2016年11月13日新西兰凯库拉(Kaikoura)MW7.8地震同震位移和应力数值分析

2016年11月13日新西兰南岛北端凯库拉（Kaikoura）发生了M_W7.8大地震,造成了强烈的地表变形并引发大面积滑坡和海啸的发生.基于美国地质调查局（USGS）断层滑动模型,建立全球同震横向不均匀并行椭球型地球模型,计算了此次新西兰凯库拉大地震产生的同震形变和应力及库仑应力变化.初步计算结果表明：新西兰凯库拉M_W7.8地震造成断层上盘东北向抬升,下盘西南俯冲;引起发震区域同震位移较大,从凯库拉到坎贝拉（Campbell）以及首都惠灵顿（Wellington）整体上东北向抬升,最大同震水平位移1.2 m,垂直位移1.1 m.此次大地震释放了发震断层上积累的压应力,但增加了发震断层两端的挤压力;同时,同震剪应力变化增加了NE-SW向断层发生右旋滑动的危险性;采用此次地震发震断层参数计算得出的最大库仑应力变化增加区域集中在发震断层两端,可达到MPa量级.当分别采用新西兰北岛Awatere断裂系和南岛Wellington断裂系参数计算库仑应力变化时,发现新西兰北岛和南岛震中以南区域的库仑应力均增加,可触发部分余震的发生.     

1976年唐山7.8级地震在鲁北造成的震害情况及其烈度校订

1976年唐山7.8级地震对山东省北部的惠民及德州地区建筑物造成破坏和人员伤亡,震后山东省组成现场联合考察队进行了震害调查。对当年的现场考察资料做了系统整理分析,使用惠民及德州地区建筑物破坏和人员伤亡现场考察资料,补充相邻的河北省有关县（市）建筑物破坏资料,客观分析1976年唐山地震对鲁北造成的灾害情况,把该区地震烈度由原来的Ⅳ、Ⅴ度校订为Ⅵ度,Ⅵ度等震线大体沿肃宁—深县—德州—商河—黄河入海口一带分布,较原来Ⅵ度等震线（沿肃宁—沧州市—黄骅—渤海分布）向南移动约100 km,并对烈度及等震线修订的合理性进行了讨论。     

底商多层砌体房屋地震破坏机理及加固研究

正"小震大害"是我国地震灾害的真实写照,其中房屋的严重破坏和倒塌是造成人员伤亡和财产损失的重要原因。而底商多层砌体结构房屋是地震中破坏和倒塌最严重的一类房屋。在汶川地震极震区,这种类型房屋倒塌率达80%。底商多层砌体结构房屋在我国长江以南地区的中小城市非常普遍,据不完全统计,我国现存该类型的房屋约200万栋,涉及居住人口1.2亿。研究该类型结构抗震机理及对现有房屋的加固方法是当前防震减灾的迫切需求。     

无人机遥感技术在新疆皮山地震灾情获取中的应用

2015年07月03日,新疆维吾尔自治区和田地区皮山县（37.6°N,78.2°E）发生M_S6.5级地震,震源深度10km。本文利用高性能无人机数据采集平台获取灾区高分辨率影像数据,结合地震现场震害调查建立建筑物震害遥感解译特征,采用人工目视解译完成了灾区6个0.01°×0.01°格网评估区房屋类型及损毁程度应急遥感调查,获取测区地震灾情信息。结果表明:测区内房屋结构类型主要包括土木、砖木、砖混结构;倒塌房屋主要为土木结构及个别老旧砖木结构房屋,倒塌和局部倒塌的土木结构房屋占评估区土木结构房屋总数的68%,倒塌和局部倒塌的砖木结构房屋占评估区砖木结构房屋总数的12%;测区砖混结构房屋局部倒塌1间,未倒塌228间,砖混结构显示出良好的抗震性能,对避免人员伤亡和减少经济损失起到重要作用。     

南亚(巴基斯坦)地震灾害分布及成因分析

通过对南亚地震震害及其成因的分析表明,南亚地震灾害具有以下特点：①南亚地震的发震构造为喜马拉雅前缘弧形逆冲断层,地震地表破裂带发育的巴拉考特镇为此次地震的极震区,大量建筑物倒塌,造成严重的人员伤亡：②建筑物震害呈有规律分布：③地表破裂带和沿河谷两岸以及山坡的滑坡、建筑物没有抗震设防、建筑物结构不合理等是造成损失惨重的主因。     

