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1.
利用GIS方法研究南北地震带和中央造山带交汇区活动断裂与地震的关系 总被引:3,自引:1,他引:2
基于地理信息系统(GIS)技术研究南北地震带和中央造山带交汇区断裂带分布与地震活动的关系,对区内16条主要断裂带,以25km为缓冲区宽度,进行叠加,分析各断裂带的地震活动性及其特征.结果表明,主要的发震断裂有西秦岭北缘断裂的西段、礼县-罗家堡断裂西南段以及临潭-宕昌断裂的东南段、文县断裂西南段、虎牙断裂和雪山断裂;虎牙断裂和雪山断裂地震活动性最强,其次是塔藏断裂、礼县-罗家堡断裂以及光盖山-迭山北麓断裂;按震源深度可将研究区划分为4个区域,区内的震源深度由北向南逐渐加大,震源深度剖面图反映了断层的几何形态和力学性质,进一步揭示出了青藏高原向东挤压、物质向东向南逃逸的运动模式. 相似文献
2.
岷山隆起带与西秦岭构造带中段位于青藏高原物质东向流动的必经之处,又是南北地震带的组成部分和GPS速度场非连续性衰减和转换的关键部位,其地壳结构及地壳变形机制受到国内外地质地球物理学家的广泛关注,了解研究区深部细结构及主要边界断裂空间展布特征,对青藏高原隆升机制及中强地震孕震构造的研究有重要意义.本文依托分别横跨岷山隆起带及西秦岭构造带中段的两条大地电磁剖面(SG-WQL-L1与SG-WQL-L2)小点距观测数据,采用大地电磁相位张量分解技术对两条剖面上各个测点的电性走向、二维偏离度进行计算分析,根据分析结果对原始数据进行主轴方位角校正处理,进一步采用NLCG(非线性共轭梯度)二维反演方法开展TE与TM模式的相位和电阻率联合反演,获取沿剖面方向30 km以浅的电阻率结构模型,并完成了地质地球物理综合解释.两条大地电磁剖面勘探成果揭示出,马尔康地块中上地壳发育的壳内低阻层与峨山隆起上地壳低阻体在深部交汇,岷江断裂带与虎牙断裂带受控于马尔康地块与岷山隆起带上地壳底部的滑脱面,滑脱面呈现往东角度逐渐变陡峭的趋势且在岷江附近出现"断坡"构造,历史强震震源深度显示虎牙断裂为岷山隆起带新生代强震的发震断裂;西秦岭构造带中段中上地壳沿剖面方向表现为横向分块、纵向分层的电性结构特征,中地壳12~25 km左右发育厚度不等的壳内低阻层,壳内低阻层多与研究区次级地块的边界断裂在深部交汇,次级地块以及区分次级地块的活动断裂带可能是GPS速度场在研究区呈现非连续性的递减并伴随方向转换的构造成因;青藏高原内部的软流圈物质向NE和SSE流动,驱动巴颜喀拉地块东缘上地壳沿中上地壳低阻层东向运移,受到摩天岭高阻地块的阻挡作用,软弱的岷山隆起带发生地壳褶皱变形并向东逆冲推覆从而形成高耸的岷山山脉,岷江断裂与虎牙断裂的左旋运动加速了岷山的隆起. 相似文献
3.
Based on the seismic station data sets from Sichuan and Yunnan provinces, we employed a multi-step seismic location method (Hypo2000 + Velest + HypoDD) to precisely locate the 7,787 earthquakes that occurred during 2010-2015 along the eastern boundaries of the Sichuan-Yunnan rhombic block, namely from southern Dawu to the Qiaojia segment. The final results show that location precision is greatly advanced and epicenter distribution exhibits good consistency with the linear distribution of the seismic faults. Earthquake distribution is quite intensive at the intersection region in the southern segment of the Xianshuihe fault, the Anninghe fault zone, the Xiaojinhe fault zone and the Daliangshan fault zone to the east. The depth profile of seismicity shows a clear stepwise activity along the active seismic fault zones. The profile crossing the faults of the Xianshuihe, Anninghe, and Daliangshan presents a complex interaction among faults near the multiple faults intersection region, Shimian, where the earthquakes are obviously divided into two groups in depth. Earthquakes are very rare at the depth of 15km-20km, which is consistent with the region of the plastic rheology between 14km-19km calculated by Zhu Ailan et al.,(2005). 相似文献
4.
