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1.
基于连续GPS数据,利用滑动块体模型研究了日本MW9.0地震前后沂沭断裂带两侧块体连续的相对运动状态,并研究其对区域地震活动的影响,结果表明日本地震以来:1)两侧块体呈右旋走滑兼挤压状态,平均走滑、挤压速率分别为0.9±0.1 mm·a-1和-0.7±0.1 mm·a-1,相比日本地震之前,运动过程更具起伏特征,可能与日本地震前后俯冲带两侧板块间相互运动状态的改变有关;2)沂沭断裂带两侧地区地震活动频次N、总释放能量折算震级M、地震活动度S值、地震b值与两侧块体相对运动的相关系数分别为0.66、0.69、0.74、-0.6,T检验显示相关性显著.在研究区地震能量集中释放阶段两侧块体相对运动方向和研究区主压应力方向一致,相对运动速率和地震活动强度变化具有同步特征,两侧块体相对运动对区域地震活动具有控制作用;3)莱州序列和乳山震群的发生可能与两侧块体相对运动促进的局部区域应力调整有关. 相似文献
2.
设定两个不同研究区域,分别就汶川8.0级地震前地震活动特征进行研究,得出以下结论:①至少在2008年5月11日之前的38年时间中,龙门山断裂带中段出现M5.0以上地震空段,汶川巨大地震就发生在这一空段;②第一研究区域强震释放能量出现阶段性梯次减少现象;③至2008年初,估算出第一研究区域地应力积累量已达5.0136×1016J,相当于一次M7.9强震所能释放的能量;④第二研究区域中小地震在龙门山断裂带中段的南端形成了几乎垂直相交的两条地震带,小震活动明显增多. 相似文献
3.
2011年日本MW9.0地震(简称日本地震)后沂沭断裂带及其两侧地区地震活动显著增强,研究日本地震对该地区地壳运动及地震潜势的影响十分必要.为此,本文通过112个连续GPS观测站获取了研究区高空间分辨率的日本地震同震形变场并得到如下认识:(1)8个定点地球物理观测的同震响应验证了本文同震形变场的可靠性;日本地震的东向拉张使研究区整体上处于张性同震应变状态,但存在局部挤压区域,其中莱州湾至海州湾的挤压条带穿过沂沭断裂带并对断裂带南北两段产生了不同的同震作用,对南段具有拉张作用,对北段产生挤压作用;(2)同震形变场在鲁东隆起和鲁西断块产生了显著的剪应变,地震b值显示上述区域的构造应力在日本地震后增强,因此同震形变场可能改变了这些区域的应力特征;(3)地震矩张量叠加分析显示,同震形变场短期内对鲁西断块、鲁东隆起区和沂沭断裂带南段累积了地震矩,可能有助于上述区域在日本地震以后的地震活动增强;日本地震对沂沭断裂带北段的地震矩具有释放作用,或许是该区域地震活动减弱的原因. 相似文献
4.
利用玉树震区21个应急流动地震台站和青海省地震台网固定地震台站的观测数据,采用双差层析成像方法,对2010年4月14日至6月15期间发生的地震进行了重定位,并反演得到了玉树地震震源区的三维速度结构.重定位结果揭示余震主要沿NW向成窄带状分布在断层的两侧,表明脆性破裂应力释放主要集中于一个狭窄的区域内.在西北端,余震偏离玉树—甘孜断裂分布,在SW向也有分布,推测可能与南西向次级断裂有关.双差层析成像得到的速度结构在浅部与地表地质构造相一致,中上地壳的速度结构显示巴颜喀拉地块为高速异常,羌塘地块为低速异常.玉树地震余震分布与特定的速度结构存在相关性:主震发生在高低速过渡带偏高速体的一侧,余震主要分布在高速体外围,高速体内部几乎没有余震分布.一般说来,中上地壳的高速体通常具有较高的强度,可以积累较强的孕震能量.主震发生后,高速体内积累的弹性能量向周边释放,可能是导致高速体周边余震发生的主要原因. 相似文献
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利用山东及邻区数字地震台网2001- 2012 年的地震观测报告及波形资料分析了沂沭断裂带及周缘地区的地震活动并利用识别出的重复地震估算了断层深部滑动速率。重新定位后的地震图像清晰展示了沂沭断裂带南北两段及东西两侧地震活动的显著差异,在研究时段内,60%以上的地震发生在沂沭带东侧的两条断裂上,震源深度分布与研究区的深部构造吻合。根据波形意义上相似地震(cc≥0.8)的定义,识别出了沂沭断裂带及其周缘相似地震共50例,组成相似地震对和多重相似地震对共19组,相似地震对的复发间隔较为随机,从数小时到数百天不等。通过对相似地震对震源位置- -致性的强约束后,基于1组重复地震估算出安丘-莒县断裂在地表以下5.9km处的滑动速率估计值为2.19mm/a,与GPS和地质等浅表观测的滑动速率值基本一致。 相似文献
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2018年1月15日佳木斯汤原县发生ML 4.4地震,采用ISOLA方法反演矩张量解,结果显示为逆冲型地震,兼少量走滑成分。结合震源区地质构造背景,推断依舒断裂北段通河-汤原段西支断裂为发震构造,主压应力轴与背景应力场方向不一致。分析认为,黑龙江亚板块由东南转向东北运动,造成断层两侧应力产生差异,区域应力场调整诱发汤原ML 4.4地震。 相似文献
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On March 11, 2011, a MW9.0 earthquake occurred in the Japan Trench, causing tremendous casualties, and attracting extensive concern. Based on the results of related research, this paper analyzes the observations, phenomena and understandings of the earthquake from varied aspects, and obtains four main conclusions. (1) The earthquake, occurring in the subduction zone in the Japan Trench located in the northwest boundary of the pacific plate has two zones of concentrated coseismic slip at different depths, and the slip in the deep zone is relatively small. Though there have been many M7.0 historical earthquakes, slips in the shallow zone are large, but there have been few historical strong earthquakes. (2) Constrained by GPS data, the study of fault movement shows that fault movement in the Japan Trench has a background of widely distributed stability and locking (the locking zone is equivalent that of coseismic rupture zone). Perturbation occurred after the 2008 M8.0 Hokkaido earthquake, several M7.0 events had after slips larger than the coseismic slip, and two obvious slow slip events were recorded in 2008 