A preliminary report of the Yangbi, Yunnan, M_(S)6.4 earthquake of May 21, 2021

According to the reports of China Earthquake Networks Center,an Ms6.4 earthquake occurred in Yangbi City,Dali Prefecture,Yun-nan Province,on May 21,2021;the epicenter was located at 25.67°N and 99.87°E with a focal depth of 8 km.Within 5 km from the epicenter the average elevation is 2268 m.

Temporal evolution of the focal mechanism consistency of the 2021 Yangbi M_(S) 6.4 earthquake sequence in Yunnan

Using the Cut And Paste(CAP)method,we invert the focal mechanism of 38 moderate earthquakes(M_(S)≥3.0)recorded by Yunnan seismic network and analyze the corresponding focal mechanism consistency based on the minimum spatial rotation angle.Our results indicate that the M_(S)6.4 mainshock is induced by a lateral strike slip fault(with a rake angle of~-165°)and a little normal-faulting component event along a nearly vertical plane(dipping angle~79° and strike~138°).Combining our results with high resolution catalog,we argue that the seismogenic fault of this earthquake sequence is a secondary fault western to the major Weixi-Qiaohou-Weishan fault.The focal mechanism evolution can be divided into three periods.During the first period,the foreshock sequence,the focal mechanism consistency is the highest(KA<36°);during the second period which is shortly after the mainshock,the focal mechanism shows strong variation with KA ranging from 8° to 110°;during the third period,the seismicity becomes weak and the focal mechanism of the earthquakes becomes more consistent than the second period(18°<KA<73°).We suggest that the KA,to some extent,represents the coherence between local tectonic stress regime and the stress state of each individual earthquake.Furthermore,high focal mechanism consistency and high linearity of seismic distribution may serve as indicators for the identification of foreshock sequence.

Apparent stress as an indicator of stress meta-instability:The 2021 M_(S)6.4 Yangbi earthquake in Yunnan,China

Investigating spatiotemporal changes in crustal stress associated with major earthquakes has implications for understanding seismogenic processes.However,in individual earthquake cases,the characteristics of the stress after it reaches its maximum value are rarely discussed.In this study,we use the 2021 M_S6.4 Yangbi earthquake in Yunnan,China and events of magnitudes M_L≥3.0 occurred in the surrounding area in the previous 11 years to investigate the spatiotemporal evolution of apparent stress.The results indicate that apparent stress began to increase in January 2015 and reached a maximum in January 2020.Apparent stress then remained at a high level until October 2020,after which it declined considerable.We suggest that the stress was in the accumulation stage from January 2015 to January 2020,and entered the meta-instability stage after October 2020.During the meta-instability stage,the zone of decreasing stress expanded continuously and the apparent stress increased around the Yangbi earthquake source region.These features are generally consistent with the results of laboratory rock stress experiments.We propose that apparent stress can be a good indicator for determining whether the stress at a specific location has entered the meta-instability stage and may become the epicenter of an impending strong earthquake.

Spatiotemporal evolution of the 2021 M_(S)6.4 Yangbi earthquake sequence

Based on the seismic phase reports of the Yangbi area from January 1 to June 25,2021,and the waveform data of M≥4 earthquakes,we obtained the relocation results and focal mechanism solutions of the M_(S)6.4 Yangbi earthquake sequence using the HypoDD and CAP methods.Based on our results,our main conclusions are as follows:(1)the M_(S)6.4 Yangbi earthquake sequence is a typical foreshock-mainshock-aftershock sequence.The fore-shocks of the first two stages have the obvious fronts of migration and their migration rate increased gradually.There was no apparent front of migration during the third stage,and the occurrence of the mainshock was related to stress triggering from a M5.3 foreshock.We tentatively speculate that the rupture pattern of the Yangbi earthquake sequence conforms to the cascading-rupture model;and(2)the main fault of the M_(S)6.4 Yangbi earthquake sequence is a NW-trending right-lateral strike-slip fault.As time progressed,a minor conjugate aftershock belt formed at the northwest end of this fault,and a dendritic branching structure emerged in the southern fault segment,showing a complex seismogenic fault structure.We suggested that the fault of the Yangbi earthquake sequence may be a young sub-fault of the Weixi-Weishan fault.

