, 1401–1408; Zhao, D., Maruyama, S., Omori, S., 2007. Mantle dynamics of western Pacific and East Asia: insight from seismic tomography and mineral physics. Gondwana Res. 11, 120–131.] who proposed that the intraplate volcanoes in NE Asia are caused by the back-arc magmatism associated with the deep dehydration process of the subducting slab and convective circulation process in the BMW above the stagnant Pacific slab. 相似文献
16.
Dapeng Zhao Franko Pirajno Nikolai L. Dobretsov Lucy Liu 《Russian Geology and Geophysics》2010,51(9):925-938
We present seismic images of the mantle beneath East Russia and adjacent regions and discuss geodynamic implications. Our mantle tomography shows that the subducting Pacific slab becomes stagnant in the mantle transition zone under Western Alaska, Bering Sea, Sea of Okhotsk, Japan Sea, and Northeast Asia. Many intraplate volcanoes exist in these areas, which are located above the low-velocity zones in the upper mantle above the stagnant slab, suggesting that the intraplate volcanoes are related to the dynamic processes in the big mantle wedge above the stagnant slab and the deep slab dehydration. Teleseismic tomography revealed a low-velocity zone extending down to 660 km depth beneath the Baikal rift zone, which may represent a mantle plume. The bottom depths of the Wadati–Benioff deep seismic zone and the Pacific slab itself become shallower toward the north under Kamchatka Peninsula, and the slab disappears under the northernmost Kamchatka. The slab loss is considered to be caused by the friction between the slab and the surrounding asthenosphere as the Pacific plate rotated clockwise at about 30 Ma ago, and then the slab loss was enlarged by the slab-edge pinch-off by the hot asthenospheric flow and the presence of Meiji seamounts. 相似文献
17.
In this article, we review the significant recent results of geophysical studies and discuss their implications on seismotectonics, magmatism, and mantle dynamics in East Asia. High-resolution geophysical imaging revealed structural heterogeneities in the source areas of large crustal earthquakes, which may reflect magma and fluids that affected the rupture nucleation of large earthquakes. In subduction zone regions, the crustal fluids originate from the dehydration of the subducting slab. Magmatism in arc and back-arc areas is caused by the corner flow in the mantle wedge and dehydration of the subducting slab. The intraplate magmatism has different origins. The continental volcanoes in Northeast Asia (such as Changbai and Wudalianchi) seem to be caused by the corner flow in the big mantle wedge (BMW) above the stagnant slab in the mantle transition zone and the deep dehydration of the stagnant slab as well. The Tengchong volcano in Southwest China is possibly caused by a similar process in BMW above the subducting Burma microplate (or Indian plate). The Hainan volcano in southernmost China seems to be a hotspot fed by a lower-mantle plume associated with the Pacific and Philippine Sea slabs’ deep subduction in the east and the Indian slab’s deep subduction in the west down to the lower mantle. The occurrence of deep earthquakes under the Japan Sea and the East Asia margin may be related to a metastable olivine wedge in the subducting Pacific slab. The stagnant slab finally collapses down to the bottom of the mantle, which may trigger upwelling of hot mantle materials from the lower mantle to the shallow mantle beneath the subducting slabs and cause the slab–plume interactions. Some of these issues, such as the origin of intraplate magmatism, are still controversial, and so further detailed studies are needed from now. 相似文献
18.
Seismic activity associated with the subducting motion of the Philippine Sea plate beneath the Kanto district, Japan 总被引:1,自引:1,他引:1
Sadaki Hori 《Tectonophysics》2006,417(1-2):85
The Pacific plate and the Philippine Sea plate overlap and subduct underneath the Kanto region, central Japan, causing complex seismic activities in the upper mantle. In this research, we used a map selection tool with a graphic display to create a data set for earthquakes caused by the subducting motion of the Philippine Sea plate that are easily determined. As a result, we determined that there are at least four earthquake groups present in the upper mantle above the Pacific plate. Major seismic activity (Group 1) has been observed throughout the Kanto region and is considered to originate in the uppermost part of mantle in the subducted Philippine Sea plate, judging from the formation of the focal region and comparison with the 3D structure of seismic velocity. The focal mechanism of these earthquakes is characterized by the down-dip compression. A second earthquake layer characterized by down-dip extension (Group 2), below the earthquakes in this group, is also noted. The focal region for those earthquakes is considered to be located at the lower part of the slab mantle, and the Pacific plate located directly below is considered to influence the activity. Earthquakes located at the shallowest part (Group 3) form a few clusters distributed directly above the Group 1 focal region. Judging from the characteristics of later phases in these earthquakes and comparing against the 3D structure of seismic velocity, the focal regions for the earthquakes are considered to be located near the upper surface of the slab. Another earthquake group (Group 4) originates further below Group 2; it is difficult to consider these earthquakes within a single slab. The seismic activities representing the upper area of the Philippine Sea plate are Group 3. This paper proposes a slab geometry model that is substantially different from conventional models by strictly differentiating the groups. 相似文献