信浓川地震带位于日本大地沟北部,地壳运动十分强烈,区内地震主要沿信浓川流域发生,并密集成带,大地构造上处于日本海板块向本州板块俯冲的边界线上。该地震带大多数地震为中强震,且均为浅源地震,地震发生伴随着明显的地下水前兆异常,震中区有强烈的超压热水系的喷溢活动。震中区地下水的温度、电导率以及主要地球化学成分呈线性异常分布,并与地震强弱或地震断裂规模有关,地震断层的规模控制了超压热水系喷溢活动的强度和规模。地震发生与超压热水系喷溢活动有着密切的成生关系,超压热水系喷溢活动使断层发生活动所需应力条件降低,诱发地震发生,同时断层活动为超压热水系向上喷溢提供通道。 相似文献
5.
选用四川及云南地震台站资料,采用多阶段地震定位法(Hypo2000+Velest+HypoDD),对四川境内川滇菱形块体东边界的道孚南至巧家段2010年1月1日~2014年12月31日7787次地震进行了精定位。精定位后,震源位置精度明显提高,震中分布与地震断裂带线性展布较一致。定位结果显示,鲜水河断裂带东南段地震分布相对密集,鲜水河南段与安宁河断裂带、小金河断裂带及以东的大凉山断裂带交叉区域相对密集。深度剖面图沿活动断裂带地震活动分段活动特征明显,横跨鲜水河、安宁河和大凉山等断裂的剖面呈现出石棉附近多断裂交汇处的断层间复杂的相互作用,地震明显分为深、浅两丛。15~20km深度范围地震非常稀少,这与朱艾斓提出的14~19km塑性流变的层厚和位置较一致。 相似文献
6.
山西带形变监测场地情况调查 总被引:1,自引:0,他引:1
对山西带跨断层短水准流动测量场地、定点台站跨断层水准场地和区域流动GPS场地及分布情况进行了调查、汇总和分析。调查了10个流动水准测量场地和4个定点台站水准测量场地,所跨断层绝大多数走向为北北东至北东向,多具有右旋正走滑活动性质,反映了山西带总体构造特征。同时发现,偶有近东西向断裂或北西向断裂与其互相切割,应该是容易造成应力集中的地方。整个山西带布有区域GPS观测点40个,每年正常观测1次的有39个,点距多为几公里到几十公里不等,在整个断层带上的分布比较均匀,并已积累了十几年的流动观测资料。结合地质资料和历史地震的活动特点,认为山西带再次孕育强震的可能性较大,这些多手段形变测量场地的布设情况、时间和空间上的相互联系及多年复测资料的积累对强震预测研究有重要价值。 相似文献
7.
新疆天山主要活断层的分段及其在地震区划中的运用 总被引:1,自引:0,他引:1
对天山地区活动断裂不同地段的几何形态、运动方式、地震活动特征存在的差异进行了分析研究。提出了活断层分段的标准和几种用于活断层分段的地震活动性指标:给出了活断层分段的标志点特征,并对新疆天山地区13条活断层进行了分段,讨论了分段结果在地震区划潜在震源区划分及其地震活动性参数确定中的应用。结果表明:通过活断层分段使潜在震源区的划分更准确、恰当,使地震活动性参数的确定更能反映出地震活动的时空不均匀性。 相似文献
8.
