2002 年甘肃玉门 5.9 级地震的地质背景研究

野外调查结果表明 ,2 0 0 2年 1 2月 1 4日发生在甘肃省玉门地区的 5 9级地震 ,其宏观震中和仪器震中都位于祁连山北缘断裂上。震中区烈度为Ⅶ度 ,Ⅶ度区呈长椭圆形 ,长轴走向N6 5°W ,长度为 1 5km ,短轴走向N2 5°E ,长度为 9km。发震断层应为祁连山北缘断裂的次级断裂旱峡—大黄沟断裂 ,本次地震的余震都分布于该断裂附近。     

2003年新疆石河子5.4级地震序列重新定位及发震断层与机制分析

利用双差地震定位法对2003年2月14日石河子5.4级地震及其余震进行重新定位。定位结果显示,石河子地震及其余震呈N40°E方向线性展布,与准噶尔南缘断裂近乎垂直;震源深度全部分布在15~30 km范围内,优势分布为15~25 km。石河子5.4级地震震中位置为44.001395°N,85.872175°E,距离新疆地震局测得的震中位置仅1.2 km,而距离宏观考察的震中位置约49 km。分析重定位结果其震源机制解得出,这次地震的发震构造是准噶尔南缘断裂,而不是宏观考察的以连哈比尔尕山断裂;节面Ⅰ是主破裂面,而且其走向与重定位地震序列的展布方向基本一致。     

2004年西藏懂错M_S 5.6地震的宏观烈度调查与控震构造分析

地表调查结果表明,发生在西藏中部的2004年懂错MS5.6地震的极震区位于懂错东侧的贡巴淌—怕尔淌之间,最大烈度为Ⅶ度,宏观震中的地理坐标:31.70°N,91.26°E。此次地震是懂错盆地东缘边界断裂活动的结果。该断裂带是一条长40km左右、NNE走向的全新世活动正断层,在断裂带的北段发育可能形成于全新世晚期的古地震地表破裂带。地表的晚第四纪断裂活动和近期的地震活动特征显示,蓬错-懂错-错那-安多地堑系构成了西藏中部一个重要的长约120km的NE向地震活动带,其北段和中南段是其中应变积累时间更长的地段     

2001年11月14日昆仑山库赛湖地震(M_S8.1)地表破裂带的基本特征

震后野外考察表明 ,2 0 0 1年 11月 14日昆仑山库赛湖地震 (MS8 1)发生在青藏高原北部东昆仑断裂带库赛湖段上 ,发震断层具有高速率左旋滑动的基本特征 ,晚更新世晚期以来的平均滑动速率达 (14 8± 2 4 )mm/a ;地震地表破裂带沿库赛湖段西起布喀达板峰东缘 (91°0 8′E) ,向东经库赛湖北缘、青藏公路 2 894里程碑、玉珠峰南麓 ,东止于青藏公路东 70km附近 (94°4 8′E) ,地震地表破裂带沿N70°～ 90°W走向线状展布 ,全长约 35 0km ,由一系列走向N4 5°～ 5 0°E拉开状张裂缝、走向N6 0°～ 75°E张剪切裂缝、走向N80°W剪切裂缝以及隆起鼓包或开裂陷坑等斜列状组合而成 ,显示出纯剪切走滑的破裂特征 ,最大左旋水平位移 6m ;宏观震中位于昆仑山口西 80～ 90km附近的库赛湖东北角山麓地带 ,地震地表破裂带宽度 30 0m ,在库赛湖北岸至山麓地带的地震地表破裂带和由地震动或重力效应引起的次生破裂带总宽度可达 2km。库赛湖地震地表破裂的左旋走滑特征表明 ,青藏高原物质确实存在着向东的滑移或流动 ,东昆仑断裂带东部与库赛湖段斜列的东大     