Performance of the Yangbi M_(S)6.4 earthquake disaster in different geomorphic units in Yunnan

An M_(S)6.4 earthquake occurred in Yangbi,Yunnan province,on May 21,2021.According to related investigations,the macro-epicenter of the earthquake is 6 km northwest of Yangbi County,and the seismogenic structure is the NW-trending Weixi-Qiaohou fault.The earthquake area is located in the hinterland of the Hengduan Mountains in the northwest of Yunnan Province,a region dominated by high and medium-high mountains,with deep canyons and tectonic basins in between.Various geomorphic features are derived from drastic topographic changes and huge geological differences in the earthquake area.There are a variety of buildings in the earthquake-affected zone,including civil and brick-wood structures ones with weak seismic performance,as well as brick-concrete and frame ones with better seismic performance.This paper summarizes and analyzes different characteristics of the earthquake in different geomorphic units through field investigations of different buildings and geological disasters in the affected area.The results show that under the same earthquake intensity,the damage to most buildings(located in slope areas or rooted in weak strata)is amplified by the earthquake.The earthquake has exerted an obvious propagation effect along the direction of the seismogenic structure.Moreover,local ground fissures will aggravate the damage to the buildings even without surface dislocation.Thus,we suggest that attention should be paid to the ground fissures caused by the slope effect.The fissure areas may also be the disaster spot of collapses and landslides in case of a high-magnitude earthquake.

Seismogenic environment and mechanism of the Yangbi M_(S)6.4 earthquake in Yunnan,China

The Yangbi M_(S)6.4 earthquake occurred on May 21,2021 in western Yunnan,China,where moderate earthquakes strike frequently.It exhibited a typical“foreshock-mainshock-aftershock”sequence and did not occur on a pre-existing active fault.The seismogenic environment and mechanism of this earthquake have aroused considerable research attention.In this study,we obtain the three-dimensional v_(P),v_(S)and v_(P)/v_(S)images using the v_(P)/v_(S)consistency-constrained double-difference tomography method,which improves the accuracy of v_(P)/v_(S)models.We focus on characteristics of v_(P)/v_(S)images in areas with a lateral resolution of 0.1°,and reveal the seismogenic environment of the Yangbi M_(S)6.4 earthquake.The conclusions are as follows:(1)Low velocity and high-v_(P)/v_(S)anomalies are revealed at different depths around the northern segment of the Red River fault.v_(S)and v_(P)/v_(S)images along the Weixi-Qiaohou-Weishan fault and the buried faults on its west show obviously segmented feature.(2)The source region of the Yangbi M_(S)6.4 earthquake is located in a low-v_(P)/v_(S)zone implying high medium strength.High-v_(P)/v_(S)anomalies in its NW direction indicate cracks development and the existence of fluids or partial melts,which are unfavorable for stress accumulation and triggering large earthquakes.Such conditions have also prevented the earthquake sequence from extending northwestward.(3)With the southeastward extrusion of materials from the Tibetan Plateau,fluid migration was blocked by the low-v_(P)/v_(S)body in the source region.The high-v_(P)/v_(S)anomaly beneath the source region may implies that the fluids or partial melts in the middle and lower crust gradually weakened medium strength at the bottom of the seismogenic layer,and preparing the largest foreshock in the transition zone of high to low v_(P)/v_(S).Meanwhile,tectonic stress incessantly accumulated in the brittle upper crust,eventually led to the M_(S)6.4 earthquake occurrence.