综合利用区域台站和流动台站(近台)的记录,基于初至P震相重新测定了2017年九寨沟序列M_S7.0主震和M_L≥3.0余震的震源位置,并利用较高精度的定位结果分析余震分布与地震构造的关系,解释发震断裂带的结构.获得的新认识有:(1)九寨沟主震震源深度为16km,位于余震带中段的南缘;余震主要分布深度为4~17km.(2)沿余震带的走向,余震分布与主震同震位错大小的分布明显相关.余震带中段8~16km深度存在的余震稀疏区与同震位错的高值区相吻合,应是发震断裂带主凹凸体的部位,也是主震时应变释放较充分的部位;余震带南东段10~18km深度的余震密集区对应了同震位错的亏损区之一,三次M_L≥5.0余震都发生于此;余震带西北段在5~10km之下既缺少余震,又属同震位错的亏损区,可能与那里多条断裂的交汇或合并造成的构造复杂性有关;余震带中-北西段3~5km深度的也缺少余震,也对应了浅部的同震位错亏损区.(3)证实了九寨沟地震的发震构造为虎牙断裂带北段,同时新揭示出发震断裂带表现为由主断裂和分支断裂构成的、向上分叉的花状结构,尺度约为4.5km宽(最大)、35km长,主断裂朝SW陡倾.这些反映主震破裂可能不只受控于单一的断裂,而有可能是沿主断裂发生主破裂,而沿分支断裂发生次要破裂.另外,本文对发震断裂带结构的分段解释,是遵循构造地质学原理去综合震源排列、震源机制解、地表断层已知位置、相邻剖面断层解释结果等信息的分析结果,而不仅仅依据余震的密集分布进行推断. 相似文献
9.
Exploration and Study of Deep Crustal Structure in the Quanzhou Basin and Its Adjacent Area 总被引:1,自引:0,他引:1
Zhu Jinfang 《中国地震研究》2006,20(3):305-315
INTRODUCTIONQuanzhou Citylocates on the southeast coast of Fujian Province .Tectonically,it locates in thevolcanic fault depression zone in East Fujian betweenthe Wuyi-Daiyunfolded doming-upregion of theSouth China block and the depression zone of the Taiwan Straits . Being on the north segment of thesoutheast seismic belt of China , many destructive earthquakes inthe history affected the area and theregional seismicityis closelyrelated withfaulting.Inthe Quanzhou basin,large-scalelo… 相似文献
10.
采用数理统计方法探讨了780 BC至今、100°—110°E、22°—35°N(中国南北地震带)区域的中国大陆5.0级及以上天然地震的分布规律。通过GMT软件绘制了南北地震带上地震震中和断裂分布图像,分析了南北地震带地震时空分布与地震活动性的规律。研究表明,该地区的大震与强震几乎全部发生在断裂带上,地震频次高、震中密集,呈现集群性等特征,地震活动性较高。该地震带中、南段相似,与北段存在显著差异。在南北地震带上,地震的活跃幕与平静幕持续时间,与活跃幕强度有关。研究结果对于了解地震的时空分布特征,认识中国南北地震带的发震规律,地震的孕震发震和地震活动周期有参考意义。 相似文献
11.
2008年5月12日四川龙门山断裂带发生了汶川8.0级地震,之后四川境内发生了两次7.0级地震(其中一个是芦山地震),为了研究汶川地震之后龙门山断裂带及周边区域的地震活动性,本研究收集了国家地震台网和四川区域地震台网2010年1月1日—2017年12月31日四川地区发生的17次M≥5.0地震以及120多次5.0>M≥4.0地震的波形资料,利用波形拟合法反演了震源机制解及区域应力场.反演结果显示,位于龙门山断裂带上的地震,震源机制以逆冲型为主,鲜水河断裂带地震震源机制以走滑型为主,而川滇块体西南部的理塘断裂、金沙江断裂附近,震源机制解以正断层为主.根据震源机制解反演得到的龙门山地区、鲜水河地区的主压应力场方向为WNW、近EW向.川滇块体的巴塘、理塘等地区,其主压应力轴方向为12°左右,接近SN向,且仰角接近40°左右.本研究利用面波振幅谱特征对震源深度进行了精确定位,定位结果与中国地震台网中心(CENC),美国地震调查局(USGS),国际地震中心(ISC)等机构地震目录进行了对比.结果显示,四川地区强震震源深度主要分布在20km以上的中上地壳.龙门山地区震源优势分布在10~20km,鲜水河断裂地震震源深度在10km左右,川滇块体西南部的理塘断裂,巴塘断裂,金沙江断裂等地区,震源深度一般在5~10km范围. 相似文献
12.
