2019年5月18日松原M5.1地震构造机制分析

基于区域地震台网的数字化波形资料,使用ISOLA方法对2019年5月18日吉林松原M5.1地震进行矩张量反演,研究地震的震源机制,并且收集了地震序列中M_L2.5以上地震的震源机制解,采用FMSI（focal mechanism stress inversion）方法反演震中区构造应力场。结果显示：松原M5.1地震的矩震级为4.9,矩心深度为6 km,双力偶分量为91.5%,主压应力P轴方位角、倾角分别为76°和3°,主张应力T轴方位角、倾角分别为166°和16°,震源机制解显示典型的构造地震特征;震中区构造应力场理论应力轴σ₁方位角、倾伏角分别为88.0°和0.9°,σ₂方位角、倾伏角分别为178.2°和9.6°,σ₃方位角、倾伏角分别为352.5°和80.4°,这一结果与区域构造应力场一致。推断认为区域构造应力场触发了2019年松原M5.1地震活动,地震震源机制解的北西向节面与震中区附近的第二松花江断裂现今活动性质完全一致,认为第二松花断裂可能是松原M5.1地震的发震断层。     

2017年九寨沟7.0级地震序列震源机制解和构造应力场特征

九寨沟余震序列的震源机制和构造应力场有助于认识本次地震的发震构造和孕震机理。本文基于四川区域地震台网的波形资料, 采用波形拟合(CAP)方法和P波初动+振幅比(HASH)方法反演得到2017年8月8日九寨沟7.0级地震序列中59次ML≥3.0地震的震源机制解, 并基于该结果采用阻尼线性逆推法(DRSSI), 计算研究区域的平均构造应力场, 给出该区域的应力场特征。结果显示, 利用CAP方法反演得到的本次主震的最佳双力偶机制解节面I: 走向248°/倾角86°/滑动角–169°, 节面II: 走向157°/倾角79°/滑动角–4°, 矩震级为Mw6.31, 矩心深度5 km, 属走滑型地震事件; 大部分余震的震源机制解错动类型与主震一致, 矩心深度集中在3~10 km; 应力场反演结果显示, 该区域周边的应力性质为走滑型, 最大主应力方向呈NWW–SEE向, 与该区域的应力场方向一致, 表明本次地震主要受区域应力的控制。结合该区域的地震地质构造等已有研究成果, 分析认为此次地震的发震断层为走向NW–SE、倾向SW的左旋走滑断裂——树正断裂, 巴颜喀拉块体向E-SE向的水平运动受到华南块体的强烈阻挡导致此次地震的发生, 汶川地震的发生对本次地震具有一定的促进作用。     

青藏铁路沿线构造活动性评价和工程稳定性区划

构造活动强度α(≤1)和地壳稳定程度β(≤1)是构造活动性评价和工程稳定性区划的重要参数，α=1-β。对青藏铁路沿线任一单元i，以断层运动速率(vi)、地震震级(Mi)、温泉温度(Ti)和构造应变(εi)综合刻画构造活动强度(αi)，αi=(vi/vmax Mi／Mmax Ti/Tmax εi／εmax)/αmax。根据各单元构造活动强度值(αi)，应用克里格等值线绘制软件，编制构造活动强度等值线图，为青藏铁路沿线构造活动性评价和工程稳定性区划提供定量判据。α≥0．40的构造活动区可能孕育Ms≥6-7级地震，对应于不稳定区：α≥0.70的强烈构造活动区可能孕育8级左右强烈地震，对应于极不稳定区。区划结果表明，青藏铁路沿线发育昆仑山南、可可西里、通天河、唐古拉山、错那湖、当雄、羊八井7个不稳定区，其中包括西大滩、谷露盆西、羊八井3个极不稳定区。     

滇西南2014年景谷中-强震群的地质构造成因——茶房-普文断裂带贯通过程的构造响应

2014年10—12月期间,云南景谷接连发生了Ms6.6、Ms5.8、Ms5.9三次中-强地震。为确定地震的地质构造成因,在地表调查的基础上,综合该区的地质构造情况、烈度与余震分布、震源机制解等资料,确定此次震群活动的宏观震中位于永平盆地东南侧山地,发震断层为地质与地貌表现不显著的NW向右旋走滑断层。此次震群活动及余震迁移过程指示,由于断层斜接部位岩桥的临时阻碍,Ms6.6地震破裂在向南东扩展过程中发生短暂停滞,突破障碍后进一步引发了Ms5.8和Ms5.9地震,这符合震源破裂沿NW向发震断裂分段破裂的行为。区域活动断裂的遥感解译结果发现,发震断层位置恰好处于NW向右旋走滑的茶房断裂与普文断裂之间,区域上属于该断裂带的不连贯部位,指示此次中-强震群活动应该是茶房-普文断裂带贯通过程的构造活动表现。结合思茅地块的历史地震资料发现,思茅地块地震活动多以小于等于6.8级为主,发震构造多为NW向断裂。指示在现今构造应力场作用下,该区NW向断裂的活动性相对NE向断裂更加显著,属于该区主要控震构造,应在今后的地震地质工作中给予更多关注。     

