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1.
利用双差地震定位方法对鄂尔多斯东缘地区(34°N-41°N,110°E-115°E)2008年1月-2012年12月的中小地震进行了重新定位.重定位后,定位精度得到改善,震中分布更加集中.鄂尔多斯东缘拉张盆地内部震源深度较浅,大多小于13 km,向盆地两端震源深度有加深的趋势,特别是太原盆地北端,临汾盆地北端,以及运城与临汾盆地之间的峨眉台地,震源深度可达20~25 km左右.我们认为盆地内部地壳减薄,上地幔上隆,热作用导致地壳内部脆性层减薄,致使最大震源深度变浅;盆地之间的横向隆起区受区域应力场挤压剪切作用以及盆地内部上地幔上拱产生的水平向挤压力作用等,在横向隆起区与盆地接触带易产生应力集中,导致地震的发生,由于受脆性层厚度变化等的影响,在盆地向横向隆起区过渡部位出现震源深度加深的现象.鄂尔多斯东北缘地区地震分布弥散、震源深度相对较浅,可能与源自地幔的大范围深部热作用以及地壳脆性层厚度减薄有关.根据地震的空间分布特征,对部分盆地内部的断层特征进行了讨论. 相似文献
2.
太原盆地的应力场特征 总被引:6,自引:0,他引:6
通过对太原盆地大量震源机制解资料的研究,揭示了该盆地的地壳应力场特征,认为其地壳应力场具有显著的局部小区域应力场特征,即以北西-北北西向水平拉张、北东-北东东向挤压作用为主,而震源类型多为走滑-近走滑,兼有一定的斜滑分量,指明该应力场控制着太原盆地的中小地震活动。得出太原盆地的平均应力场与华北区域应力场完全一致,太原盆地的地壳应力场及地震活动仍严格受华北区域应力场的作用与控制的结论。 相似文献
3.
环渤海地区位于华北克拉通的中东部,是岩石圈破坏和减薄的主要地区,同时也是我国大陆东部强震的多发区和油气田产区,一直是国内外学者研究的重点区域.本研究利用环渤海地区1980—2015年期间中国地震台网高质量Pn波到时数据,反演得到环渤海地区Pn波速度结构及各向异性.结果显示,环渤海地区上地幔顶部的Pn波速度结构存在明显的横向不均匀性,且与区域地质构造有一定相关性.在地形隆起区,如太行山隆起、燕山隆起、鲁西隆起、胶辽隆起及苏鲁褶皱带地区,呈现为低波速异常,说明这些隆起区下方的上地幔存在热物质上涌,而凹陷地区,如华北盆地、南黄海北部盆地和南黄海南部盆地,则表现为高波速异常,说明这些凹陷地区上地幔顶部岩石圈强度较大.地壳内强震主要发生于低波速异常区和高低波速异常过渡带上,说明华北地区地壳强震的发生有可能受到上地幔深部构造的影响.太行山造山带地区Pn波各向异性快波方向为近NNE向,苏鲁褶皱带区域的Pn波各向异性快波方向为近NE向,与断裂带的走向基本一致,表明在地壳形变剧烈的地区,可能受上地幔顶部的深部动力学影响较大.华北盆地的北部和南部各向异性方向存在差异,可能与岩石圈的厚度及热状态的不均匀性有关. 相似文献
4.
渤海位于北华北新生代裂陷盆地的东部,是一个晚第四纪形成的内陆海盆. 渤海盆地活动断裂发育,地震活动强烈,交会于渤海中部的NE向营口——潍坊断裂带北段、庙西北——黄河口——临邑断裂带及NW向北京——蓬莱断裂带是主要的活动构造带,将海区分成4个次级新构造区,成为现代应力场作用的构造基础. 综合研究38个震源机制解和75个井区应力场等资料,以及构造应力场二维数值模拟计算结果表明,渤海及其邻区现代构造应力场的压应力方向为NE60~90,张应力为SN——NW30;以水平和近水平应力作用为主;不同构造区主应力方向存在一定的差异. 现今渤海地区地壳发育以NNE——NE和NW——WNW走向的共轭剪切破裂为特征,是控制地震活动的主要构造. 相似文献
5.