尼泊尔8.1级地震建筑物震害遥感提取与分析

2015年4月25日尼泊尔发生的8.1级地震,造成重大人员伤亡与经济损失。在地震前、后灾区高分遥感影像分析处理基础上,结合现场实地调查,对灾区房屋建筑及其震害程度进行了遥感解译,编制了地震灾区房屋建筑震害分布图。结果分析表明:尼泊尔地震灾区影像上显示的建筑物震害分布与该区域房屋结构类型、主余震位置和区域活动构造分布密切相关。其中,房屋较为严重倒塌区域主要分布在8.1级主震和7.5级余震震中附近,但这两个区域并没有相连;居民点建筑物个别倒塌的居民地则连成一个区域。影像上显示的建筑物倒塌区域,与多数8级巨大地震比较,总体上极震区震害偏轻,但在南南西(垂直于破裂方向)上展布较宽。这一特征与引发该地震的印度与欧亚大陆板块边缘活动断裂在深部呈近似于平行地表的低角度断层面破裂引起的地震动能量在地表相对较宽而低的分布特征是一致的。     

针对大地震设防的地震动参数确定方法研究

正大地震(M≥7.0)是地震灾害的主要原因,建筑物倒塌是人员伤亡的直接原因。我国大地震频度大、分布广、危害大。我国当前的抗震设防体系在防御大地震、确定大震概率性设计地震动参数方面存在诸多不足。本文探讨了"大地震"与罕遇、极罕遇地震作用的区别与联系,并详细分析了基岩场地上罕遇地震动(50年超越概率2%)、极罕遇地震动(年超越概率     

汶川M_S8.0地震彭州灾区典型震害与成因初步分析

2008年5月12日14时28分汶川发生的8.0级大地震对我国四川省西部及西北部县市造成了特别严重,甚至是毁灭性破坏.基于现场调查资料,分析了彭州灾区的灾害空间分布,描述了典型建筑物破坏和大型滑坡体等地质灾害现象,并结合彭州地区房屋抗震设防情况,对此次地震灾害的主要成因进行了分析.结果表明,本次地震灾害的主要成因包括震级大、破坏力强,滑坡崩塌等地震地质灾害严重,农村建筑物缺乏必要的抗震设防措施等.在未来的规划与建设中,应避开断层、滑坡危险区域,并加强对农村地区建筑物的抗震设防指导.     

1738年青海玉树地震考证及其与2010年玉树7.1级地震关系探讨

2010年4月14日在青海玉树发生的Ms7.1级地震造成了严重的人员伤亡和重大的财产损失.根据现场考察结果,本次地震形成了长约51km的地震地表破裂带,性质为左旋走滑,最大水平位错约1.8m,其发震断裂为甘孜-玉树断裂的玉树段.在此之前,于1738年12月23日前在玉树附近还发生过另外一次大地震,造成全户伤亡无存或不堪...     

山西大同市农村民居震害特征及防震对策

1989年10月18日山西大同-阳高发生了6.1级地震,在这次地震中,倒塌房屋31 348间,其中,倒塌的大部分是土窑洞.可见,减轻地震灾害的关键是提高建筑物的抗震性能.     

2022年门源MS6.9和2016年门源MS6.4地震序列比较分析

2022年1月8日青海省海北州门源县发生M_S6.9地震,震中距离2016年1月21日门源M_S6.4地震震中约33km,两次门源地震均发生在冷龙岭断裂附近,但在震源机制、主发震断层破裂过程及地震序列余震活动等方面显著不同。针对两次门源地震序列的比较分析,对研究冷龙岭断裂及其附近区域强震序列和余震衰减特征等具有重要研究意义。通过对比分析2022年门源M_S6.9地震和2016年门源M_S6.4地震余震的时空演化特征,发现二者在震源过程和断层破裂尺度上存在明显差异,前者发震断层破裂充分,震后能量释放充分,余震丰富且震级偏高;而后者发震断层未破裂至地表,余震震级水平偏低。综合分析两次门源地震序列表现出来的差异性,认为其可能与地震发震断层的破裂过程密切相关,且同时受到区域构造环境的影响。     

Am improved source mechanism for the 1935 Timiskaming,Quebec earthquake from regional waveforms

The Timiskaming earthquake, which occurred near the Quebec-Ontario border at the northwest end of the Western Quebec seismic zone in 1935, is one of the five largest instrumentally recorded southeastern Canadian earthquakes. Previous studies of this earthquake concentrated on modeling teismograms recorded at regional distances, a better constrained focal mechanism is obtained. The waveforms indicate thrust faulting on a moderately dipping northwest striking plane at a depth of 10 km. TheM _w of 6.1 determined in this study is in good agreement with previous magnitude estimates (m _b 6.1,M _s 6.0, andm _bLg 6.2–6.3). The focal mechanism is similar to those of many recent small to moderate earthquakes in the region, and the inferred (from theP axis) acting stress of northeast compression is consistent with the overall eastern North American stress field. The Lake Timiskaming Rift Valley in which the earthquake occurred, comprises several northwest striking faults consistent with the strike of the 1935 event. Thus, the 1935 earthquake appears to be a result of faulting on the reactivated Timiskaming graben.     