and 2011. Eventually, the March 9, 2011 M7.0 foreshock and the March 11, 2011 MW9.0 mainshock occurred. The pre-earthquake changing of the fault movement in the Japan Trench is quite clear. (3) Traditional precursory observation show no obvious anomaly, possibly due to monitoring reason. Anomaly before earthquake consists of high stress state in focal zone reflected by some seismic activity parameters, short period anomaly in regional ground motion, etc. (4) The analysis of physical property in focal zone aroused more scientific issues, for example, is there obvious difference between physical property in focal zone and its vicinity? Does frictional property of fault determine seismogenic ability and rupture process? Whether pre-earthquake fault movement include pre-slips? Could deep fluid affect fault movement in focal zone? Experience is the best teacher, and authors hope this paper could be a modest spur to induce others in basic research in earthquake forecast and prediction. 相似文献
8.
STUDY ON SOURCE PARAMETERS OF THE 8 AUGUST 2017 M7.0 JIUZHAIGOU EARTHQUAKE AND ITS AFTERSHOCKS,NORTHERN SICHUAN 
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下载免费PDF全文 WU Wei-wei WEI Ya-ling LONG Feng LIANG Ming-jian CHEN Xue-fen SUN Wei ZHAO Jing 《地震地质》1979,42(2):492-512
On August 8, 2017, a strong earthquake of M7.0 occurred in Jiuzhaigou County, Aba Prefecture, northern Sichuan. The earthquake occurred on a branch fault at the southern end of the eastern section of the East Kunlun fault zone. In the northwest of the aftershock area is the Maqu-Maqin seismic gap, which is in a locking state under high stress. Destructive earthquakes are frequent along the southeast direction of the aftershocks area. In Songpan-Pingwu area, only 50~80km away from the Jiuzhaigou earthquake, two M7.2 earthquakes and one M6.7 earthquake occurred from August 16 to 23, 1976. Therefore, the Jiuzhaigou earthquake was an earthquake that occurred at the transition part between the historical earthquake fracture gap and the neotectonic active area. Compared with other M7.0 earthquakes, there are few moderate-strong aftershocks following this Jiuzhaigou earthquake, and the maximum magnitude of aftershocks is much smaller than the main shock. There is no surface rupture zone discovered corresponding to the M7.0 earthquake. In order to understand the feature of source structure and the tectonic environment of the source region, we calculate the parameters of the initial earthquake catalogue by Loc3D based on the digital waveform data recorded by Sichuan seismic network and seismic phase data collected by the China Earthquake Networks Center. Smaller events in the sequence are relocated using double-difference algorithm; source mechanism solutions and centroid depths of 29 earthquakes with ML≥3.4 are obtained by CAP method. Moreover, the source spectrum of 186 earthquakes with 2.0≤ML≤5.5 is restored and the spatial distribution of source stress drop along faults is obtained. According to the relocations and focal mechanism results, the Jiuzhaigou M7.0 earthquake is a high-angle left-lateral strike-slip event. The earthquake sequence mainly extends along the NW-SE direction, with the dominant focal depth of 4~18km. There are few shallow earthquakes and few earthquakes with depth greater than 20km. The relocation results show that the distribution