InSAR观测与小震分布联合分析2021年云南漾濞M_(S)6.4地震应力卸载对周围区域的影响

为分析2021年5月21日云南省漾濞M_(S)6.4地震后震区应力变化对周围断层的影响,本文通过InSAR技术获得了漾濞地震的同震形变场,并联合小震分布数据建立断层破裂滑动模型,继而通过计算断层面上的同震库仑应力来评估此次地震对周边断层的影响,以便有效地分析地震破裂的时空解析度.结果显示:(1)在升降轨InSAR数据获得的精细同震形变场中,升轨最大视线向形变量约为5.00 cm,降轨最大视线向形变量约为7.80 cm;(2)余震精定位的主震震中为(99.89°E,25.67°N),震源深度为13.29 km,除主震之外震源深度主要集中在5—15 km;通过小震位置拟合出的发震断层走向为NW-SE(316.69°),断层倾角为88.56°,滑动角为177.97°;(3)基于InSAR同震形变场结果及小震拟合断层参数联合反演得到此次地震的断层滑动以右旋走滑为主,升轨断层最大滑动量为0.80 m,对应的深度为8.85 km,平均滑动量为0.22 m,矩震级为M_(W)6.41;降轨的断层最大滑动量为0.30m,对应的深度为6.88 km,平均滑动量为0.05 m,矩震级为M_(W)6.01;7.50 km和15 km深度处断层面上的应力计算结果表明,震后断层与其周围的应力差明显减小,对周围断裂具有显著的应力卸载作用.结合余震分布区域、模拟断层迹线以及同震库仑应力逐渐减小的方向,基本可以确定漾濞地震的发震断层为维西—乔后—巍山断裂的隐伏次生断裂.该地震通过卸载周围断裂的应力释放区域应力,降低了周围断裂的地震危险性.

Coseismic surface rupture characteristics and earthquake damage analysis of the eastern end of the 2021 M_(S)7.4 Madoi(Qinghai)earthquake

At 02:04 on May 22,2021,an M_(S)7.4 earthquake occurred in Madoi County in Qinghai Province,China.This earthquake is the largest seismic event in China since the 2008M_(S) 8.0 Wenchuan earthquake.Thus,it is critical to investigate surface deformation and damage in time to accurately understand the seismogenic structure of the Madoi earthquake and the seismogenic capacity of the blocks in this region.This study focuses on the Xuema Village,located at the eastern end of the coseismic surface ruptures produced by the event,and assesses the deformation and seismic damage in this area based on field surveys,UAV photogrammetry,and ground penetrating radar(GPR).The results indicate that the rupture scale is substantially smaller at the eastern end of the rupture zone compared to other segments.En echelon type shear tensile fractures are concentrated in a width range of 50–100 m,and the width of single fractures ranges from 20 to 30 cm.In contrast,the degree of seismic damage significantly increases at this site.All of the brick and timber houses are damaged or collapsed,while the steel frame structures and the color steel houses are slightly damaged.More than 80%of the bridge decks on the Changma River Bridge collapse,similar to the terraces along the Youerqu and Changma Rivers and the cut slopes of Provincial Highway S205.We infer that the seismogenic fault of the Madoi earthquake exerts a tail effect in this segment.The tension zone has led to a reduction at the eastern end of the rupture zone,causing shaking damage.Local topography and buildings without earthquake-resistant construction along the strike of the rupture zone have undergone different levels of seismic damage.

2021年5月21日M_(S)6.4漾濞地震GNSS同震变形场及其约束反演的破裂滑动分布

2021年5月21日云南大理州漾濞县发生了M_(S)6.4强震.地震未产生明显的地表破裂,但前震-主震-余震大致呈线状展布于维西—乔后—巍山断裂的西南侧.我们基于覆盖震中区域的高密度连续GNSS观测台阵,观测获得了震区周围50 km范围的高精度、高密度三维同震形变场.结果显示:地震破裂为明显的右旋走滑兼拉张;地表形变场呈现出走滑断裂前端压缩隆升、尾端拉张下沉的典型变形模式;GNSS观测到最大水平位移和垂直下沉分别达46 mm(漾濞县淮安村周围)和-44 mm(漾濞县秀岭林场周围);发震断裂的地表错动从漾濞淮安村GNSS观测站和秀岭林场GNSS观测站之间的狭小地带穿过.在此基础上,我们以前震和主震精定位结果为约束,推测发震断层面走向135°、倾向SW、倾角80°,进而通过弹性半空间断裂位错模型,对发震断层面的同震滑动分布进行了反演.初步反演结果表明:同震滑动主要集中分布在3~12 km深度范围内,矩震级为M_(W)6.04,滑动量分布与前震序列呈现较好的空间一致性.