川滇地区是我国地震危险性较高的地区之一.本文基于对特大强震的风险性考虑,使用全球地震模型OpenQuake软件,建立了川滇地区地震危险性预测新模型.首先根据构造特征划分多个震源分区,并整理出这些震源分区内断层活动特征与滑动速率;基于震源分区和断层模型,使用GPS应变率转换成的锥形古登堡-里克特关系作为整个区域的地震积累率,并允许超过历史最大震级的特大地震的出现,结合活动断层滑动速率所积累的地震发生率,给出震源分区内断层地震源和背景地震源的地震发生率的比率分配关系;在活动断层分段上,保留了大型断裂或其主要部分,没有根据小的阶区来对断层进行详细分段,以便分配特大地震发生率;并使用地震率平滑方法分配背景地震发生率.最后在OpenQuake中加入地震动预测方程,计算出了川滇地区的PGA分布图,为区域地震危险性提供科学依据. 相似文献
13.
Tada-nori Goto 《Physics of the Earth and Planetary Interiors》2005,148(1):55-72
Seismicity along the Atotsugawa Fault, located in central Japan, shows a clear heterogeneity. The central segment of the fault with low-seismicity is recognized as a seismic gap, although a lot of micro-earthquakes occur along this fault. In order to elucidate the cause of the heterogeneity in seismicity, the electrical resistivity structure was investigated around the Atotsugawa Fault by using the magnetotelluric (MT) method. The regional geoelectrical strikes are approximately parallel to the fault in a low-frequency range. We constructed two-dimensional resistivity models across the fault using TM-mode MT responses to minimize three-dimensional effects on the modeling process. A smooth inversion algorithm was used, and the static-shifts on the apparent resistivity were corrected in the inversion process.A shallow, low resistivity zone along the fault is found from the surface to a depth of 1-2 km in the best-fit model across the high-seismicity segment of the fault. On the other hand, the corresponding low resistivity zone along the low-seismicity segment is limited to a shallower depth less than 1 km. The low resistivity zone along the Atotsugawa Fault is possibly due to fluid in the fracture zone; the segment with higher levels of seismicity may have higher fluid content in the fault zone compared with the lower seismicity segment. On a view of the crustal structure, a lateral resistivity variation in a depth range of 3-12 km is found below the fault trace in the high-seismicity segment, while a resistive layer of wide extent is found at a depth of about 5 km below the fault trace in the low-seismicity segment. The resistive layer is explained by less fluid condition and possibly characterized as high rigidity. Differences in the resistivity structures between low and high-seismicity segments of the fault suggest that the seismic gap in the central part of the Atotsugawa Fault may be interpreted as a locked segment. Thus, MT is an effective method in evaluating a cause and future activity of seismic gaps along active faults.The lower crust appears as a conductive zone beneath the low-seismicity segment, less conductive beneath the high-seismicity segment. Fluid is inferred as a preferable cause of the conductive zone in this study. It is suggested that the conductive lower crust beneath the low-seismicity segment is recognized where fluid is trapped by an impermeable layer in the upper crust. On the other hand, fluid in the lower crust may upwell to the surface along the high-seismicity segment of the fault. 相似文献
14.
Tian Qinjian 《中国地震研究》2007,21(1):74-84
The interaction zone between southern Tianshan and northern Tarim is located at the northeast side of Pamir. It is a region with high seismicity. We constructed a seismotectonic model for the west part of this zone from geological profiles, deep crust seismic detection and earthquake focal mechanisms data. Based on the synthesized geological features, deep crust structure, and earthquake focal mechanisms, we think that the main regional tectonic feature is that the Tianshan tecto-lithostratigraphic unit overthrusts on the Tarim block. The Tianshan tectonic system includes the Maidan fault and thrust sheets in front of the fault; The Tarim tectonic system includes the underground northern Tarim margin fault, conjugate faults in basement and overthrust fault in shallow. The northern Tarim margin fault is a high angle fault deep in the Tarim crust, adjusting different trending deformation between Tianshan and Tarim. It is a major active fault that can generate large earthquakes. The other faults, such as the Tianshan overthrust system and the Tarim basement faults in this area may generate moderately strong earthquakes with different styles. 相似文献
15.
On August 8, 2017, Beijing time, an earthquake of M7.0 occurred in Jiuzhaigou County, Aba Prefecture, Sichuan Province, with the epicenter located at 33.20°N 103.82°E. The earthquake caused 25 people dead, 525 people injured, 6 people missing and 170000 people affected. Many houses were damaged to various degrees. Up to October 15, 2017, a total of 7679 aftershocks were recorded, including 2099 earthquakes of M ≥ 1.0.