of aftershocks is bounded by the M7.0 main shock, which shows obvious segmental characteristics in space, and the aftershock area is divided into NW segment and SE segment. The NW segment is about 16km long and 12km wide, with scattered and less earthquakes, the dominant focal depth is 4~12km, the source stress drop is large, and the type of focal mechanism is complicated. The SE segment is about 20km long and 8km wide, with concentrated earthquakes, the dominant depth is 4~12km, most moderate-strong earthquakes occurred in the depth between 11~14km. Aftershock activity extends eastward from the start point of the M7.0 main earthquake. The middle-late-stage aftershocks are released intensively on this segment, most of them are strike-slip earthquakes. The stress drop of the aftershock sequence gradually decreases with time. Principal stress axis distribution also shows segmentation characteristics. On the NW segment, the dominant azimuth of P axis is about 91.39°, the average elevation angle is about 20.80°, the dominant azimuth of T axis is NE-SW, and the average elevation angle is about 58.44°. On the SE segment, the dominant azimuth of P axis is about 103.66°, the average elevation angle is about 19.03°, the dominant azimuth of T axis is NNE-SSW, and the average elevation angle is about 15.44°. According to the fault profile inferred from the focal mechanism solution, the main controlling structure in the source area is in NW-SE direction, which may be a concealed fault or the north extension of Huya Fault. The northwest end of the fault is limited to the horsetail structure at the east end of the East Kunlun Fault, and the SE extension requires clear seismic geological evidence. The dip angle of the NW segment of the seismogenic fault is about 65°, which may be a reverse fault striking NNW and dipping NE. According to the basic characteristics of inverse fault ruptures, the rupture often extends short along the strike, the rupture length is often disproportionate to the magnitude of the earthquake, and it is not easy to form a rupture zone on the surface. The dip angle of the SE segment of the seismogenic fault is about 82°, which may be a strike-slip fault that strikes NW and dips SW. The fault plane solution shows significant change on the north and south sides of the main earthquake, and turns gradually from compressional thrust to strike-slip movement, with a certain degree of rotation. 相似文献
9.
2008年汶川MS8.0地震前地震活动异常特征 总被引:1,自引:1,他引:0
分析了汶川地震前地震活动时空演化特征.结果表明:①汶川地震前38a龙门山断裂带及其附近形成5级地震背景空区,震前6.5a形成ML4.0地震孕震空区,震前1a孕震空区内部及其两端相继发生多次ML4.0—5.0地震,空区缩小;②中国大陆西部及邻区2001年以来处于大震活跃时段,而中国大陆内部地震活动水平非常低,出现非常显著的7级、6级和5级地震平静;③南北地震带7级以上地震在时间上具有准周期特征,空间上存在由南向北迁移的特点,汶川地震的发生符合这一规律;④1998年以来南北地震带中段为7级地震空段,汶川地震就发生该空段内;⑤2003年云南大姚地震后,南北地震带地震活动显著增强,且在中、南段形成4.6级以上地震环形分布,四川及其附近表现为异常平静,同时震群活动显著,且在4.6级地震平静区内形成震群空区,汶川地震就发生震群空区的边缘,震前8个月,震群频度出现高值异常;⑥汶川地震前7个月,青藏块体大范围ML≥4.0地震平静103d,2008年1月13日以后平静区逐渐解体,至汶川地震前4级地震平静区缩小到巴颜喀拉地块,汶川地震就发生在巴颜喀拉地块的东边界带上,汶川地震前3 个多月,孕震空区内部出现NW走向的3级地震条带,与龙门山断裂带斜交. 相似文献
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马亮 《地震地磁观测与研究》2017,38(5):1-7
2016年青海门源M_S 6.4地震具有显著特征,如:余震强度低、能量释放水平低、震害较轻等。震区地震构造表现出一定规律性,如:冷龙岭断裂呈周期性破裂,发震断裂含多支相互斜交的分支断裂等。虽然地震前小震活动未能提供有价值的预测信息,但震中落入2015年甘肃省年度危险区。本文对此次地震的震源机制解、地震序列衰减、震害特点及冷龙岭断裂带构造进行分析,给出地震序列属性、发震断层及错动动力源,提出地震并未发生在冷龙岭主断裂的证据,从而为震区及邻区地震活动状态与孕震机制判定提供参考,并为后续震情判定提供震例与数据。 相似文献
11.