华北东部地区上地幔运动与盆地形成关系的模拟研究 总被引:3,自引:0,他引:3
在综合分析华北东部深部构造、盆地构造及其动力学特征等资料的基础上,运用离心技术讨论了该区盆地形成机制与上地幔运动的关系。这种离心技术采用物质密度差代替温度差是一种新的实验方法。 实验结果表明,上地幔对流、上地幔隆起(或底辟)以及重力均衡作用产生了华北地壳的单向引张力,从而导致箕状盆地的形成。 作者认为,华北东部地区盆地形成和发展的动力源与上地幔的运动和重力作用密切相关 相似文献
6.
三维黏弹性数值模拟华北盆地地震空间分布与构造应力积累关系 总被引:2,自引:1,他引:1
华北盆地为我国板内地震多发区域,历史以来相继发生多次破坏性大地震.前人地震勘探与震源定位结果揭示了华北地震的空间分布特征:横向上,华北地震基本发生在地壳的薄弱地带(Moho面上隆),或者地壳厚度的急剧变化带;纵向上,华北地震在地壳一定深度范围内呈现成层分布特征;主震一般在上地壳底部9~15 km深度范围,余震多发生在大约深5~25 km的上地壳与中地壳范围内,在中地壳下层与下地壳中仅有少量或者鲜见有余震发生.为研究解释华北盆地地震空间分布的以上特征,本文建立了华北盆地岩石圈三维黏弹性有限元模型.震源机制和GPS反映华北盆地处于NNE最大主压应力方向挤压,因此对模型边界施以恒定的位移速率边界条件;数值模拟华北岩石圈各层位在数百年以上长期匀速构造挤压作用下的应力积累特征,分析了华北地震空间分布与构造应力积累速率的关系,探讨了地壳结构与地壳分层流变性质对地壳应力积累的影响.计算结果表明,Moho面的隆起与地壳各层位岩石介质的黏滞系数是华北盆地地震孕育的重要因素.华北盆地在构造挤压的持续作用下,Moho面隆起处产生明显应力集中现象.该区域应力在长时期的积累过程中,在脆性的上地壳与中地壳上层,应力表现近于线性增长趋势,上地壳底部较其它深度有最大的应力增长率,其主震可以在应力积累至岩石破裂强度时发生;在脆、韧性转换的中地壳下层,应力增长速率次之,华北地震的大部分余震可能在该层位为主震所触发;而在柔性的下地壳应力增长近于指数形式,稳定状态之后其应力增长速率近于零,而鲜有地震发生.地壳各层位的应力增长率差异与地震成层分布的现象揭示了华北地壳的分层流变性质:脆性(上地壳)-较弱脆性(中地壳上层)-较弱韧性(中地壳下层)-较强韧性(下地壳)-韧性(岩石圈上地幔)的分层流变结构. 相似文献
7.
通过区域地震和远震记录的走时残差,测定华北盆地中部和周围山区的三维弹性波速度结构。我们计算了1975年唐山地震的200个余震的P波和S波的走时残差,以及从1976年至1983年间北京台网记录的194个远震的P波走时残差。仅基于余震走时残差,我们完成了地壳和上地幔结构一维和三维的块状反演迭代。我们还基于远震走时残差以及把余震和远震走时残差相结合,完成了对地壳和上地幔的块状反演迭代。我们测定出华北盆地和周围山区的地壳平均厚度接近35km,然而华北盆地沿海岸部分的地壳厚度大约为32~33km。地壳上部大约20km的速度结构与地质露头完全相关,并且相似于表面地形的短波长(几十公里)特点。低地震速度的岩石在盆地之下而高地震速度的岩石存在于山区之下。地幔顶部,也许下地壳在内,好象是上地壳和地幔之间速度结构的过渡带。关于速度结构的相对高低趋势,地幔与地壳几乎完全相反,华北盆地下伏的大部分地幔物质具有比平均地震速度要高的速度,而西部山区之下物质的速度都低于平均速度。地幔速度结构与华北盆地的重力和地形的长波(成十到成百公里)特征显然相应。盆地之下的高速地幔物质或许说明了地幔过程与华北盆地无直接关系。我们推断,短波与长波速度特点之间的过渡带表明了岩石层与软流层无相互影响的范围。尤其是华北地块的岩石层相对软流层正在向东运动。 相似文献
8.