2017年九寨沟7.0级地震前应力状态及b值异常特征研究

2017年8月8日青藏高原东缘四川九寨沟地区发生7.0级强震,依据前人研究结果分析九寨沟7.0级地震发震构造,并计算震前应力状态。结果显示:本次地震受到构造和历史强震的影响,是发生在历史强震引起的应力加载区域。另外,采用中国地震台网1990年以来的地震目录,在评估目录完整性的基础上,利用最大似然法计算得到2017年8月8日九寨沟7.0级地震前震源区及邻区地震b值空间图像。结果显示,九寨沟7.0级地震发生在四川北部地区显著低b值高应力异常区域内部(0.82b0.75)。所以,研究区域内外历史强震可能促进了九寨沟7.0级地震的发生。     

The December 26, 2004, off the west coast of northern Sumatra, Indonesia, M W=9.0, earthquake and the critical-point-like model of earthquake preparation

Long-term seismic activity prior to the December 26, 2004, off the west coast of northern Sumatra, Indonesia, M _W=9.0 earthquake was investigated using the Harvard CMT catalogue. It is observed that before this great earthquake, there exists an accelerating moment release (AMR) process with the temporal scale of a quarter century and the spatial scale of 1 500 km. Within this spatial range, the M _W=9.0 event falls into the piece-wise power-law-like frequency-magnitude distribution. Therefore, in the perspective of the critical-point-like model of earthquake preparation, the failure to forecast/predict the approaching and/or the size of this earthquake is not due to the physically intrinsic unpredictability of earthquakes. Foundation item: Ministry of Science and Technology Project (2004CB418406). Contribution No. 05FE3010, Institute of Geophysics, China Earthquake Administration.     

九寨沟M_S7.0地震震源机制解及构造应力场研究

2017年8月8日四川九寨沟县发生M_S7.0地震。根据中国地震台网固定台站的记录波形,利用gCAP方法和P波初动符号反演方法求解了主震的震源机制解,其结果与哈佛CMT震源机制解、美国地质勘探局发布的震源机制以及中国地震局发布的各震源机制解有很好的一致性。此外,还求解了九寨沟地震震中附近2010—2016年间28次小震的震源机制解,利用得到的小震震源机制解反演了该区域的构造应力场。结果表明,这一区域构造应力场的最大应力轴与最小应力轴均为水平方向,其中最大应力轴方向为NWW方向,最小应力轴方向为SSW方向。     

The Spatial Distribution and Attribute Parameter Statistics of Landslides Triggered by the May 12th, 2008, MW7.9 Wenchuan Earthquake

A complete landslide inventory and attribute database is the importantly fundamental for the study of the earthquake-induced landslide. Substantial landslides were triggered by the M_W7.9 Wenchuan earthquake on May 12^th, 2008. Google Earth images of pre- and post-earthquakes show that 52 194 co-seismic landslides were recognized and mapped, with a total landslides area of 1 021 km².Based on the statistics,we assigned all landslide parameters and established the co-seismic landslides database, which includes area, length, and width of landslides, elevation of the scarp top and foot edge, and the top and bottom elevations of each located slope. Finally, the spatial distribution and the above attribute parameters of landslides were analyzed. The results show that the spatial distribution of the co-seismic landslides is extremely uneven. The landslides that mainly occur in a rectangular area (a width of 30 km of the hanging wall of the Yingxiu-Beichuan fault and a length of 120 km between Yingxiu and Beichuan) are obviously controlled by surface rupture, terrain, and peak ground acceleration. Meanwhile, a large number of small landslides (individual landslide area less than 10 000 m²)contribute less to the total landslides area. The number of landslides larger than 10 000 m² accounts for 38.7% of the total number of co-seismic landslides, while the area of those landslides account for 88% of the total landslides area. The 52 194 co-seismic landslides are caused by bedrock collapse that usually consists of three parts:source area, transport area, and accumulation area. However, based on the area-volume power-law relationship, the resulting regional landslide volume may be much larger than the true landslide volume if the landslide volume is calculated using the influenced area from each landslide.     