辽宁沿海地区构造活动性分析与评价

辽宁沿海地区区域地质构造复杂,新构造运动强烈,活动断裂发育,地震活动频繁。通过对沿海地区地形地貌及活动构造的调查分析,对辽宁沿海地区区域地壳稳定性进行评价,辽宁沿海地区主要为相对稳定区和相对较稳定区。     

泉州市中心城区区域地壳稳定性分析

在前人工作成果的基础上,对泉州市中心城区的区域地壳结构、区域地质构造、新构造运动、区域构造应力场和区域地震活动性进行综合分析.分析结果表明,泉州市中心城区在第四纪中更新世之前位于环太平洋中、新生代构造一岩浆活动带中,地壳运动频繁而又强烈,区域地质构造复杂;现代处于菲律宾海板块对欧亚板块挤压形成的"台湾动力触角"影响区,但区内的断裂不具全新世活动性,新构造运动不强烈,有史以来未见≥5.0级地震记载,属于地壳相对稳定区,未来遭遇6.0级地震的危险性不大,其地震破坏性影响主要来自周边孕震区,特别是东部海域,与"台湾动力触角"的作用和滨海断裂带的活动有关.     

上海及邻区新构造应力场初步探讨

本文从活动断裂、水系分布方向、地震震源机制解三个方面,对上海及邻区新构造应力场进行了探讨。从新构造期活动断裂的力学性质分析,本区主压应力场方向为北东东至近东西;从水系河谷分布的优势方向推论出的主压应力场方向为96°左右;用本区56个地震震源机制解的 P轴赤平极射投影的极点统计分析法,确定主压应力方向约为80°;三者大体一致,说明它们是同一构造应力场的产物,其主压应力场方向为近东—西向。     

地震震源与灾害评估分析:中国四川2008年5月12日Ms 8.0汶川地震

汶川5月12日8.0级地震在构造上起因于印度板块与欧亚板块以每年约5 cm的速度聚敛,并因此而引起青藏高原的地壳物质向四川盆地及中国东南大陆运移.主震震源及余震活动集中于以龙门山为中轴的一条长约350 km、宽约100 km的地震活动带.震源深度一般分布丁地壳脆性-韧性转换边界以上约10～20 km区间的地壳震源层之中,属浅源构造地震.主要震源机制与龙门山构造运动方式密切相关,以其地壳厚度向西急剧加厚、重力梯度带、高波速比(Vp/Vs～2.2)等深部异常及逆冲断层兼具走滑性质的地质构造为特征.在震源辐射、路径传播和场地效应研究的基础上,分别计算并比较了岩石和土壤条件下的地震响应谱,特别强调了土壤条件下的场地放大效应;同时对与地震安全性有关的一些问题如地质灾害、地震频谱设计、地震早期预警系统及中、长期至短期地震预报等进行了探讨;特别提供了一个由加权平均计算、以岩石条件下震波衰减模式为基础的地震频谱设计参考实例.地震构造与动力学研究可融人工程地质与环境工程等学科发展.经历汶川地震考验的一些新近设计和建设的工程项目可为今后改进工程建筑规范与标准提供重要而有益的参考.地震预报是当今一大难题,但需探索研究,不可懈怠.地震减灾与预防足目前比较切合实际的安全举措.     

九寨沟7.0级地震的地震断裂及震源破裂的构造动力学机理研究

本文针对九寨沟7.0级地震的发震构造及震源破裂的构造动力学问题,从地质调查、测试与震源构造动力学理论分析相结合的角度阐明:此次地震发生在处于高法向应力左旋剪切受力状态的岷山隆起带北端与西秦岭地槽褶皱带之南缘文县-玛沁断裂相交汇部位;沿"九寨天堂"-震中-五花海以及上四寨村-中查-比芒一线发育的两条具有构造破裂特征的NW向地裂缝带,是"隐伏状"地震断裂错动造成的地表同震破裂,前者是本次地震的控震构造,后者是NW向断层的次级同震复活及扩展;此次地震的震源断层错动过程受NW331°走向的陡倾角（∠87°）断层节面控制的走滑型剪切破裂,断裂两端的剪切破裂表现出持续扩展趋势;震源构造动力学过程实质上是地壳深部沿NW方向左旋剪断"凸出体";地震断裂带两端破裂扩展的持续发展,将导致地壳"凸出体"逐步剪断贯通。     