2013年4月20日四川芦山M7.0级地震与余震精确定位及发震构造初探

使用汇集在四川台网中心的固定台站、震后架设的流动台站、周边水库台站等震中距150 km以内的震相数据,选用分层速度模型,对芦山7.0级地震及震后9天内的余震利用双差定位法进行了重新定位.给出了芦山7.0级地震的发震时刻为2013-04-20 08:02:46.8,震中位置30.278°N,102.989°E,震源深度16.67 km,给出了3324次余震的双差定位结果,并对发震构造进行了分析.结果表明:芦山地震主破裂长度约40 km,下倾宽度约20 km,破裂视面积约800 km²,主破裂沿南西走向,倾角约40°.余震震源优势深度为10~22 km.余震沿南西走向,主要集中于大邑-名山断裂上盘.     

SPOT和IKONOS影像在昆仑山口西8.1级地震中的应用研究

昆仑山口西 8. 1级地震发生在青藏高原北部可可西里无人区,这里气候寒冷、空气稀薄,野外考察极其艰难。利用高分辨率卫星影像进行地震地表破裂带解译, 10m分辨率SPOT卫星影像能够清楚地反映出地震地表破裂主破裂带的形迹; 1m分辨率IKONOS影像,是一幅真实的地表微缩景观,形象、直观地反映出地震地表破裂的精细结构及运动特征。研究表明:昆仑山口西 8 .1级地震地表破裂带位于东昆仑断裂南麓冲洪积台地或冲洪积台地后缘的地貌陡变带,在布喀达坂峰以东的地表破裂带长近 350km,由 3条次级破裂组成,走向 100°,是一条叠置在先存地震破裂带上的地震地表破裂带。流经破裂带的一系列沟谷发生左旋同步扭曲,平均滑动速率为 13. 4~16. 8mm/a。宏观震中位于 93°17′E, 35°47′N玉西峰附近的地震破裂带上,这里最大地震位错为 7 8m,地震破裂带最宽达1 250m,这与中国地震局推测的宏观震中 93. 3°E, 35. 8°N非常接近     

关于通海地震发震地点的商榷

笔者参加了云南省地震局年初召开的通海1970年7.7级地震学术讨论会后,感到关于该地震发震地点的确定值得商榷。《中国地震简目》(地震出版社,1977年出版)根据当年宏观调查确定的震中位置是北纬24°、东经102.7°,地点在北西向曲江断裂的东南段、通海县高大公社西北的五街附近,该处原先在构造上被解释为通海山字型前弧西翼与曲江断裂斜接之处。但是阚荣举在1977年(《地球物理学报》20卷2期96—109页)和刘祖荫在1979年(《地震研究》2卷3期39—49页)根据国际地震中心和《中国地震目录》确定的新震中位置是北 更多还原     

2018年5月松原MS5.7地震序列发震断层及应力场特征

利用双差定位方法对2018年松原M_S5.7地震序列中M_L≥1.0地震重新定位,之后使用CAP方法求解松原M_S5.7地震序列中强地震的震源机制解,再借助MSATSI软件包反演得到松原地区的区域应力场。综合分析以上研究结果得到如下结论:① 松原M_S5.7地震序列发生在NW走向的第二松花江断裂与NE走向的扶余—肇东断裂交会处,将地震精定位结果沿两条断层走向作剖面分析,NW向剖面主轴长度约为5 km,震中分布均匀,NE向剖面主轴长度亦约为5 km,震中呈倾向NE的高倾角分布;② 该序列中的4次M_L≥3.7地震的震源机制解具有良好的一致性:节面Ⅰ走向为NE向,节面Ⅱ走向为NW向,均为高倾角走滑断层。中强地震的震源机制节面解与第二松花江断裂性质基本一致,由此推断第二松花江断裂是本次松原地震的发震断层;③ 松原地区的主压应力方位角为N86°E,倾角为7°,主张应力方位角为N24°E,倾角为71°。松原地区的区域应力场既受到大尺度的板块构造运动的控制,又受到区域构造运动的影响。在太平洋板块对北东亚板块向西俯冲作用下,东北地区产生了近EW向的主压应力,受周边地质构造控制,松辽盆地内NE向断裂与NW向断裂交会处易发生走滑型地震,2018年松原M_S5.7地震正是在这种构造作用控制下发生的中强地震。      