本研究拾取了中国数字测震台网固定台站记录的2008-2016年2级以上地震事件中的27233条高质量Pn到时资料,反演得到了郯庐断裂带及其邻区上地幔顶部Pn波速度和各向异性结构模型.结果显示,研究区上地幔顶部Pn波速度结构存在强烈的横向不均匀性,速度异常形态与区域地质构造较为吻合.太行山造山带、鲁西隆起、大别造山带、苏鲁褶皱带、胶辽隆起和华北盆地南端等隆起区表现为低波速异常,而黄海北、南部盆地、渤海湾和华北盆地北部等凹陷区均为高波速异常.壳内强震主要发生在Pn低波速异常和高低波速异常的横向过渡地带,说明强震的发生与上地幔结构的横向变化之间存在有一定关联.郯庐断裂带两侧Pn波速度以郯城地震为界其东北侧和西南侧分别分布有与断裂带近平行的低波速异常条带,而西北侧和东南侧分别分布有高波速异常条带,各向异性快波方向近乎沿断裂带走向,可能由于上地幔热物质沿郯庐断裂带上涌形成低速异常后断裂带发生左旋平移运动所致.华北盆地内上地幔顶部Pn波速度结构和各向异性的明显变化,反映华北克拉通破坏过程中经历了地幔热物质上涌、莫霍面隆升以及岩石圈拆沉等复杂构造变形. 相似文献
9.
邢台地震区深部构造背景的地震转换波探测和研究 总被引:14,自引:5,他引:14
1982-1986年期间,在东汪、隆尧和百尺口邢台地区的强震震源区完成了3条近NW向地震转换波测深剖面。利用转换波数据处理新方法,实现了转换震相的相位对比追踪,得出了震源区较详细的深部构造剖面图和速度结构模型。发现强震震源区深部构造的特点为:上地壳强烈褶皱变形;中地壳急剧减薄;下地壳和上地幔局部上隆;存在一组深部超壳断裂;低速层急剧增厚,波速比增大以及上地幔波速偏低。表明研究区的下地壳和上地幔的温度可能偏高,其地震活动可能与上地幔物质的侵入作用有关。 相似文献
10.
利用环渤海地区的天然地震P波到时资料,采用纬度和经度方向分别为05°×06°的网格划分,反演了该地区地壳上地幔的三维P波速度结构.初步结果表明,环渤海地区地壳上地幔的速度结构具有明显的横向不均匀性:京津唐地区地壳中上部的速度异常反映了浅表层的地质构造特征,造山带和隆起区对应于高速异常,坳陷区和沉积盆地对应于低速异常;地壳下部出现大规模的低速异常与华北地区广泛存在的高导层相对应,估计与壳内的滑脱层和局部熔融、岩浆活动有关;莫霍面附近的速度异常反映了地壳厚度的变化及壳幔边界附近热状态的差异;上地幔顶部大范围的低速异常可能是上地幔软流层热物质大规模上涌所致. 相似文献
11.