肃北县德勒诺尔铁矿区构造应力场分析

本文以德勒诺尔铁矿区发育的节理为研究对象,在约20ｋｍ²的研究区内布置了93个观测点,在野外共观测三百余组节理,采用数学统计方法,对节理进行分期配套,确定区内主要发育3组高倾角平面X剪节理,通过节理之间相互错断、限制关系对节理期次进行配套分析,并对不同期次构造应力场形成的共轭剪节理进行了研究,利用吴氏网绘制各观察点的主应力图解,获得各点应力轴（σ₁,σ²,σ₃）的产状。研究得出本区第1次构造应力场最大主压应力轴（σ₁）的优选产状为181°∠8°,中间应力轴（σ²）为141°∠81°,最小主应力轴（σ₃）为89°∠5°,可能是区内的主体构造格架的动力来源,在区内形成了近ＥＷ向的复式背斜及叠瓦状逆冲断裂。第２期构造应力场最大主压应力轴呈NE—SW向,最大主压应力轴（σ₁）的优选产状为250°∠12°,中间应力轴（σ²）为56°∠78°,最小主应力轴（σ₃）为143°∠11°,为区内形成NW—NWW向展布的逆冲断裂的主要动力来源。第３期构造应力场最大主压应力轴呈NNW—SSE向,最大主压应力轴（σ₁）的优选产状为344°∠3°,中间应力轴（σ²）为79°∠80°,最小主应力轴（σ₃）为252°∠13°,可能为区内ＮＷ、ＮＥ向展布的张性断裂的主要动力来源。研究总结了区内不同期次构造应力场的特征,并对动力来源进行了初步探讨。     

基于深地震测深的深部动力学研究方法和应用

深地震测深是探测壳幔岩石圈精细速度结构、探讨岩石圈变形和演化过程的一种有效方法,在青藏高原隆升、克拉通裂解等大陆动力学研究中已发挥了重要的作用。然而,地震测深方法与深部动力学研究的结合尚处于现象描述为主的状态。因此,本文对前人利用深地震测深资料进行深部动力学研究的相关方法进行了回顾与总结:宽角反射/折射地震震相特征具有明显的动力学响应,是进行动力学研究的基础;通过速度结构对比可以确定不同地壳速度结构模型所对应的构造单元及其演化过程,地壳厚度和泊松比等参数可以用于地壳变形模式的讨论,壳内高速和低速异常体反映了不同动力学过程对地壳的改造;人工地震S波资料与Pn波速度可以用于壳幔各向异性的研究,为动力学演化过程研究提供独立的观测证据;运用现代构造解析方法可以构建不同的地壳结构—动力型式,进而通过壳幔结构的解构恢复岩石圈演化过程;此外,地震测深资料可以约束地壳成分结构,为动力学数值模拟提供岩石流变参数等资料。本文对于充分挖掘深地震测深资料在动力学研究中的应用价值至关重要,对于加强地震测深同其他学科的交叉研究也具有重要意义。     

Quantitative Tectonic Markers of Large Coastal Earthquakes in Fujian, Guangdong, Taiwan and Hainan——with a Discussion of Qualitative Indicators

This paper expounds the quantitative tectonic indicators and some qualitative indicators of large earthquakes in the coast areas of Fujian, Guangdong, Taiwan and Hainan. The main quantitative indicators include uplift amplitude of the Moho, Quaternary and Late Holocene coasts. The paper also gives a brief account of the research method on quantitative indicators of surface uplifted zones. Taiwan is a famous neotectonic zone and an area of large earthquakes in the world. There is only one large-earthquake area in each of Fujian, Guangdong and Hainan Provinces. Along the coast large earthquake areas there are certainly many remains of crustal activity. Among these remains, coast activity, taking the sea level as the accurate marker horizon, can determine not only the amplitude of coastal elevation and subsidence in a certain period, but also the cycle and rate of positive or negative movements.     