On October 27, 2001, a large earthquake with Ms6.0, named the Yongsheng earthquake, occurred along the Jinshajiang segment of Chenghai fault in Yongsheng County, Yuunan Province. It is the largest event to occur along the Chenghai fault in the last 200 years. The seismo-geological survey shows that the seismogenic fault, which is the Jinshajiang segment of Chenghal fault, takes left-lateral strike-slip as its dominant movement pattern. According to differences in vertical motion, motion time, landforms and scales, the Chenhai fault can be divided into eight segments. The Jinshajiang segment has a vertical dislocation rate of 0.4mm/a, far lower than the mean rate of the Chenghai fault, about 2.0 mm/a. It‘ s deduced that the two sides of Jinshajiang segment “stuck“ tightly and hindered the strike-slip of the Chenghai fault. The strong earthquake distribution before this event shows that the Jinshajiang segment was in the seismic gap. The Chenghai fault, as a boundary of tectonic sub-blocks, makes the Northwest Yunnan block and the Middle Yunnan block move clockwise, and their margins move oppositely along the Chenghai fault. In the motion process of the Chenghai fault, structural hindrance and the seismic gap of strong earthquakes are propitious to the concentration and accumulation of structure stress. As a result, the Yongsheng Ms6.0 earthquake occurred. The Sujiazhuang-Shangangfu segment is similar to the Jinshajiang segment with a low vertical motion rate of 0.3 mm/a and in the seismic gap. So it‘s postulated that the segment may become a new structure hindrance, and the Yongsheng Ms6.0 earthquake may trigger the occurrence of future large earthquakes along this segment. 相似文献
12.
松潘-甘孜块体位于中国大陆西南部、南北地震带的中段,其东段与扬子块体相接,拥有多条活动断裂带,是青藏高原北部的主要构造单元.该地区地震活动性强烈,历史上曾发生过多次灾难性地震.本文基于地震触发原理和黏弹松弛分层地壳模型,计算了松潘-甘孜块体东北端历史强震之间应力传输和相互作用的过程.模型结果显示,受之前地震导致的库仑应力场变化的影响,1879年武都地震和1976年8月23日松潘M7.2级地震震中库仑应力积累提升,将促进这些地震提前发生;1933年M7.5叠溪地震和1973年M6.5松潘地震震中库仑应力降低,前续地震的影响可能使得这两次地震的发震时间推迟;在研究历史地震对1960年漳腊M6.7级地震、1976年8月16日M7.2级和1976年8月22日M6.7级松潘地震的作用时,有效摩擦系数的取值十分重要,当有效摩擦系数取0.8时,前续地震导致的应力场变化将促进以上三次地震的发生.松潘-甘孜块体东北端的强震活动有效地增强了西秦岭北缘断裂、东昆仑断裂玛沁-玛曲段、鲜水河断裂康定-道孚段和岷江断裂中段上的库仑应力积累,将提升这些断裂今后发生地震的概率;有效降低了龙日坝断裂上库仑应力的积累,降低了该断层上发生地震的概率.松潘-甘孜块体的地震活动降低了汶川地震震中位置的库仑破裂应力,但提升了破裂面东北段的应力积累,有助于汶川地震向东北端破裂. 相似文献
13.