本文以地质与地球物理资料作为约束条件,利用小波多尺度分析方法,对首都圈地区重力场进行了有效分离,应用Parker位场界面反演法及变密度模型对莫霍界面进行了反演分析,并构建了两条地壳密度结构剖面模型,对该区精细地壳结构进行了深入研究.研究结果表明首都圈地区受多期构造运动的改造,形成坳、隆相邻,盆、山相间,密度非均匀性,壳内结构与莫霍面埋深相差比较大的地壳分块构造格局.受华北克拉通岩石圈伸展、减薄以及岩浆的上涌底侵作用,首都圈地区莫霍面起伏比较大,莫霍面区域构造方向呈NE-NNE方向,在盆地向太行山、燕山过渡地带形成了莫霍面陡变带;盆地内部莫霍面形成东西向排列、高低起伏的框架,最大起伏约5 km,但平均地壳厚度比较小,北京、唐山地区地壳厚度最小约29 km,武清凹陷地壳厚度最大约34 km.在重力均衡调整作用下,西部太行山区地壳厚度较大,但地壳密度小于华北裂谷盆地内部;中上地壳重力场特征与地表地形及地貌特征具有很大的相关性.受新生代裂谷作用影响,首都圈中上地壳结构非常复杂,形成了NNE方向为主体的构造单元,断层多下延至中地壳;下地壳发生明显的褶曲构造,表现出高低密度异常相间排列的典型特征;首都圈地区地壳密度具有明显的非均匀性.研究认为首都圈地区地震的发生与上地幔顶部及软流层物质的上涌有一定关系. 相似文献
12.
YongHong Duan FuYun Wang XianKang Zhang JiYan Lin Zhi Liu BaoFeng Liu ZhuoXin Yang WenBin Guo YunHao Wei 《中国科学:地球科学(英文版)》2016,59(7):1477-1488
Lithosphere thinning and destruction in the middle-eastern North China Craton (NCC), a region susceptible to strong earthquakes, is one of the research hotspots in solid earth science. All 42 seismic wide-angle reflection/refraction profiles have been completed in the middle-eastern NCC. We collect all the 2-D profiling results and perform gridding of the velocity and interface depth data, building a 3-D crustal velocity structure model for the middle-eastern NCC, named HBCrust1.0, by using the Kriging interpolation method. Our result shows that the first-arrival times calculated by HBCust1.0 fit well with the observations. The result demonstrates that the upper crust is the main seismogenic layer, and the brittle-ductile transition occurs at depths near interface C (the interface between upper and lower crust). The depth of interface Moho varies beneath the source area of the Tangshan earthquake, and a low-velocity structure is found to extend from the source area to the lower crust. Based on these observations, it can be inferred that stress accumulation responsible for the Tangshan earthquake may have been closely related to the migration and deformation of the mantle materials. Comparisons of the average velocities of the whole crust, the upper and the lower crust show that the average velocity of the lower crust under the central part of the North China Basin (NCB) in the east of the craton is obviously higher than the regional average. This high-velocity probably results from long-term underplating of the mantle magma. 相似文献
13.
中国大陆下扬子及邻区地壳结构基本特征:深地震测深研究综述 总被引:2,自引:2,他引:0
The Deep Seismic Sounding( DSS) projects carried out from the 1970 s in the lower Yangtze region and its neighboring area were reviewed in this paper,then the basic wave group features of those wide angle reflection / refraction record sections,and of the crustal structure are summarized. It shows that there were in total five clear wave groups on the record sections,which include the first arrival Pg,the reflection P1 from the bottom interface of the upper crust,the reflection P3 from the bottom interface of the middle crust,the strong reflection Pm from the Moho boundary,and the refraction Pn from uppermost mantle. In general,these phases are easily consistently traced and compared,despite some first arrivals being delayed or arriving earlier than normal due to the shallow sedimentary cover or bedrocks. In particular,in the Dabie Mountain region the seismic events of a few gathered shots always have weak reflection energy,are twisted,or exhibit disorganized waveforms, which could be attributed to the disruption variations of reflection depth,the broken Moho,and the discontinuity of the reflection boundary within crust. The regional crustal structures are composed of the upper,middle and lower crust,of which the middle and lower layers can be divided into two weak reflection ones. The crustal thickness of the North China and Yangtze platform are 30km- 36 km,and the Moho exhibits a flat geometry despite some local uplifts. The average pressure velocity in lower crust beneath this two tectonic area is 6. 7 ± 0. 3km / s. Nevertheless,beneath the Dabieshan area the crustal thickness is 32km- 41 km,the Moho bends down sharply andtakes an abrupt 4km- 7km dislocation in the vertical direction. The average pressure velocity in the lower crust beneath the Dabieshan area is 6. 8 ± 0. 2km / s. 相似文献
14.