昆仑山口西8.1级地震西破裂带尾端破裂特征

20 0 1年 11月 14日昆仑山口西 8.1级地震的地表破裂带 ,宏观上可明显分为东、西两段。野外考察表明 ,8.1级地震地表西破裂带分布于库水浣湖—太阳湖之间 ,总体走向为 2 85°～ 2 90° ,全长约 2 5km ,以左旋走滑为主。西破裂带具有典型的左旋走滑末端效应 ,该段西端位于库水浣湖以西的冲沟沟床中 ,破裂带总体走向由NWW向转为 2 4 0°方向 ,表现为一系列走向 30°～ 4 0°、长 5～ 15m不等的斜列张裂缝及走向NW -SE的挤压脊组合 ;东端位于太阳湖西岸阶地上 ,破裂带总体走向由 10 5°～110°转为N5 0°E左右 ,NE向构造张裂缝与NW向挤压脊交错排列 ,总体表现为棋盘格状 ,并在太阳湖边消失。分析认为 ,昆仑山口西 8.1级地震地表西破裂带为一独立的地震事件所形成的形变带 ,昆仑山口西 8.1级地震具有多点破裂的特征     

汶川M_S8.0地震地表破裂带

2008年5月12日14时28分4秒,四川省汶川县发生MS8.0大地震。发震断裂为龙门山断裂带中的映秀-北川断裂。该次地震的地表破裂可分成2条,分别出现在龙门山断裂带中的映秀-北川断裂、彭县-灌县断裂上,前者破裂长度约200km,后者破裂长度约80km。本次地震的最大垂直和右旋水平同震位移出现在都江堰市虹口乡附近的映秀-北川断裂上,分别为(5±0.2)m和(4.8±0.2)m。破裂带南段出露的地表断层产状为N32°E/NW∠76°,其上的侧伏角为S75°～80°W,反映了该次地震在南段以逆冲运动为主,兼有少量的右旋走滑分量     

藏南错那-沃卡裂谷的第四纪正断层作用及其特征

地表调查发现,位于西藏南部的错那-沃卡裂谷带包含了3个相对独立的地堑-半地堑——沃卡、邛多江和错那-拿日雍错地堑(从北到南),并构成了该区重要的近SN向控震构造带。该裂谷带整体的展布方式及其中各地堑主边界断裂带的正断层活动指示了100°±2°的区域伸展方向。各边界断裂带的活动强度分析表明,断裂的平均垂直活动速率介于0·3~1·9mm/a。其中,末次盛冰以来合理的活动速率估算值为1·2~1·5mm/a,而末次间冰期以来的活动速率只有(0·6±0·3)mm/a,暗示该裂谷带的断裂活动行为可能类似于地震的丛集活动,存在间歇期与活跃期交替出现的特点。综合分析认为,中-下地壳物质的近EW向伸展或流动所导致的上地壳均匀拉张模式可能是该裂谷带的主要成因     