基于鄂尔多斯块体的地质构造演变过程及历史强震活动规律,阐述南北地震带和龙门山断裂带强震时空分布规律对鄂尔多斯北缘的可能影响,对比分析鄂尔多斯其他3缘与北缘的地震活动.结果表明,青藏块体强震对鄂尔多斯北缘中强地震具有一定的触发作用;南北地震带中强以上地震的空间迁移特征表明,鄂尔多斯北缘将是未来中强以上地震的有利发震区域.2005年以来中小地震活动特征表明,鄂尔多斯北缘兼有Ms≥4.0地震平静和西北缘ML≥3.0地震活跃两种异常特征.综合地震地质背景和近期地震活动研究结果分析认为,今后一段时间鄂尔多斯北缘有可能发生中强以上地震. 相似文献
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15.
地震构造是地震孕育和发生的载体,也是地震危险性预测的基础.中国大陆地震构造具有鲜明的分区特征.不同地区的地震活动都有其自身的强弱变化,很难用统一的活动期或平静期来涵盖.地震活动强度与各个区域的断裂活动水平有较好的一致性.如东、西部断裂活动水平相差约一个数量级,大震发生的频度也相差一个数量级.地震不但与活断层有关,而且与地震构造块体的关系也相当密切.前兆异常和地震不是因果关系,是伴生或孪生的关系,它们都是构造活动的产物.本文从中国大陆地震构造环境出发,研究了典型地震构造块体和主要地震断裂带与地震危险性的关系.结果表明:中国大陆未来十年或更长一段时间大震活动的地区主要在西部.重点应该注意塔里木块体沿南北两侧边缘断裂带由西向东发展的趋势.在川滇地区应重点关注鲜水河-安宁河-小江断裂带及毗邻地区.东部可能会有多次中强地震发生,发震地点可能与渤海-张家口-河套地震断裂带和郯庐地震断裂带有关. 相似文献
16.
在整理垂直摆地震响应的基础上,采用USGS提供的有限断层模型和速度结构模型,运用德国地学研究中心(GFZ)王荣江研究员开发的(PSGRN/PSCMP)计算程序,分析日本MW 9.0地震和中俄交界MS 6.6地震倾斜场变化,并与垂直摆记录数据进行对比。通过整理现有地质资料和断层数据,模拟依舒断裂带北段鹤岗周边发生MS 6.0地震时,该地区同震及震后倾斜场的变化,以了解不同震源性质的地震产生的地倾斜变化及对鹤岗地区产生的影响。 相似文献
17.
南北地震带北段近期强震趋势研究 总被引:2,自引:1,他引:1
2008年5月12日汶川8.0级地震后,南北地震带可能进入新一轮的强震活跃期.从汶川8.0级地震以来ML≥5.0地震活动空间分布特征来看,近期南北地震带北段与中、南段存在较大差异.由南北地震带强震前孕震区中强地震活动特征,并结合当前5级地震活动情况,认为应同时关注南北地震带中、南段和北段的强震危险性.甘东南地区出现的4级地震空区被2011年2月23日迭部-岷县交界ML4.4地震打破后,2011年11月1日空区周边又发生了青川Ms5.4地震,表明该空区及周边地区的地震活动增强.类比1990年共和7.0级地震前的空区演化过程,认为甘东南地区存在发生7级地震的可能.结合对甘东南地区主要大型断裂7级地震复发周期的综合分析认为,需关注南北带北段毛毛山断裂和金强河断裂、香山-天景山断裂东段、黄河断裂灵武段、西秦岭北缘断裂、六盘山-宝鸡断裂和东昆仑断裂东段玛沁-玛曲段发生7级地震的可能. 相似文献
18.
沂沭断裂带重力场及地壳结构特征 总被引:5,自引:2,他引:3
沂沭断裂带为郯庐断裂带山东段,新构造运动显著,是华北地区的强震活动带之一。文中收集了该地区的布格重力数据,利用小波多尺度分析方法对重力场进行有效分离,研究区域地壳结构特征及断裂空间展布,并应用Parker变密度模型对区域莫霍面进行反演分析,得到以下几点结论:1)重力区域场显示,沂沭断裂带形成了NNE走向的大型重力梯度带,分隔了鲁西、鲁东地块,成为区域内重要的地球物理分界线。2)重力局部场显示,中上地壳结构复杂,沂沭带内部呈现两堑一垒的重力异常格局,5条主干断裂形成线性梯度带分布于东、西地堑内,鲁西块体的多条NW向活动断裂交切于沂沭断裂带,多数断裂只交切于西地堑,而蒙山山前断裂和苍尼断裂横穿沂沭断裂带;下地壳结构相对简单,发生明显的褶曲构造,表现出大规模高、低密度异常相间排列的典型特征。3)区域莫霍面形态东高西低,沂沭断裂带形成了莫霍面陡变带,造成了东西分异格局,潍坊东—莒县—临沂一线出现莫霍面上隆区,具有强震发生的深部孕震环境。4)区域内地震多发于高、低重力异常转化带之间,特别是活动断裂对应的重力梯度条带之上,地震的发生与断裂活动有着密切的关系,沂沭断裂带地震活动性最强,且东地堑强于西地堑。 相似文献
19.
