1991年柯坪6．5级地震余震序列分析     

王伟利  尹光华  桂蓉 《内陆地震》2001,15(1):80-82

前言1 991年 2月 2 5日 ,新疆维吾尔自治区柯坪县发生 6.5级强烈地震。该地震发生在柯坪断裂与北西向扭张断层交汇部位附近 ,是柯坪断裂带近 1 5年来发生的最大一次地震 ,给柯坪县及巴楚附近地区造成了不同程度的破坏 (详细烈度区划见文献 [1 ])。根据新疆地震局地震台网测定 ,该地震微观震中位置位于北纬 40°2 0′,东经 79°0 1′,震源深度为 2 2 km;现场考察结果确定宏观震中位置为北纬 40°2 3′,东经 79°0 4′,震源深度为 2 2 km左右 ,两者相当接近。笔者通过对柯坪地震的余震频度衰减、能量释放、余震的空间分布特征等进行分析 ,总结…  相似文献   

柯坪地震的灾害评估     

尹光华  陈忠民 《内陆地震》1991,5(4):344-351

根据国家地震局震害防御司制定的“震害评估细则”对1991年2月25日柯坪6.5级地震的震害进行了评估。在实地调查的基础上,对灾区房屋破坏情况进行分区统计,对不同房屋进行分类统计并计算破坏比,得出该地震造成的总的经济损失约461万元。  相似文献   

广西靖西M_s5.2级地震房屋破坏特征          下载免费PDF全文

赵修敏    张忠利    牟剑英  韦王秋  杨钦杰 《世界地震工程》2021,(1):228-234

近年来广西地震发生频率明显提高,陆续发生了3次5级以上中强地震,包括2016年苍梧5.4级地震、2019年北流5.2级地震和2019年靖西5.2级地震,这可能意味着广西地区进入了地震活跃期。2019年靖西5.2级地震造成较重的房屋建筑物破坏,是分析广西房屋震害很好的样本。本文对各烈度区内不同结构类型房屋的震害现象进行了整理和统计,分析了不同结构类型房屋的震害特征与震害原因。结果显示:简易房屋除年久失修的之外基本完好;砌体结构房屋因结构不规则,缺乏抗震构造措施等,破坏较重,且破坏形式多样;框架结构房屋主体完好但填充墙会出现破坏。  相似文献   

2019年2月2日新疆塔城M_S5.2地震房屋震害特点与发震构造     

黄帅堂  马建  常想德  阿里木江·亚力昆  任静 《震灾防御技术》2020,15(2):339-348

2019年2月2日新疆塔城市发生M_S5.2地震，根据现场震害调查确定本次地震极震区烈度为Ⅵ度。地震造成震中附近20世纪八、九十年代建造的个别土木结构房屋出现中等程度以上破坏，少数轻微破坏(含旧裂缝加宽)，多数基本完好；其他结构类型房屋多数基本完好。本次地震震级小、有感范围广，震区土木结构房屋缺少抗震措施、年久失修、地基处理不当是造成房屋出现破坏的主要原因。综合分析等震线分布及深部构造特征，初步判定本次地震发震构造为塔克台断裂向塔城盆地迁移、扩展的隐伏断裂。  相似文献   

2016年2月11日新疆新源5.0级地震发震构造及房屋震害特点     

姚远  常想德  谭明  陈建波  裴亮 《地震工程学报》2016,38(S2):319-324

2016年2月11日新疆新源县发生MS5.0地震,极震区烈度为Ⅵ度。综合现场调查及地震等震线分布情况,初步判定本次地震的发震构造为阿吾拉勒山南缘断裂。对灾区乡镇的房屋进行调查,发现部分土木结构房屋未进行过抗震设计,在本次地震中破坏较为严重;部分砖木结构房屋地基未按照规范施工,在震动荷载作用下出现不均匀沉降,致使房屋墙体被拉裂、倾斜。数月前灾区发生过强降雨、冻融灾害,加之多次地震灾害叠加,造成本次地震房屋破坏率高、房屋破坏程度重。  相似文献   

2020年1月16日新疆库车5.6级地震烈度及房屋震害特征分析     

《内陆地震》2021,(1)

2020年1月16日新疆库车5.6级地震造成库车市塔里木乡居民房屋不同程度破坏。依据地震现场1个乡18个调查点的实地调查结果,初步分析此次地震的烈度分布和房屋震害特征。结果表明:地震灾区最高烈度为Ⅵ度,受灾面积为813.6 km~2,涉及185户685人,无人员伤亡;建造年代较早的砖木结构抗震安居房,由于抗震设防烈度较低,部分房屋抗震构造措施不完善,破坏程度相对较重;少数砖混结构房屋因地基沉降及地震叠加破坏作用,造成门窗洞口处墙体出现裂缝;框架结构房屋受场地地震动放大影响出现填充墙开裂现象。  相似文献   