The M7.0 Jiuzhaigou earthquake occurred in the northeastern boundary belt of the Bayan Har block on the Qinghai-Tibet Plateau, where many active faults are developed, including the Tazhong Fault(the eastern segment of the East Kunlun Fault), the Minjiang fault zone, the Xueshan fault zone, the Huya fault zone, the Wenxian fault zone, the Guanggaishan-Daishan Fault, the Bailongjiang Fault, the Longriuba Fault and the Longmenshan Fault. As one of the important passages for the eastward extrusion movement of the Qinghai-Tibet Plateau(Tapponnier et al., 2001), the East Kunlun fault zone has a crucial influence on the tectonic activities of the northeastern boundary belt of Bayan Kala. Meanwhile, the Coulomb stress, fault strain and other research results show that the eastern boundary of the Bayan Har block still has a high risk of strong earthquakes in the future. So the study of the M7.0 Jiuzhaigou earthquake' seismogenic faults and stress fields is of great significance for scientific understanding of the seismogenic environment and geodynamics of the eastern boundary of Bayan Har block.
In this paper, the epicenter of the main shock and its aftershocks were relocated by the double-difference relocation method and the spatial distribution of the aftershock sequence was obtained. Then we determined the focal mechanism solutions of 24 aftershocks(M ≥ 3.0)by using the CAP algorithm with the waveform records of China Digital Seismic Network. After that, we applied the sliding fitting algorithm to invert the stress field of the earthquake area based on the previous results of the mechanism solutions. Combining with the previous research results of seismogeology in this area, we discussed the seismogenic fault structure and dynamic characteristics of the M7.0 Jiuzhaigou earthquake. Our research results indicated that:1)The epicenters of the M7.0 Jiuzhaigou earthquake sequence distribute along NW-SE in a stripe pattern with a long axis of about 35km and a short axis of about 8km, and with high inclination and dipping to the southwest, the focal depths are mainly concentrated in the range of 2~25km, gradually deepening from northwest to southeast along the fault, but the dip angle does not change remarkably on the whole fault. 2)The focal mechanism solution of the M7.0 Jiuzhaigou earthquake is:strike 151°, dip 69° and rake 12° for nodal plane Ⅰ, and 245°, 78° and -158° for nodal plane Ⅱ, the main shock type is pure strike-slip and the centroid depth of the earthquake is about 5km. Most of the focal mechanism of the aftershock sequence is strike-slip type, which is consistent with the main shock's focal mechanism solution; 3)In the earthquake source area, the principal compressive stress and the principal tensile stress are both near horizontal, and the principal compressive stress is near east-west direction, while the principal tensile stress is near north-south direction. The Jiuzhaigou earthquake is a strike-slip event that occurs under the horizontal compressive stress. 相似文献
16.
《中国地震研究》2016,(1)
In order to obtain deformation parameters in the south segment of Longmenshan fault zone,Euler datum transformation and the least square collocation for data interpolation and smoothing are used to process GPS displacement time series data in the south segment of Longmenshan fault zone,and the rigid and elastic-plastic block motion model is used to calculate the strain parameters in each subarea. Conjoint analysis of displacement,velocity of each station and strain parameters of each subarea reveals that the influence of the Wenchuan earthquake on the south segment of Longmenshan fault zone increases from southeast to northwest,causing a highest deformation rate 6 times the background value and heightening the influence of the hidden faults on the difference of the earth surface along its two sides,which leads to the seismic risk of the southern segment increasing from north to south. The comparison of seismic risk among subareas based on the tectonic and seismicity background indicates that the most dangerous area is on the southeast of Longmenshan faults,and the background strain accumulation and the promoting effect of the Wenchuan earthquake advanced the occurrence of Lushan earthquake and the sinistral strike-slip on the rupture plane. The Wenchuan earthquake also caused a slight two-year long continuous strain release in the south segment of Xianshuihe fault,but the influence is far less than the effect of the compressive strain caused by the Sichuan-Yunnan block. 相似文献
17.