2021年5月21日云南漾濞M_(S)6.4地震震区地壳结构特征与孕震背景

本文基于“中国地震科学台阵探测——南北地震带南段”密集布设的流动地震台阵和川滇区域数字测震台网等共计634个台站所记录的观测资料,先采用地震体波层析成像(TOMO3D)方法反演获得川滇区域的地壳速度结构特征,在此基础上,重点剖析云南漾濞M_(S)6.4地震震区及周边的三维P波速度结构;再采用三维视密度反演方法,获得漾濞震区壳内视密度的横向变化特征,最后综合分析漾濞M_(S)6.4地震震区地壳结构特征与地震活动关系、深部孕震背景等科学问题.研究结果表明:漾濞震区P波速度结构与视密度展布特征在深度和分区特征上均具有较好的联系和可比性,震区三维速度结构和视密度反演结果均表现出明显的横向不均匀分布特征,漾濞M_(S)6.4地震位于高低异常值的过渡带附近,震区南、北两侧速度结构和视密度分布特征各异,综合说明了震区地壳物质存在显著的横向差异.漾濞M_(S)6.4地震序列集中分布在主震的SE侧,并沿着NW-SE向呈条带状与维西—乔后断裂近似平行展布,长约20 km,主震震源深度为8.6 km,序列震源深度优势分布层位在5~15 km,漾濞M_(S)6.4地震序列处于高低速异常过渡带附近,震区壳内介质结构的非均匀分布是控制漾濞地震及其序列展布形态的深部构造因素.我们的研究结果还揭示了漾濞M_(S)6.4地震震区北侧洱源附近存在地壳尺度的低速、低密度异常这一最显著特征,该结果与该部位地表温泉较发育、大地热流值显著偏高等地热分布高度一致,这些均暗示着漾濞地震机制除了与青藏高原东缘深部物质SE向逃逸有关外,可能还与来自上地幔的热异常和深部过程密切相关.

2021年云南漾濞M_(S)6.4地震序列发震构造及其与2013年洱源、2017年漾濞地震的异同

2021年5月21日云南漾濞发生M_(S)6.4地震.为深入了解该地震的发震断层及发震构造特征,探讨其与2013年洱源与2017年漾濞地震发震构造及背景的异同,本文基于中国地震台网中心的观测报告,使用双差方法对漾濞地震序列进行重定位,并从全球矩心矩张量(GCMT)和美国地质调查局(USGS)搜集了9个震源机制解计算了震源区构造应力场,初步得到如下结论:(1)2021年漾濞地震序列呈NW-SE向展布且SE端余震数量多于NW端,余震区地壳应力不均匀释放,致使5.0级及以上地震周边余震稀少;4个5.0级及以上地震初始破裂深度大于矩心深度,推测发震断层是从断裂底部向浅部破裂.(2)发震断裂是维西—乔后—巍山断裂西南侧的未知断裂F2、F3,其走向NW-SE、倾向SW、倾角近垂直,具有右旋走滑特征.其中F2贯穿整个地震序列,长约30 km,F3主要发育在中南段,长约11 km,两条发震断层相交于地震丛集中间位置.(3)震源区构造应力场是走滑的应力机制,呈SSE向(174.57°)低倾伏角(18.79°)挤压,及SWW向(-93.65°)近水平(5.21°)拉张状态.震源区的发震构造受川滇块体与滇南块体形成的右旋走滑边界控制.(4)这3个地震均发生在川滇块体右旋走滑西南边界形成的走滑应力机制作用背景下.2013年洱源地震可能更多的受控于局部构造的垂向差异运动;2017年漾濞地震仅受到川滇块体西南边界的右旋走滑作用;2021年漾濞地震则主要受控于川滇块体西南边界的右旋走滑运动,还存在少量局部构造垂向差异运动作用.