DISCUSSION ON RUPTURE CHARACTERISTICS OF THE 2013 TONGLIAO M5.3 EARTHQUAKE AND ITS AFTERSHOCKS

On two velocity models, the HypoDD method is used to accurately locate the Tongliao M5.3 earthquake sequence, then the CAP method is used to invert the focal mechanism solutions. The parameters of the seismogenic fault plane are fitted quantitatively by the small earthquake distribution and the regional stress field. The geometry, rupture features and possible seismogenic structure of the Tongliao M5.3 earthquake are comprehensively determined. The HypoDD relocation results show that this earthquake is located at 42.95°N, 122.37°E, the whole sequence trends in NW and major aftershocks (M_L ≥ 3.0) strike in NEE direction. With the time elapsed, the aftershocks extended to the shallow crust gradually. Comparing the focal mechanism solutions and relocation results, we determine that the fitted causative fault based on NNW-trending aftershock distribution is reliable, which has the top left corner (43.00°N, 122.35°E, depth 3.3km), lower left corner (43.00°N, 122.35°E, depth 8.9km), upper right corner (42.92°N, 122.37°E, depth 3.3km), lower right corner (42.92°N, 122.37°E, depth 8.9km), extending range 3km×7km, trending in 349° (NNW), dip angle 86° (nearly vertical), and slip angle 15°. It is inferred that whole process of main shock rupture is from the source to the NW and SE sides as a shear. The rupture degree is larger in southeast where the late rupture concentrated, and did not reach the surface.     

祁连山东段天桥沟-黄羊川断裂古地震活动习性研究

天桥沟-黄羊川断裂位于祁连山东段主峰冷龙岭以东,是祁连山东段的重要活动断裂之一。该断裂以关家台为界分为东西2段,全新世以来均有过明显的活动。沿断裂开挖了6个古地震探槽,通过综合对比得到了该断裂全新世以来的7次古地震事件和1次历史地震事件,其年代分别为事件Ⅰ(10743±343)aBP,事件Ⅱ(9038±39)aBP,事件Ⅲ(7050±577)aBP,事件Ⅳ(4847±185)aBP,事件Ⅴ(3562±190)aBP,事件Ⅵ(2476±194)aBP,事件Ⅶ(1505±253)aBP,事件Ⅷ为1927年古浪8级大地震。这表明该断裂可能也参与了1927年古浪8级地震的活动。各次古地震事件在时空分布上相对较均匀,大致具有准周期复发的特征     

一九八○年二月十六日云南地区日全食的电离层效应

本文借助于Budden的频高图分析方法,分析了云南省瑞丽县弄岛街1980年2月16日日全食期间的电离层资料,计算了日食日及控制目的剖面,给出了剖面参数,得到了E层临频及最大电子浓度所在高度在日食过程中的变化,也研究了F层的日食效应,指出了在各选定频率上的反射虚高和真高在日食过程中的变化,发现在300公里以下的各给定高度上,尤其是在270公里附近的高度上,其电子浓度明显地下降。     

1988年云南澜沧-耿马地震的烈度分布及地表破裂

1988年11月6日,在云南省西南部的澜沧-耿马断裂带上发生了两次大于7级的地震.地震造成的严重破坏和人员伤亡主要是由于极震区内抗震性能极差的毛石房、砖柱土坯房的大量倒塌所致.澜沧地震的震中基本烈度可达Ⅸ度,耿马地震极震区烈度达Ⅹ度.澜沧地震构造活动的地表证据主要是出现在极震区内的张性地裂缝带和小断层陡坎.地裂缝带和小断坎主要出现在四条相对连续的北北西走向的狭窄地带内,其长度从几百 m 到6km 不等.澜沧地震地表破裂带长约35km,宽约3km,最大垂直位移量和最大右旋水平位移量分别为1.5m 和1.4m.耿马地震地表断裂活动的明显证据包括一系列北北西走向的地裂缝带和一段长约5km的地震断层陡坎.耿马地震地表破裂带长约24km,其最大垂直位移3.5m,最大右旋水平位移为3m.两次地震形成的地表破裂带均具有右旋-正断层性质.本文讨论了这两次地震的 度分布及地表破裂特征.      