1991年2月25日柯坪6.5级地震烈度及震害   总被引：1，自引：0，他引：1  

尹光华  陈忠民 《内陆地震》1991,5(2):169-174

0 前言 1991年2月25日北京时间22时30分25秒,在新疆阿克苏地区柯坪县境内发生6.5级强烈地震。柯坪县城及所属三乡一镇一场、生产建设兵团六个团场均有不同程度的震害。地震发生后,新疆地震局现场工作队和阿克苏中心地震台、地震办公室的同志参加了地震宏观考察与震害调查工作。本文是此次地震宏观考察工作的扼要总结。  相似文献   

云南漾濞MS6.4级地震土木结构房屋震害分析     

宴金旭  肖本夫  张露露  周琪  赵雪慧  格桑扎西 《华南地震》2021,41(3):71-75

通过对云南漾濞MS6.4级地震影响区范围内房屋震害调查发现,区域内土木结构房屋破坏较其他结构严重,主要分为"穿斗式"和"墙抬梁式"两种类型,两者在地震中的破坏虽有相同,但也各有特点.文章从两种类型土木结构房屋破坏比较明显的主体架构、屋顶、墙体和地基部位进行震害特点分析,结合调查情况发现造成房屋受损严重的主要原因为房屋自身结构缺陷抗震性能差、地震频发加重房屋震害、地形条件造成不均匀沉降.  相似文献   

九江瑞昌5．7级地震主要结构类型房屋破坏成因分析   总被引：5，自引：0，他引：5  

罗杰 《华南地震》2009,29(1):115-121

九江瑞昌5,7级地震是江西省近代以来强度最大、破坏最为严重的一次地震。由于震区地质条件复杂,房屋抗震性能差,再加上震源浅因而造成了大量民房的毁坏。在地震现场科学考查的基础上,针对灾区主要结构类型房屋的破坏情况,从灾区地震地质环境、不同结构类型房屋的分布情况和震害特征,对不同结构类型房屋的破坏成因作了较为客观的分析与总结。  相似文献   

1991年2月25日柯坪6.5级地震及监视预报     

柯坪地震工作组  王盛泽  王海涛 《内陆地震》1991,5(2):166-168

0 前言 1991年2月25日,新疆柯坪县南发生6.5级地震。震后第二天,自治区副主席毛德华率领慰问组立即奔赴现场对灾区各族人民进行慰问。新疆地震局及所属阿克苏中心台、阿克苏地震办公室以及国家地震局分析预报中心在震后即派出人员赴现场进行监视预报、宏观调查,并编写了“柯坪6.5级地震工作总结报告”。本文即为此报告部分章节缩写而成。  相似文献   

西南天山柯坪推覆构造柯坪塔格山前逆断裂东段晚第四纪的古地震   总被引：2，自引：2，他引：2       下载免费PDF全文

冉勇康  杨晓平  程建武  徐锡伟  陈立春 《地震地质》2006,28(2):245-257

柯坪推覆构造系是西南天山前陆推覆构造的重要组成部分。文中试图通过对柯坪推覆构造区的影像解译和野外观察、断错地貌的实测和探槽开挖,探讨柯坪塔格山前断裂东段晚第四纪以来的古地震活动。在三岔口以西的五道班—三间房一带和三岔口以东的大山口道班一带,除现代洪积扇外,明显可见2期保存较完整的洪积扇被断错。五道班—三间房地段的3个探槽揭露出了晚更新世末期以来该破裂段发生的4次事件,其参考年代为:距今22、14、6·5和4·4ka;重复间隔时间约为:8、7和2ka左右。间隔时间长的事件垂直位移量约1~1·2m,缩短量约1·3~1·4m;间隔时间短的事件,垂直位移量0·20~0·30m,缩短量0·6~0·7m。大山口道班段探槽揭露出了晚更新世末期以来的2次事件,分别发生在稍早于距今13ka和稍晚于距今6ka。重复间隔时间约7ka。同震垂直位移量约50cm,缩短量130cm左右  相似文献   

Analysis on the Characteristics of the Kalpin MS5.3 Earthquake Sequence of December 1, 2013 and Anomalies before the Earthquake     