Estimation of the 3-D velocity structure of the Sorachi–Yezo and Oshima Belts in the western part of Hokkaido, Japan

We adopted the seismic tomography technique to refine the three-dimensional velocity structure model of the western part of Hokkaido, Japan. Using the P-wave first arrival data listed by Japan Meteorological Agency from 2002 to 2005, we could estimate a 3-D inhomogeneous velocity structure model with a low velocity at a depth of 14 km beneath Asahikawa. The crustal structure near Sapporo was characterized by lateral velocity change toward the southern seaside. The low-velocity zone near Urakawa, proposed by previous research, was also clarified. In general, the present model showed lower-velocity values for most of the crustal layers in the area concerned. The results of this study were affected by less number of higher magnitude events (M?≥?0.5) in the central part of the area of interest. However, the perturbation results for comparatively shallow layers (6–50 km) were good in resolution. It was found that the source region of the Rumoi–Nanbu earthquake of December 14, 2004 was characterized by a low-velocity zone, located between high velocity zones. Such an inhomogeneous crustal structure might play an important role in the relatively high seismic activity in the Rumoi–Nanbu earthquake source region.     

中国大陆科学钻探场址区的地壳速度结构特征

为了深入研究大别—苏鲁超高压变质带的深部结构及空间展布特征, 进一步揭示该超高压变质形成的动力学过程, 在中国大陆科学钻探场址区进行了广角反射/折射地震测深调查.根据广角反射/折射地震测深的资料研究, 建立了中国大陆科学钻探场址区的地壳纵波速度结构.从纵向上来看, 研究区域的地壳结构可划分为上、中、下3层: 上地壳的速度小于6.2 0km/s, 厚10余km; 中地壳的速度为6.4 0km/s, 厚亦为10km左右; 下地壳的速度为6.6 0km/s.地壳厚度为31km左右, 且其地壳的平均速度为6.30km/s.上地壳中的速度倒转指示了超高压变质体在地壳内部的空间分布, 且超高压变质体在大陆科学钻探场址及其附近的下部呈现为一隆起形态.      

Role of crustal heterogeneity beneath Andaman–Nicobar Islands and its implications for coastal hazard

The Andaman–Nicobar (A–N) Islands region has attracted many geo-scientists because of its unique location and complex geotectonic settings. The recent occurrence of tsunamis due to the megathrust tsunamigenic north Sumatra earthquake (Mw 9.3) with a series of aftershocks in the A–N region caused severe damage to the coastal regions of India and Indonesia. Several pieces of evidence suggest that the occurrence of earthquakes in the A–N region is related to its complex geodynamical processes. In this study, it has been inferred that deep-seated structural heterogeneities related to dehydration of the subducting Indian plate beneath the Island could have induced the process of brittle failure through crustal weakening to contribute immensely to the coastal hazard in the region. The present study based on 3-D P-wave tomography of the entire rupture zone of the A–N region using the aftershocks of the 2004 Sumatra–Andaman earthquake (Mw 9.3) clearly demonstrates the role of crustal heterogeneity in seismogenesis and in causing the strong shakings and tsunamis. The nature and extent of the imaged crustal heterogeneity beneath the A–N region may have facilitated the degree of damage and extent of coastal hazards in the region. The 3-D velocity heterogeneities reflect asperities that manifest what type of seismogenic layers exist beneath the region to dictate the size of earthquakes and thereby they help to assess the extent of earthquake vulnerability in the coastal regions. The inference of this study may be used as one of the potential inputs for assessment of seismic vulnerability to the region, which may be considered for evolving earthquake hazard mitigation model for the coastal areas of the Andaman–Nicobar Islands region.     

Uplift of the Longmen Shan area in the eastern Tibetan Plateau: an integrated geophysical and geodynamic analysis

Abstract

The mechanism for uplift of the eastern Tibetan Plateau is still a matter of debate. There are two main models: extrusion and crustal flow. These models have been tested by surface observations, but questions about the uplift remain. In addition, the devastating 2008 M_w 7.9 Wenchuan earthquake along the Longmen Shan fault zone (LMSFZ) reminds us that the tectonic activity within eastern Tibet is complex and poses a major natural hazard. This activity is accompanied by dramatic uplift along the LMSFZ, but only minor convergence (<4 mm year^–1) against the Sichuan basin is observed. In order to investigate the mechanism for uplift of Longmen Shan (LMS) area, we explored the lithospheric structure across the Songpan–Ganzi terrane (SGT), LMS, and western Sichuan basin by undertaking an integrated analysis of a variety of data including new, logistically challenging controlled-source seismic profiling (reflection and refraction) results, receiver function estimates of crustal thickness, gravity and magnetic data, GPS data, and geologic constraints. Our analysis of crustal structure indicates that the crust is not thick enough to support its current elevation and that the crust is essentially composed of three layers of similar thickness. Thus, based on our crustal structure model, 2D numerical modelling was conducted to investigate uplift mechanisms. The modelling results indicate that the middle crust beneath the SGT is the most ductile layer, which is the key factor responsible for the crustal-scale faulting, earthquake behaviour, and periods of uplift. In addition, the modelling results indicate that the strong Sichuan block acts as a backstop for the thrusting along the LMS and crustal thickening to the west.     