台湾9.21集集地震考察兼论强震发震断层

1999年9月21日,台湾中部山麓带发生了M7.3的大地震,震源深度为8km,财产损失及人员伤亡是百年来台湾许多地震中损失及伤亡最大的1次,其震级也是台湾本岛陆上所发生的地震级别最大的。震源机制属低角度逆冲断层成因,余震在平面上围绕着北港高基底作半圆状分布,在垂向上,则分布在逆冲断层的上盘。与此相应,地面变形及上部结构物的破坏,以车笼埔发震断层上盘最为激烈,下盘几乎不受影响。此外,地震断裂的北端,水平位移量高达9.8m,垂直抬升达10m,比主震区要大;其地面加速度峰值,亦高达水平为502gal,垂直为519gal。这些特点表明,地震是受到地下深处侏罗型叠瓦状构造的控制。此外,3个诱发地震中心均受当地的地质构造与地貌条件的控制。文中还叙述了震害及工程结构物破坏的特点,尤其是水工结构物的震害     

MECHANISM OF THE 2015 PISHAN,XINJIANG, MS6.5 MAINSHOCK AND RELOCATION OF ITS AFTERSHOCK SEQUENCES

Using the digital broadband seismic data recorded by Xinjiang network stations, we obtained focal mechanism of the July 3 Pishan, Xinjiang, M_S6.5 earthquake with generalized Cut and Paste(gCAP)inversion method. The strike, dip and rake of first nodal plane are 97°, 27°, 51°, and the second nodal plane are 318°, 70°, 107°. The centroid depth and moment magnitude are calculated to be 12km and 6.4. Combining with the distribution of aftershocks, we conclude that the first nodal plane is the seismogenic fault, and the main shock presents a thrust earthquake at low angle. We relocated 1014 earthquakes using the double-difference algorithm, and finally obtained 937 relocated events. Our results show that the earthquake sequences clearly demonstrate a unilateral extension about 50km nearly in NWW direction, and are mainly located above 25km depth, especially the small earthquakes are predominately located at the shallow parts. Furthermore, the focal depth profile shows a southwestward dipping fault plane at the main shock position, suggesting listric thrust faulting, which is consistent with the dip of the mainshock rupture plane. The spatial distribution of aftershocks represents that the Tarim block was thrust under the West Kunlun orogenic belt. In addition, the dip angle of the fault plane gradually increases along the NWW direction, possibly suggesting a gradual increase of strike-slip component during the NWW rupturing process. From above, we conclude that the Pishan M_S6.5 earthquake is the result of Tibet plateau pushing onto the Tarim block from south to north, which further confirms that the continuous collision of India plate and Eurasia plate has strong influence on the seismic activity in and around the Tibet plateau.     

COSEISMIC SURFACE RUPTURES AND SEISMOGENIC MUJI FAULT OF THE 25 NOVEMBER 2016 ARKETAO MW6.6 EARTHQUAKE IN NORTHERN PAMIR

The M_W6.6 Arketao earthquake,which occurred at 14:24:30 UTC 25 November 2016 was the largest earthquake to strike the sparsely inhabited Muji Basin of the Kongur extension system in the eastern Pamir since the M 7 1895 Tashkurgan earthquake.The preliminary field work,sentinel-1A radar interferometry,and relocated hypocenters of earthquake sequences show that the earthquake consists of at least two sub-events and ruptured at least 77km long of the active Muji dextral-slip fault,and the rupture from this right-lateral earthquake propagated mostly unilaterally to the east and up-dip.Tectonic surface rupture with dextral slip of up to 20cm was observed on two tens-meter long segments near the CENC epicenter and 32.6km to the east along the Muji Fault,the later was along a previously existing strand of the Holocene Muji fault scarps.Focal mechanisms are consistent with right-lateral motion along a plane striking 107°,dipping 76° to the south,with a rake of 174°.This plane is compatible with the observed tectonic surface rupture.More than 388 aftershocks were detected and located using a double-difference technique.The mainshock is relocated at the Muji Fault with a depth of 9.3km.The relocated hypocenters of the 2016 Arketao earthquake sequence showed a more than 85km long,less than 8km wide,and 5~13km deep,NWW trending streak of seismicity to the south of the Muji Fault.The focal mechanism and mapping of the surface rupture helped to document the south-dipping fault plane of the mainshock.The listric Muji Fault is outlined by the well-resolved south-dipping streak of seismicity.The 2016 Arketao M_W6.6 and 2015 Murghob M_W7.2 earthquakes highlight the importance role of strike-slip faulting in accommodating both east-west extensional and north-south compressional forces in the Pamir interior,and demonstrate that the present-day stress and deformation patterns in the northern Pamir plateau are dominant by east-west extension in the shallow upper crust.     