2017年8月8日在青藏高原东缘四川省九寨沟县发生M7.0级强烈地震,极震区烈度达Ⅸ度,但无明显地表破裂,一定程度上限制了发震构造的确定和后续地震危险性判定.本文基于截止至2017年8月14日的地震资料,采用多阶段定位方法,对主震及余震进行了重新定位,同时,利用CAP波形反演方法,获得了M7.0主震与13次ML ≥ 4.0级余震的震源机制解和震源矩心深度,进而初步分析了本次地震的发震构造.结果显示,九寨沟M7.0地震的矩震级MW6.4,震源矩心深度5 km,表明主震发生在上地壳浅部,与2003年伊朗巴姆(Bam)MW6.5地震特征极为相似;12次ML ≥ 4.0级余震的震源矩心深度6~12 km,显示这些余震发生在主震下部,仅1次例外.重新定位后的余震震中呈NW-SE向窄带展布,位于近NS向的岷江断裂与近EW向的东昆仑断裂带东端分支塔藏断裂所夹持的区域,余震带长轴长约38 km,主震位于余震带中部.根据余震震中分布、主震及余震震源机制解等,推测本次九寨沟M7.0地震及其余震的主发震构造为位于岷江断裂与塔藏断裂之间的树正断裂.震源机制解揭示,树正断裂呈左旋走滑,走向约152°,近SE,倾向SW,倾角约70°,该断裂应属于东昆仑断裂东端的分支断裂之一,或与东南侧的虎牙断裂构成统一断裂系. 相似文献
18.
利用基于GPU加速的匹配定位法和双差定位法,对江苏盐城及邻区18个台站记录的2009~2018年共10年的连续地震资料进行分析。首先从台网目录中挑选211个地震事件作为模板事件,使用匹配定位技术对江苏盐城附近连续10年的地震进行检测和识别,共识别出1349个地震事件,约为台网目录地震事件的3倍,最小完备震级由台网目录的ML1.9降为ML1.2。然后利用双差定位法对检测到的地震事件进行精定位,精定位的结果揭示:建湖地区的地震密集带与洪泽-沟墩断裂有关,震源深度优势分布为5~20km,断裂两侧震源深度有显著差异,断裂带倾向NW;射阳震群震源深度比建湖震群有所加深,优势分布为10~25km,震源深度由南东向西北逐渐变浅;宝应地区地震丛集分布;东台地区由于模板事件相对较少,扫描定位后,地震事件在陈家堡-小海断裂带附近零星分布。研究结果为研究盐城地区的地震活动性、发震断层的深部构造提供了基础数据支撑。 相似文献
19.
以中国地震台网中心地震目录中的事件为模板地震,通过滑动窗口的波形互相关方法对布设在灌县—安县断裂周边17个流动地震台的连续地震记录进行处理,识别ML0.0以上的重复地震. 然后使用结合波形互相关技术的双差算法对这些地震进行重定位,获得了243次地震的重定位结果. 结果表明: 在研究时段内,灌县—安县断裂的地震活动性呈减弱趋势; 地震震源的优势分布深度为5—15 km,震源深度剖面显示地震呈高角度向西倾斜分布; 地震震中沿NE向分布,与龙门山前山断裂的走向基本一致; 研究区内南、 北两段的地震活动性及b值存在差异,这可能与龙门山断裂带中段区域应力方向由南到北发生的WNW向到ENE向转换的构造作用密切相关. 相似文献
20.
龙陵—澜沧新生地震断裂带位于地震活动强烈的滇西南地区, 该地区历史上曾发生多次MS≥7.0大地震, 已知的历史地震破裂几乎覆盖了整条断裂带. 本文首先对滇西南地区主要断裂的最新构造活动特征进行分析; 然后通过该区域地震活动b值图像的空间扫描计算, 圈定出高应力集中区, 并结合历史地震和现今小震的分布情况以及晚第四纪以来断裂的活动强度、 古地震最晚离逝时间等定量参数, 综合分析龙陵—澜沧断裂带的未来大震危险性; 最后基于地震空区理论, 识别该断裂带存在的地震空区. 研究结果表明, 龙陵—澜沧断裂带内的龙陵、 永德、 沧源、 澜沧及孟连断裂中东段在未来10年内均存在发生中强以上地震的危险性, 应引起关注. 相似文献