闽南区域地壳稳定性分区及其特征

通过一系列区域地壳稳定性背景资料的分析，以地壳结构、深断裂、活动断裂、第四纪升降速率、大地热流值、布格异常梯度、地壳应变能量、地震最大震级、基本烈度等综合指标，将闽南区域的地壳稳定性，自西而东划分为稳定区、基本稳定区和次稳定区。     

滩海区人工岛场地地震安全性评价

本文以辽河口滩海区人工岛场地为例, 从区域地震地质、近场区地震地质、区域地震活动等方面, 讨论了滩海区人工岛基本地震地质环境特点, 在此基础上, 完成场地地震烈度、地震设防参数、场地地震地质灾害等影响人工岛场地安全性的因素评价。结果说明, 从场地地震安全性角度, 本文所评价的场地, 对人工岛兴建是适宜的。     

松潘—甘孜地区百年地震构造和现今动力学

研究区位于青藏高原的东北隅(96°～107°E,30°～35°N)。基于该地区长度大于2km的4 781条1∶20万数字化实测断裂、1900年以来的5 220条数字地震记录,以及野外地质观测数据,识别出993条不同属性的地震断层,构建了该地区百年地震构造格局。1970年以来十年期地震断层跃迁图像表明,自20世纪80年代中期白马—虎牙强烈震群爆发之后,地震活动在沿各主要走滑断层带自西(北西)向东(南东)迁移的同时,逐渐向中部贡玛—达曲断裂带和南部鲜水河断裂带的东南段集中。地震活动的断裂构造联系主要表现为挤压剪切转换机制和典型的楔顶效应。研究区165个GPS速度矢量展现了与3个地块和以鲜水河断裂带为主的速度域、速度梯度带和速度扰动区。跨研究区南缘鲜水河断裂带的位移速率因贡玛—达曲断裂带汇聚而达到了6.5～8.6mm/a,而跨北缘东昆仑断裂带的位移速度只有1.8～2.2mm/a。因鲜水河断裂走向在其中南段发生向南的急剧偏转,垂直断层面的位移矢量分量不断增强,形成了汶川8.0级地震成核及NE向单边破裂的动力学条件。     

An attempt to detect temporal variations of crustal structure in the source area of the 2006 Wen-An earthquake in North China

Lei et al. (2008) revealed a low-velocity (low-V) anomaly in the lower crust under the source area of the 4 July 2006 Wen-An earthquake (M 5.1) in North China. In this work we tried to investigate the temporal variations of the crustal structure by using a number of P and PmP (Moho reflected) wave arrival times recorded by 107 digital seismic stations from earthquakes that occurred separately in 2002, 2003, 2004, and 2005–2006 to determine P-wave velocity structures in and around the source area of the Wen-An earthquake in different periods. Our results show that tomographic images inferred from the data sets in different years are all dominated by a low-V anomaly in the lower crust under the Wen-An source area. However, there exist some differences in the P-wave velocity image in the Wen-An source area inferred from the P and P + PmP data sets, suggesting that the PmP data have improved the tomographic images in the middle and lower crust, but the results from the 2005–2006 P and P + PmP data sets all show a relatively lager increase of the low-V anomaly under the Wen-An source area in the amplitude and extent as compared with those from the 2003 and 2004 P and P + PmP data sets. Incorporating the previous results, if this low-V anomaly may indicate the existence of fluids, then our results suggest that the occurrence of the Wen-An earthquake is not only related to the long-term influence of fluids that decrease the effective normal stress on the fault plane, but also closely associated with the drastic increase of such influence. However, this study is just an experimental work and the results are still preliminary because the resolution scale of the present tomographic model is much larger than the Wen-An source area and our extensive tests show that different samplings of seismic rays from different data sets have affected the details of the tomographic images, suggesting that the present sparse data coverage can hardly detect reliably any temporal variations of the velocity anomalies in the Wen-An source area. In future studies it is necessary to improve the resolution of crustal tomography to the size of the rupture zone and utilize identical seismic ray paths from the same pairs of sources and receivers in order to detect any temporal variations of the crust structure in the source area of a large earthquake.