PRIMARILY STUDY ON FEATURES OF SURFACE RUPTURES INDUCED BY THE 2016 MW7.8 KARKOURA EARTHQUAKE,NEW ZEALAND

The surface ruptures produced by the 2016 M_W7.8 Karkoura earthquake, New Zealand are distributed in a belt with~170km long and~35km wide, trending generally in the NE-SW direction. There are at least 12 faults on which meter-scale displacements are identified and they were formed across two distinct seismotectonic provinces with fundamental different characteristics(Hamling et al., 2017; Litchfield et al., 2017). Although the trending directions of the seismic surface ruptures vary greatly at different locations, the ruptured faults can be generally divided into two groups with the NE to NEE direction and the NNW to N direction, respectively. The faults in the NNW-near NS direction are nearly parallel with 40~50km apart and featured by reverse movement with the maximum displacement of 5~6m. The faults in the NE-NNE direction, with the maximum of 25~30km apart are not continuous and featured by the dextral strike slip with the largest displacement of 10~12m. Even if some faults along the NE-NEE direction are end to end connected, their strikes differ by about 30°. The combination styles of the strike-slip fault surface ruptures along the NE-NEE direction can be merged into 3 categories, including en-echelon, bifurcation and parallel patterns. The scales of the fault surface ruptures with the same structural style could be obviously different in different areas, which results in significant changes in the widths of deformation zone, from tens of meters to hundreds of meters. En-echelon distributed surface rupture(section)can appear as a combination belt of meter-scale to dozens of meter-scale shear fracture with bulge and compressional shear fractures, and also can be characterized by the combination of the left-step en-echelon tensile shear fractures with a length of more than one hundred meters. The step-overs between surface rupture sections are clearly different in sizes, which can be dozens of meters, hundreds of meters to several kilometers. The spacing between parallel surface ruptures can be several meters, dozens of meters to several kilometers. Besides, as one of the prominent characteristics, the seismic surface ruptures caused by the Karkoura earthquake broke through the known distribution pattern of active faults. The surface ruptures can occur either on the previously thought inactive or unmapped faults, or break through the distribution range of previously realized active faults in the striking or lateral direction. The basic features about the distribution and widths of the surface ruptures induced by the 2016 M_W7.8 Karkoura earthquake, New Zealand presented in this paper might be helpful for understanding some seismic problems such as complex corresponding relationship between the active faults and the deep seismogenic structure, and the necessary measurements for engineering crossing active faults.     

1996年5月3日内蒙古包头西M_S6.4级地震的震源机制研究

利用地幔波波形拟合和P波初动符号联合反演的方法,估计了1996年5月3日内蒙古包头西MS6．4级地震的震源机制．得到节面1（40°,70°,－174°）,节面2（308°,84°,－20°）。主压力轴P（-13．95×1017Nm,262°,19°）,主张力轴T（15．66×1017Nm,356°,10°）,中性轴N（B）（1．52×1017Nm,112°,69°）．地震形成左旋走滑兼弱倾滑断裂,断裂面较陡．据ML≥3.0级的余震分布、Ⅷ度区的烈度分布以及宏观震中与微观震中的相对位置推测,节面2可能与实际的地震破裂面相近．据宽频垂直向（BHZ）波形记录中SP与P的到时差估计,震源深度约为21Km．