Damage Investigation of the Hutubi MS6.2 Earthquake on December 8, 2016

The Hutubi M_S6.2 earthquake occurred on December 8, 2016, in Hutubi County, Xinjiang Uygur Autonomous Region, causing three people injured. The earthquake effected areas mainly included 25 townships and towns, plus Hutubi County and Manas County in Changji, Hutubi and Manas. The total effected area is 12,450km². In this paper, we summarize the seismo-tectonic background and geomorphic features of the earthquake zone. Under the guidance of the standard "The Earthquake Site Works-Parts 4:Assessment of Direct Loss", the damage to buildings and lifeline systems with various structural types are introduced, and we ultimately estimate the direct economic losses to mud-wood houses and the destruction of brick-wood houses. Our results indicate that "The Urban and Rural Seismic Safe Housing Project" played a key role in reducing this earthquake disaster.     

Moment Magnitude and Its Calculation

In this paper, we give a brief introduction to the proposal and development history of the earthquake magnitude concept. Moment magnitude M_W is the best physical quantity for measuring earthquakes. Compared with other magnitude scales used traditionally, moment magnitude is not saturated for all earthquakes, regardless of big and small earthquakes, deep and shallow earthquakes, far field and near field seismic data, geodetic and geological data, moment magnitude can be measured, and can be connected with well-known magnitude scales such as surface wave magnitude M_S. Moment magnitude is a uniform magnitude scale, which is suitable for statistics with wide magnitude range. Moment magnitude is the preferred magnitude selected by the International Seismological community, and it is preferred by the departments responsible for publishing seismic information to the public.Moment magnitude is a uniform magnitude scale, which is suitable for statistics with wide magnitude range. Moment magnitude is a preferred magnitude for international seismology, it is preferred by the agency responsible for providing information about earthquakes to the public. We provide all formulas used in the calculation of moment magnitude, and the calculation steps in detail. We also analyzed some problems and rules to solve these problems by using different formulas and numerical value calculation steps.     

Relocation of the MS5.7 Earthquake Sequence in Songyuan, Jilin Province, 2018 and the Analysis of Its Seismogenic Structure

The 2018,Songyuan,Jilin M_S5. 7 earthquake occurred at the intersection of the FuyuZhaodong fault and the Second Songhua River fault. The moment magnitude of this earthquake is M_W5. 3,the centroid depth by the waveform fitting is 12 km,and it is a strike-slip type event. In this paper,with the seismic phase data provided by the China Earthquake Network, the double-difference location method is used to relocate the earthquake sequence,finally the relocation results of 60 earthquakes are obtained. The results show that the aftershock zone is about 4. 3km long and 3. 1km wide,which is distributed in the NE direction. The depth distribution of the seismic sequence is 9km-10 km. 1-2 days after the main shock,the aftershocks were scattered throughout the aftershock zone,and the largest aftershock occurred in the northeastern part of the aftershock zone. After 3-8 days,the aftershocks mainly occurred in the southwestern part of the aftershock zone. The profile distribution of the earthquake sequence shows that the fault plane dips to the southeast with the dip angle of about 75°. Combined with the regional tectonic setting,focal mechanism solution and intensity distribution,we conclude that the concealed fault of the Fuyu-Zhaodong fault is the seismogenic fault of the Songyuan M_S5. 7 earthquake. This paper also relocates the earthquake sequence of the previous magnitude 5. 0 earthquake in 2017. Combined with the results of the focal mechanism solution,we believe that the two earthquakes have the same seismogenic structure,and the earthquake sequence generally develops to the southwest. The historical seismic activity since 2009 shows that after the magnitude 5. 0 earthquake in 2017,the frequency and intensity of earthquakes in the earthquake zone are obviously enhanced,and attention should be paid to the development of seismic activity in the southwest direction of the earthquake zone.     

浙江文成-泰顺交界M4.2地震烈度调查与震害特征

2014年9月12日至2014年10月31日,在浙江文成-泰顺交界的珊溪水库区域发生了最大震级M4.2地震。珊溪水库地区曾在2002、2006年分别发生过最大震级为ML3.9、ML4.6的地震序列,受这2次地震作用影响,震区房屋已经遭受了一定程度的破坏。2014年地震现场调查发现,震区震感明显,房屋受损现象较为普遍,震害具有叠加效应,出现了"小震致灾"的现象。另外,在震中附近的一些道路边坡上,地震还引发了规模较小的崩塌、滑坡等地质灾害。