Liu Jianming  Wang Qiong  Nie Xiaohong  Gao Ge  Zhang Linlin  Zhang Zhiguang  Xiang Yang 《中国地震研究》2017,31(3):381-394

This paper introduces the basic parameters, focal mechanism solutions and earthquake sequence characteristics of the Kalpin M_S5.3 earthquake sequence of December 1, 2013, and analyzed seismic activity before the earthquake, the adjacent tectonic features and the precursory anomaly at fixed points within a range of 200km. Research indicates:(1) The earthquake occurred on Kalpin fault, the source rupture type is thrust faulting with sinistral strike-slip component. (2) The earthquake sequence is mainshock-aftershock type, with the aftershock distribution attenuating quickly and trending NE. (3) Abnormal seismic activity before the earthquake was characterized by seismically nesting quiescence of M_S2.0-4.0 earthquakes, seismic quiescence of M_S4.0 earthquakes and seismic belts of M_S3.0 earthquakes in the Kalpin block, abnormal enhancement zone of moderate earthquakes on Puchang fault and seismological parameters. (4) Anomalies of precursory observation data at fixed stations are mainly characterized by mutation. Apart from the borehole tiltmeter in Halajun, the spatial distribution of other abnormal precursors showed a phenomenon of migration from the near field to far field and from the epicenter to the peripheries.  相似文献   

西南天山柯坪逆冲推覆构造带的地壳缩短分析   总被引：7，自引：5，他引：7       下载免费PDF全文

杨晓平  冉勇康  宋方敏  徐锡伟  程建武  闵伟  韩竹军  陈立春 《地震地质》2006,28(2):194-204

柯坪逆冲推覆构造带是西南天山山前晚新生代以来形成的活动逆断裂-褶皱带,由5~6排近平行的弧形褶皱带组成,出露地层为寒武系—第四系。背斜形态多为复式箱状背斜和不对称的斜歪背斜,分别与断层弯曲背斜和断层扩展背斜的几何形态一致。地震勘探资料显示,各褶皱带前缘活动逆断裂在深部归并于统一的、由寒武系中的石膏层组成的滑脱面。滑脱面深度具有南浅北深、东浅西深的特点,皮羌断裂西侧滑脱面深度约为9km,东侧滑脱面深度为5km。在柯坪逆冲推覆构造中部的皮羌断裂东西两侧各5km和8km的位置,以断层弯曲褶皱和断层扩展褶皱构造模型为指导,用线长平衡的方法完成了2条长度分别为78km和73km的平衡地质剖面,恢复到变形前的形态后计算出这2条剖面上的地壳缩短量分别为40km和45km,缩短率为33%和37%。由于对柯坪逆冲推覆构造开始形成时间的证据较少,所以要计算长期的缩短速率是比较困难的。对比天山南麓库车活动逆断裂-褶皱带的形成时代,以及柯坪逆冲推覆构造与印干断裂的关系,认为柯坪逆冲推覆构造形成于第四纪早期的西域砾岩沉积阶段,按距今2.5Ma计算,柯坪逆冲推覆构造的地壳缩短速率是15.4~17.3mm/a  相似文献   

南天山及塔里木北缘构造带西段地震构造研究   总被引：4，自引：0，他引：4       下载免费PDF全文

田勤俭  丁国瑜  郝平 《地震地质》2006,28(2):213-223

南天山及塔里木北缘构造带位于帕米尔地区东北侧,地震活动强烈。文中通过地质构造剖面、深部探测资料和地震震源机制解资料,综合研究了该区的地震构造模型。结果认为,该区的构造活动主要表现为天山地块逆冲于塔里木地块之上。天山构造系统包括迈丹断裂及其前缘推覆构造;塔里木构造系统包括深部的塔里木北缘断裂、基底共轭断层和浅部的推覆构造。塔里木北缘断裂是发育于塔里木地壳内部的高角度断裂,其形成原因在于塔里木和天山构造变形方向的差异。塔里木北缘断裂为研究区大地震的主要发震构造,天山推覆构造和塔里木基底断裂系统均具有不同性质的中强地震发震能力  相似文献   