本义利用1979-1981年中国科学院地球物理研究所在随县-马鞍山所做的人工源地震探测的资料,采用二维射线追踪来拟合地震波的走时和振幅,取得了该地带的地壳与上地慢速度结构.结果表明,该地带地壳厚度为32-37km,莫霍面起伏变化显著.地壳速度的横向变化甚为强烈,地壳中部存在低速层.在巢湖以西宽数10km的范围内,地壳结构与其它地方明显不同,上地壳速度明显偏高,莫霍面上隆并有间断;在其两侧,明显可见有两条深断裂.结合其它地球物理场特征及大地构造概况,对结果进行分析,认为郯庐构造带南段被两条深断裂所夹,构造带宽度可达数10km,并在地质历史时期曾有过地幔物质上涌. 相似文献
15.
JOINT INVERSION OF AMBIENT NOISE AND SURFACE WAVE FOR S-WAVE VELOCITY OF THE CRUST AND UPPERMOST MANTLE BENEATH WEIHE BASIN AND ITS ADJACENT AREA 
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下载免费PDF全文 The Weihe Basin is the main component of the extrusion and escape shear zone between the ancient North China craton block in Ordos and the ancient Yangtze platform in Sichuan Basin, and carries the dynamic transmission from the main power source of the Qinghai-Tibet Block in the west to the North China and South China regions in the east. The basin itself plays multi roles in the east-west and north-south tectonic movement, and is an excellent site for studying the structural interlacing, dynamic transformation and transmission. At the same time, Weihe Basin is also a famous strong earthquake zone in China. Historically, there was a strong earthquake of magnitude 8 1/4 occurring in Huaxian County in 1556, causing huge casualties and property losses. In view of the special geological structures and the characteristics of modern seismicity activities in the Weihe fault-depression zone, it is necessary to carry out fine three-dimensional velocity structure detection in the deep part of Weihe Basin and its adjacent areas, so as to study the relationship between velocity structure and geological structural units and their evolution process, as well as the deep medium environment where earth ̄quakes develop and occur.
We investigate the S-wave velocity structure beneath Weihe Basin and its adjacent regions based on continuous background noise data and teleseismic data recorded by 257 broadband stations in Shaanxi Province and its adjacent regions and China Seismological Science Array Exploration Project, and by adopting seismic surface wave inter-station method and background noise cross-correlation method, a total of 10 049 fundamental-mode Rayleigh surface wave phase velocity dispersion curves in the periods of 5~70s are obtained. Firstly, using the average dispersion curve in this study area, we obtain the one-dimensional average S-wave velocity structure model of the study area, and then we apply the ray-tracing surface-wave-dispersion direct inversion method to obtain the S-wave velocity structure of the crust and uppermost mantle (3~80km) beneath Weihe Basin and its adjacent regions. The test results of a 1°×1° grid checker board show that the recovery is good, except for the areas east of 111° and south of 32° of the study area, where there is almost no resolution. The imaging results show that the velocity structure beneath each tectonic unit in the study area has a certain distribution rule, and there is a good correlation between surface geological structure and deep velocity structure.