2021年云南漾濞M_(S)6.4地震异常跟踪分析

对云南漾濞M_(S)6.4地震前出现的前震序列、地震学、定点形变和流体观测异常进行系统梳理和回顾,结果表明:前震序列较为复杂,能找到一些地震学的异常特征,但难以通过这些特征对震后趋势进行正确判断;定点形变观测异常出现时间早、异常幅度大,可为震级预测提供依据;流体观测异常出现时间短、异常相对集中,为时间预测提供了更好的支撑;形变和流体异常与亚失稳后期阶段具有较为相似的时空特征,可能与亚失稳过程有关。前震序列的判断结合区域地震危险性,可能是提高判断准确性更好的方法,合理利用地震孕育不同阶段的异常特征,是做好综合预测需要提倡的方法。

2021年云南漾濞M_(S)6.4地震预警处理结果分析

2021年5月21日云南漾濞发生M_(S)6.4地震,云南地震预警处理系统对观测数据进行了有效处理并产出预警信息。首先分析了观测记录的走时—震中距关系以及不同类型台站的信噪比,说明该系统震相拾取正确,确保了震中位置和发震时刻测定的高准确度;鉴于此次地震预警震级整体偏小,对比了不同类型台站的震级偏差,其中一般台震级偏差最小、测震台次之、基准台第三、基本台最大。云南地震预警处理系统在2021年5月接入基准台和基本台后,对于漾濞地震的震中位置和发震时刻测定的准确性和稳定性均有提高,震级偏差变化不明显,仍然整体偏小。这说明了云南地震预警处理系统台站布局合理,系统具备一定的预警能力,但震级算法还有待改进。

2021年5月21日云南漾濞M_(S)6.4地震序列的时空演化

"亚失稳"研究试验区滇西北短周期测震台网测得的2021年5月21日云南漾濞6.4级地震序列显示,主震发生前约3d内在破裂区北西段依次出现相邻区域的前震时空丛集;后续临震时段(主震前约1h)的前震从破裂区中心开始对称地向两端快速扩展,随后爆发主震。不同时段的前震空间分布显示了地震进入短临阶段后断层不同部位破裂的时空迁移及快速扩展,扩展速度由前震丛集过程的约5km/d提高至临震时段的约96km/d;主震震中位于前震丛集的边缘、最终破裂区的北西端,主震后余震向SE迁移,约0.5h后扩展至整个破裂带,最终破裂带长度> 20km,显示了本次地震的单向传播特征;该台网建立以来,漾濞地区的小地震活动显示本区域近3a时段内b值平稳(为0.9~1.1),6.4级主震前b值异常持续下降至0.6以下,反映了漾濞地震前存在显著的应力增加过程。

2021年云南漾濞M_(S)6.4地震序列重定位及发震构造探讨

利用云南地震台网提供的地震编目快报观测报告和地震事件波形数据,采用联合波形互相关分析的双差地震定位方法,对2021年5月21日云南漾濞M_(S)6.4地震前3天至震后2天期间发生的地震事件进行了重定位,并基于两种不同的区域速度模型,采用CAP方法反演了序列中3次M_(S)≥5.0地震的震源机制解和矩心深度。结果表明:双差重定位获得了漾濞地震序列中1012次地震的精确位置,水平和垂直方向的定位误差分别为1.1 km和3.0 km。3次M_(S)≥5.0地震的震源机制解和深度均有所不同,初步分析认为这可能是由断裂深浅部的结构、形态差异或地震破裂后震源区附近的应力调整或流体运移导致的断层成核破裂变化所致。综合地震重定位、震源机制解反演及区域活动构造资料,初步分析认为漾濞M_(S)6.4地震的发震破裂面走向约为140°,倾角约为80°,滑动角约为-160°,发震断层可能为维西—乔后断裂中段的一条或多条次级断裂,且具有右旋走滑特征。

云南洱源井水温在2021年漾濞M_(S)6.4地震前的异常特征

2021年5月21日21时48分(北京时间)云南省大理白族自治州漾濞县(99.87°E,25.67°N)发生M_(S)6.4地震。该地震发生后,我们对震中附近的地下流体观测资料进行了系统的总结,结果显示云南省地震台在2021年2月24日提出洱源井水温异常,该井水温在漾濞M_(S)6.4地震前呈现明显的异常现象。