新疆南部构造区带与地震活动状态研究     

曲延军  王琼  聂晓红 《中国地震研究》2012,26(2):222-233

Based on the studies of earthquake activity, tectonic movement, crustal shortening rate, fault activity, local stress field and historical characteristics of strong earthquake activities in Xinjiang, we divide the south part of Xinjiang into 4 seismotectonic zones, namely, the eastern segment of south Tianshan seismic belt, the Kalpin block, the Kashi-Wuqia junction zone, and the west Kunlun Mountains seismic belt. Using earthquake catalogues from Xinjiang since 1900, and on the basis of integrity analysis of earthquake records in different magnitude ranges, the seismicity state of different seismotectonic zones is analyzed quantificationally by calculating the mean value of annual strain energy release, annual rate of earthquakes with different lower limits of magnitude, b-value, and the parameter m of accelerating strain release model. The characteristic indexes of seismicity state for each of the seismic tectonic zones are then determined, which provide a quantitative basis for earthquake tendency analysis and judgment.  相似文献   

Seismotectonic Study on the West Part of the Interaction Zone Between Southern Tianshan and Northern Tarim     

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   

1906年新疆玛纳斯大震区的多层次逆冲构造与深部结构   总被引：10，自引：0，他引：10       下载免费PDF全文

杨晓平  顾梦林  孙振国  赵成斌  周庆 《地震地质》2002,24(3):303-314

通过对天山北麓 190 6年玛纳斯 7 7级地震区的浅层地震探测资料、石油地震反射剖面、二维电性结构剖面、深地震反射剖面的研究 ,发现玛纳斯地震区多层次活动构造系统的根带 ,它通过脆 -韧转换带与天山活动构造块体内上地壳中的低速、高导层连为一体。低速、高导层可能是天山地壳内正在活动的韧性剪切带 ,而齐古逆断裂 -褶皱带下的脆 -韧转换带是连接深部活动韧性剪切带与地壳浅部脆性破裂的枢纽 ,也是现今孕育和发生大地震的重要构造部位。 190 6年玛纳斯地震发生在脆韧转换带的底部 ,地震区的活动逆断裂和褶皱只是部分记录了深部韧性剪切带活动的信息  相似文献   

FOCAL MECHANISM SOLUTION AND TECTONIC STRESS FIELD CHARACTERISTICS OF THE MIDDLE TIANSHAN MOUNTAINS,XINJIANG          下载免费PDF全文

ZHANG Zhi-bin ZHAO Xiao-cheng REN Lin 《地震地质》1979,42(3):595-611

The middle part of the Tianshan Mountains in Xinjiang is located in the north-central part of the Tianshan orogenic belt, between the rigid Tarim Basin and Junggar Basin. It is one of the regions with frequent deformation and strong earthquake activities. In this paper, 492 M_S>2.5 earthquake events recorded by Xinjiang seismograph network from 2009 to 2018 were collected. The M_S3.5 earthquake was taken as the boundary, the focal mechanism solutions of the earthquake events in this region were calculated by CAP method and FOCEMEC method respectively. At the same time the focal mechanism solutions of GCMT recorded historical earthquake events in this region were also collected. According to the global stress map classification standard, the moderate-strong earthquakes in the region are mainly dominated by thrust with a certain slip component, which are distributed near the combined belts of the Tarim Basin, Junggar Basin, Turpan Basin and Yili Basin with Tianshan Mountains. The thrust component decreases from south to north, while the strike-slip component increases. The spatial distribution characteristics of the tectonic stress field in the middle section of the Tianshan Mountains in Xinjiang are obtained by using the damped regional-scale stress field inversion method. The maximum principal compressive stress in axis the study area rotated in a fan shape from west to east, the NW direction in the western section gradually shifted to NE direction, its elevation angle is nearly horizontal, in the state of near horizontal compression. The minimum principal compressive stress axis is nearly EW, and the elevation angle is nearly vertical. Influenced by large fault zones such as Kashi River, Bolhinur, Nalati, Fukang, the southern margin of the Junggar and the north Beiluntai, the local regional stress field presents complex diversity. Under the influence of the northward extrusion of Pamir and Tarim blocks, the whole Tianshan is shortened by compression, but its shortening rate decreases from south to north and from west to east, the stress shape factor increases gradually from west to east, the intermediate principal compressive stress axis exhibits a change in compression to extension. There are some differences in the characteristics of tectonic stress field between the north and south of Tianshan Mountains. The regional maximum principal compressive stress axis is 15° north by east on the south side, while it is nearly NS on the north side. The deformation of the Tianshan Mountains and the two basins on both sides is obviously larger than that in the inside of the mountain. Changes in the crustal shortening rate caused by the rotation of the rigid Tarim block and Junggar block to the relatively soft Tianshan block, as well as the uplifts of Borokonu and Bogda Mountains, the comprehensive influence of the material westward expansion constitute the stress field distribution characteristics of the north and south sides of the middle section of Tianshan Mountains. The recent two M_S6.6 earthquakes in the region caused the regional stress field to rotate counterclockwise. The post-earthquake stress field and the main source focal mechanism solution tend to be consistent. The seismic activity in the study area is week in the south and strong in the north. The focal depth is about 20km. Most strike-slip earthquakes occur near the junction belt of the Tianshan and Junggar Basin.  相似文献   