Based on the analysis of velocity slices at different depths and S-wave velocity structures of three profiles, and combined with existing geological structures, geophysics and other deep exploration research results, we obtain the following knowledge and conclusions:1)The thick sedimentary layer covering the top of Weihe Basin is the cause of low velocity anomaly in its shallow crust, the middle and upper crust of the basin are of low velocity structure, and the low-velocity zone extends about 25km, the Moho interface uplifts abruptly relative to both the Ordos Block and the Qinling orogenic belt on opposite sides, and high-speed materials from the upper mantle intrude into the lower crust, which may be related to the underplating of mafic-ultramafic materials from the upper mantle in Mesozoic-Cenozoic period; 2)The south Ordos Block is not a homogeneous whole, the low-velocity structure of the shallow crust in southern Ordos Block is thin in east and thick in west, which may be related to the overall tilting of the Ordos Basin since the Phanerozoic, as well as the differential uplift and strong and uneven denudation of the Ordos Block since the Late Cretaceous. The crustal structure of the south Ordos Block is relatively simple and homogeneous. There is no significant low-velocity structure in the curst of the block, which shows that the low-velocity structure in the crust does not penetrate the whole Ordos block. We speculate that the southern Ordos Block still maintains the stable craton property, and has not been reformed significantly so far; 3)The variation characteristics of deep structure of the Qinling orogenic belt reflect the deep crustal structure and tectonic deformation characteristics of the orogenic belt which are strongly reformed by land-land collision and suture between North China plate and Yangtze plate, intracontinental orogeny, uplift of Qinghai-Tibet Plateau and its northeastern expansion since the Late Hercynian-Indosinian period. The deep structure beneath the eastern and western Qinling orogenic belt is different and has the characteristics of segmentation. The low-velocity anomaly at the bottom of the lower crust of the orogenic belt may be affected by tectonic activities such as uplift and outward extension of the NE Tibetan plateau, and the analysis considers that there is little possibility of the existence of lower crustal circulation channel for the eastward flowing of Tibetan plateau materials in the Qinling orogenic belt. However, since the maximum depth from the inversion of this paper is 80km, which is located at the top of the upper mantle, our results cannot prove that there exists a mantle flow channel for the eastward flow of Tibetan plateau material beneath the Qinling orogenic belt. 相似文献
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随县—马鞍山地带地壳与上地幔结构及郯庐构造带南段的某些特征 总被引:14,自引:2,他引:14
本义利用1979—1981年中国科学院地球物理研究所在随县—马鞍山所做的人工源地震探测的资料,采用二维射线追踪来拟合地震波的走时和振幅,取得了该地带的地壳与上地慢速度结构.结果表明,该地带地壳厚度为32—37km,莫霍面起伏变化显著.地壳速度的横向变化甚为强烈,地壳中部存在低速层.在巢湖以西宽数10km的范围内,地壳结构与其它地方明显不同,上地壳速度明显偏高,莫霍面上隆并有间断;在其两侧,明显可见有两条深断裂.结合其它地球物理场特征及大地构造概况,对结果进行分析,认为郯庐构造带南段被两条深断裂所夹,构造带宽度可达数10km,并在地质历史时期曾有过地幔物质上涌. 相似文献
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本文是1986年古雷—石城剖面及嵩口—宜城剖面深地震测深资料的初步研究结果。 对古雷—石城的纵剖面资料,分析了震相特征,共识别出五个波组:P_2、P_3~0、P_4~0、P_5~0及P_n(P_n~0)。通过对波的走时反演,正演拟合和理论地震图方法等计算,得到了该区地壳与上地幔结构模型。 古雷—石城地区地壳具有多层结构,并可划分为上、中、下三层。古雷炮点给出的厚度分别为1.0km、15.7km、12.8km,地壳平均速度为6.29km/s,深度为29.5km,上地幔顶面P_n波速度为7.83km/s。石城炮点给出厚度分别为1.8km、18.3km、12.4km。地壳平均速度为6.29km/3,深度为32.4km,土地幔顶面P_n速度为8.00km/s。 在中地壳下部存在一低速层,其厚度为2.8km,速度为5.85km/s。根据其它研究结果,初步判断低速层介质是半熔融物质组成。 测区内横向变化比较强烈。从东向西有长乐—诏安、政和—海丰和邵武—河源三个大断裂穿过该区,并且都深切至莫霍面;在漳州盆地之下莫霍面隆起约3km,戴云山区下莫霍面凹陷近2km;永安—梅州莫霍面隆起接近3km。莫霍面分布显示出从东南向西北逐渐加深。 宜城—连城—嵩口非纵剖面显示了莫霍面在两处有明显断错,错距约2km邵。表明昭武—河源断裂是切割莫霍面的深大断裂。 相似文献
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Integrated Analysis on Gravity and Magnetic Fields of the Hailar Basin, NE China: Implications for Basement Structure and Deep Tectonics 总被引:2,自引:0,他引:2
Bin Sun Liangshu Wang Ping Dong YongJing Wu Changbo Li Bo Hu Chong Wang 《Pure and Applied Geophysics》2012,169(11):2011-2029