2021年云南漾濞M_(S)6.4地震震源区断层系统的几何复杂性

地震精定位及震源机制反演能够提供发震构造信息,特别在地表无明显断层迹线的震源区,可有效揭示隐伏断裂的深部几何结构。文中采用双差定位方法对2021年5月18日—6月4日期间云南区域台网记录到的漾濞M_(S)6.4地震序列进行精定位,得到主震前4d和主震后14d共3233次地震事件的空间位置,并计算了漾濞震源区的b值;进一步利用云南和四川区域台网记录的波形数据,采用近震全波形反演方法得到了包括主震在内10个4.0级以上地震的全矩张量解,并反演得到震源区构造应力场。地震定位结果显示,前震序列和余震序列在时空分布上存在明显差异:前震主要在NW-SE方向呈条带状分布,且震中位置存在往返迁移现象;余震主要在NW和NE 2个方向分布,呈不对称共轭断层分布形态,在NW向地震带南端存在多组不同走向的余震分布,暗示震源区介质及断层几何结构的复杂性。b值随时间变化的结果显示,主震前b值已有上升趋势,表明震前震源区应力积累已开始逐步得到释放,可能和本次地震为前震-主震-余震的序列类型有关;而主震发生后b值的变化幅度较大,可能反映余震活动较为剧烈,应力释放变化较大。震源机制结果显示地震以走滑型为主,正断分量其次,并包含显著的非双力偶成分,可能表明震源区NW及NE向断裂交错分布,地震破裂并非简单地沿断层平面滑动。综合上述结果以及近SN向挤压、EW向拉张的应力场环境,我们认为漾濞M_(S)6.4地震序列的发震构造为位于宝山地块内部一条NW向的高倾角右旋走滑断裂,可能是与维西-乔后-巍山断裂平行的次级断裂,并且该断裂在南段包含多条NE向分支断裂。文中结果表明漾濞震源区断层系统几何结构的复杂性控制了地震序列时空分布范围及震源破裂的多样性。

2021年云南漾濞M_(S)6.4地震烈度与震害特征

基于应急阶段现场调查、强震动观测,结合震区地质构造、震源机制解、地震序列空间分布等,评定了2021年云南漾濞M_(S)6.4地震的烈度分布。通过对各类震害现象的系统收集和综合分析,归纳了本次地震震害的基本特征并对震害原因进行了初步分析。对照云南地区其他同等级别地震烈度与震害,总结了现场调查得到的初步认识。本次地震形成了呈不规则椭圆状的Ⅷ度、Ⅶ度和Ⅵ度3个等级的烈度区,且长轴均为NNW方向,与震中附近的维西—乔后断裂走向一致,也与强震动观测记录、地震序列空间分布及震源机制解相吻合。此次地震灾害与云南同等级别地震相比明显偏轻,其原因主要是主震前持续多日、不断升级的前震活动警示作用,以及各级党委政府采取了及时有效的动员和疏散避险措施;震区的土木结构房屋震害严重,应科学规划城乡建设布局,逐步减少土木结构房屋存量,提高综合防灾减灾能力;各级政府应高度重视、加大帮扶地震中房屋遭到严重破坏的山区农村居民,避免因灾返贫的情况发生。

2021年云南漾濞M_(S)6.4地震仪器地震烈度与宏观地震烈度对比分析

利用云南省强震动及地震预警台网获得的漾濞M_(S)6.4地震地震动记录数据,根据《中国地震烈度表》的仪器烈度计算方法,得到各台站的仪器地震烈度。对比分析了漾濞M_(S)6.4地震的仪器烈度图与宏观烈度图的异同,发现二者最高烈度相同、等震线长轴走向相似,但各烈度区面积与形状不相同;对比分析了仪器烈度与调查点的评估烈度的吻合性,发现二者完全吻合的比例为81.25%,偏差±1度的比例为93.75%,说明仪器地震烈度在一定程度上能客观反映实际的震害情况。

2021年云南漾濞M_(S)6.4地震序列特征及强余震判定

利用云南地震台网观测资料,对2021年漾濞M_(S)6.4地震序列的时空演化特征进行分析,结果表明:漾濞地震序列的空间展布可分为4段,且余震活动衰减非常迅速。通过分析历史地震序列类型、h值、等待时间法、累计频次曲线、初动方向等,判断漾濞M_(S)6.4地震序列为前震-主震-余震型。利用云南地区6级地震最大余震发震时间统计和震级差分布特征分析,认为漾濞M_(S)6.4地震最大余震已经发生。最后讨论了漾濞地震序列4级余震偏多的现象及可能的原因。