Abstract Bathymetric data from south of Hokkaido obtained during a cruise of R/V Hakuho-Maru are summarized, and their correlation with earthquake occurrence is discussed. There are structural lineations on the seaward slope of the Kuril Trench, oblique to the Kuril Trench axis and parallel to the magnetic lineations in the Pacific plate. The structural lineations comprise horst-grabens generated by normal faulting. This suggests that Cretaceous tectonic structures originating at the spreading centre affect present seismotectonics around the trench axis. The structural-magnetic relation is compared to the case of the Japan Trench. North-east of the surveyed area, there are two major fracture zones (Nosappu Fracture Zone and Iturup Fracture Zone) that divide the oceanic plate into three segments. If the fracture zones (FZ) and the zone of paleo-mechanical weakness, represented by magnetic lineations, can control the direction of normal faults at a trench, the extent of the resulting topographic roughness on the seaward slope of the trench would be different across an FZ because of the differences in ages. By studying recent large earthquakes occurring in the south Kuril region, it is shown that several main-aftershock distributions for large earthquakes in this region are bounded by the Nosappu FZ and the Iturup FZ. Two models (Barrier model and Rebound model) are presented to interpret earthquake occurrence near the south Kuril Islands. The Barrier model explains seismic boundaries seen in several examples for earthquake occurrence in the south Kuril regions. The fracture zone forming the boundary of two segments with different magnetic lineations is also the boundary of two different normal fault systems on their ocean bottom, and the difference in sea-bottom roughness between two normal fault systems should affect the seismic coupling at a plate interface. Due to the difference of seismic coupling, earthquake occurrence is controlled by an FZ and then the FZ acts as a seismic boundary (Barrier model). Existing normal faults created by plate bending of subducting oceanic plate should rebound after its subduction (Rebound model). This rebound of normal faults may cause intraplate earthquakes with a high-angle reverse-fault mechanism such as the 1994 Shikotan Earthquake. The energy released by an intraplate earthquake generated by normal-fault rebounding is not directly related to that of interplate earthquakes such as low-angle thrust earthquakes. It is a reason why large earthquakes occurred in the same region during a relatively short period. 相似文献
20.
The characteristics of spatio-temporal seismicity evolution before the Wenchuan earthquake are studied. The results mainly involve in the trend abnormal features and its relation to the Wenchuan earthquake. The western Chinese mainland and its adjacent area has been in the seismically active period since 2001, while the seismic activity shows the obvious quiescence of M≥?7.0, M≥?6.0 and M?≥5.0 earthquakes in Chinese mainland. A quiescence area with M?≥7.0 has been formed in the middle of the North-South seismic zone since 1988, and the Wenchuan earthquake occurred just within this area. There are a background seismicity gap of M?≥5.0 earthquakes and a seismogenic gap of ML?≥4.0 earthquakes in the area of Longmenshan fault zone and its vicinity prior to the Wenchuan earthquake. The seismic activity obviously strengthened and a doughnut-shape pattern of M?≥4.6 earthquakes is formed in the middle and southern part of the North-South seismic zone after the 2003 Dayao, Yunnan, earthquake. Sichuan and its vicinity in the middle of the doughnut-shape pattern show abnormal quiescence. At the same time, the seismicity of earthquake swarms is significant and shows heterogeneity in the temporal and spatial process. A swarm gap appears in the M4.6 seismically quiet area, and the Wenchuan earthquake occurred just on the margin of the gap. In addition, in the short term before the Wenchuan earthquake, the quiescence of earthquake with ML≥?4.0 appears in Qinghai-Tibet block and a seismic belt of ML?≥3.0 earthquakes, with NW striking and oblique with Longmenshan fault zone, is formed. 相似文献