The Hailar Basin is one of the typical basins among the NE China Basin Groups, which is situated in the east of East Asia Orogene between the Siberia Plate and the North China Plate. Based on the detailed analysis of magnetic, gravity, petrophysical, geothermal and seismological data, we separate the Gravity and Magnetic Anomalies (GMA) into four orders using Wavelet Multi-scale Decomposition (WMD). The apparent depths of causative sources were then assessed by Power Spectrum Analysis (PSA) of each order. Low-order wavelet detail anomalies were used to study the basin’s basement structure such as major faults, the basement lithology, uplifts and depressions. High-order ones were used for the inversion of Moho and Curie discontinuities using the Parker method. The results show that the Moho uplifting area of the Hailar Basin is located at the NE part of the basin, the Curie uplifting area is at the NW part, and neither of them is consistent with the basin’s sedimentary center. This indicates that the Hailar Basin may differ in basin building pattern from other middle and eastern basins of the basin groups, and the Hailar Basin might be of a passive type. When the Pacific Plate was subducting to NE China, the frontier of the plate lying on the mantle transition zone didn’t pass through the Great Khingan Mountains region, so there is not an obvious magma upwelling or lithospheric extension in the Hailar Basin area. Finally, based on the seismological data and results of WMD, a probable 2D crust model is derived from an across-basin profile using the 2D forward modeling of the Bouguer gravity anomaly. The results agree with those from seismic inversion, suggesting WMD is suitable for identifying major crustal density interfaces. 相似文献
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Using records of continuous seismic waveforms from 609 broadband seismic stations in the South China Block and its adjacent areas in 2010–2012, empirical Green's functions of surface waves were obtained from cross-correlation functions of ambient noise data between these stations. High quality phase velocity dispersion curves of Rayleigh waves were obtained using time-frequency analysis. These interstation dispersion curves were then inverted to build Rayleigh wave phase velocity maps at periods of 6–50 s. The results of phase velocity maps indicate that phase velocities at 6–10 s periods are correlated with the geological features in the upper crust. Major basins and small-scale grabens and basins display slow velocity anomalies; while most of the orogenic belts and the fold belts display high velocity anomalies. With the gravity gradient zone along Taihang Mountain to Wuling Mountain as the boundary for the phase velocity maps at period of 20–30 s, the western area mainly displays low velocity anomalies, while the eastern side shows high velocity anomalies. Phase velocities in the eastern South China Block south to the Qinling-Dabie orogenic belt is higher than that in the eastern North China Block to the north, which is possibly due to the differences of tectonic mechanisms between the North China Craton and the South China Block. The phase velocities at periods of40–50 s are possibly related to the lateral variations of the velocity structure in the lower crust and upper mantle: The low-velocity anomalies in the eastern part of the Tibetan Plateau are caused by the thick crust; while the Sichuan Basin and the southern part of the Ordos Basin display distinct high-velocity anomalies, reflecting the stable features of the lithosphere in these blocks. The lateral variation pattern of phase velocities in the southern part of the South China Block is not consistent with the surface trace of the block boundary in the eastern Yunnan Province and its vicinities. The phase velocities in the Sichuan Basin are overall slow at short periods and gradually increase with period from the central part to the edge of the basin, indicating the features of shallower basement in the center and overall stable lithospheric mantle of the basin. The middle and upper crust of the southern Ordos Basin in the North China Block is heterogeneous, while in lower crust and the uppermost mantle the phase velocities mainly exhibit high anomalies. High-velocity anomalies are widespread at the middle of the Qinling-Dabie orogenic belt, as well as the areas in southeastern Guangxi with Caledonian granite explosion, but its detailed mechanism is still unclear. 相似文献