新疆及周缘构造破裂特征及地震序列类型   总被引：2，自引：0，他引：2       下载免费PDF全文

李莹甄  张博  殷娜  沈军  邵博 《地震工程学报》2016,38(1):36-45

横亘新疆境内的天山及其周边的西昆仑、阿尔金和阿尔泰是中国大陆著名的强构造运动区和地震活动带。在对新疆构造区应力环境、动力过程、断层运动变形特征和地震序列分析讨论的基础上,对新疆及其周缘主要构造区地震破裂方式和序列类型进行研究,得出如下结论:(1)西昆仑构造区受来自青藏块体和塔里木块体NS和NW向水平压应力和垂向力的作用,构造运动呈现出走滑与逆冲特征,震源破裂以走滑型为主,数量较少的逆断型地震主要分布在西昆仑帕米尔一侧的深震挤压区,正断型地震主要出现在西昆仑与阿尔金交汇的拉张盆地及附近。该区主余型地震占63%,6级以上地震序列也存在多震类型。(2)阿尔金断裂带位于西昆仑北缘断裂和北祁连断裂过渡带,受青藏块体向北和向西的推挤,断裂本身的左旋位移量通过两端逆冲挤压而转化,使得青藏高原北边界不断向外扩展。在此力源下,阿尔金断裂带震源破裂以走滑为主,也有少量的逆冲型地震。地震序列中主余型和孤立型地震占比相同(占44%)。(3)在印度板块和亚欧大陆碰撞效应影响下,天山地区产生近NNE向水平压应力,构造运动显现出带旋性特征的逆冲和走滑,震源破裂方式与之相吻合。而天山构造大跨度的空间展布、扩展形式的多样性和地震破裂的两重性,又影响到地震序列类型的多样性,使得主余型、孤立型和多震型地震在不同构造部位呈现优势分布。(4)阿尔泰的构造运动可能受到了来自印度板块与亚欧板块碰撞的远程效应和西伯利亚块体南向运动的双向影响,形成NNE和SW向水平挤压力,主要大型发震断裂做右旋剪扭错动,而一些深断裂则以逆冲运动为主。震源破裂呈现出走滑(占64%)和部分的逆冲(占27%),6级以上地震序列主要为主余型,5级左右地震则多为孤立型。  相似文献   

Active faults and seismogenic models for the Urumqi city,Xinjiang Autonomous Region,China          下载免费PDF全文

Yingzhen Li  Yang Yu  Jun Shen  Bo Shao  Gao Qi  Mei Deng 《地震科学（英文版）》2016,29(3):173-184

We have studied the characteristics of the active faults and seismicity in the vicinity of Urumqi city, the capital of Xinjiang Autonomous Region, China, and have proposed a seismogenic model for the assessment of earthquake hazard in this area. Our work is based on an integrated analysis of data from investigations of active faults at the surface, deep seismic reflection soundings,seismic profiles from petroleum exploration, observations of temporal seismic stations, and the precise location of small earthquakes. We have made a comparative study of typical seismogenic structures in the frontal area of the North Tianshan Mountains, where Urumqi city is situated,and have revealed the primary features of the thrust-foldnappe structure there. We suggest that Urumqi city is comprised two zones of seismotectonics which are interpreted as thrust-nappe structures. The first is the thrust nappe of the North Tianshan Mountains in the west, consisting of the lower(root) thrust fault, middle detachment,and upper fold-uplift at the front. Faults active in the Pleistocene are present in the lower and upper parts of this structure, and the detachment in the middle spreads toward the north. In the future, M7 earthquakes may occur at the root thrust fault, while the seismic risk of frontal fold-uplift at the front will not exceed M6.5. The second structure is the western flank of the arc-like Bogda nappe in the east,which is also comprised a root thrust fault, middle detachment, and upper fold-uplift at the front, of which the nappe stretches toward the north; several active faults are also developed in it. The fault active in the Holocene is called the South Fukang fault. It is not in the urban area of Urumqi city. The other three faults are located in the urban area and were active in the late Pleistocene. In these cases,this section of the nappe structure near the city has an earthquake risk of M6.5–7. An earthquake M_S6.6, 60 km east to Urumqi city occurred along the structure in 1965.  相似文献