皎口水库地震精定位、震源机制及发震机理探讨

利用双差定位法对宁波皎口水库2009—2021年地震进行重新定位,通过HASH方法计算了较大地震的震源机制解,基于精确定位后的地震震源位置分布、深度分布以及总体震源机制解特征,结合区域地质构造背景、库区地质条件以及水库水位变化,对发震构造及孕震机理进行探讨。结果表明,皎口水库2009—2012年地震序列与2018—2021年地震序列孕震机理相似,区域性断裂长兴—奉化可能为发震断层;库水通过断裂破碎带下渗,孔隙水压力扩散及库水对岩石的软化弱化长时间作用,造成断层面及其深部某些薄弱部位变为不稳定区域,最后在库水变化导致的加卸荷应力场作用下触发地震。     

北天山地区部分中强震前小震震源深度变化特征

利用双差定位法修订后的新疆北天山地区地震目录, 以1990年以来该区发生的8次7组5级以上中强地震作为震例样本, 分析研究主震前震源附近区域小震震源深度的变化特征。 研究结果显示, 在研究时段内7组地震中6组地震前出现小震震源深度趋深变化的异常图像。 类似异常图像共出现9次, 异常对应率66.7％。 这种异常图像可为地震预测综合判定提供参考依据。     

影区地震的识别与定位

通过分析西安地震台近几年各个方向记录到的影区地震,详细阐述 Lg1、Lg2波的确认方法,运用 Matlab对数据进行分析,给出S波与 Lg1、Lg2波的走时关系式,提高影区地震的分析速度和准确度,为单台大震速报和日常分析提供借鉴经验。     

Source mechanism and source parameters of May 28, 1998 earthquake,Egypt

On May 28, 1998, a moderate size earthquake of mb 5.5 occurred offshore the northwestern part of Egypt (latitude 31.45°N and longitude 27.64°E). It was widely felt in the northern part of Egypt. Being the largest well-recorded event in the area for which seismic data from the global digital network are available, it provides an excellent opportunity to study the tectonic process and present day stress field occurring along the offshore Egyptian coast. The source parameters of this event are determined using three different techniques: modeling of surface wave spectral amplitudes, regional waveform inversion, and teleseismic body waveform inversion. The results show a high-angle reverse fault mechanism generally trending NNW–SSE. The P-axis trends ENE–WSW consistently with the prevailed compression stress along the southeastern Hellenic arc and southwestern part of the Cyprean arc. This unexpected mechanism is most probably related to a positive inversion of the NW trending offshore normal faults and confirms an extension of the back thrusting effects towards the African margin. The estimated focal depth ranges from 22 to 25 km, indicating a lower crustal origin earthquake owing to deep-seated tectonics. The source time function indicates a single source with rise time and total rupture duration of 2 and 5 s, respectively. The seismic moment (M _o) and the moment magnitude (M _w) determined by the three techniques are 1.03 × 10¹⁷ Nm, 5.28; 1.24 × 10¹⁷ Nm, 5.33; and 1.68 × 10¹⁷ Nm, 5.42; respectively. The calculated fault radius, stress drop, and the average dislocation assuming a circular fault model are 7.2 km, 0.63 Mpa, and 0.11 m, respectively.     

线性震中迁移交汇法和强震位置预报机理讨论

由短期、长距离、线性震中迁移线交汇得到的稳定交汇区进行强震地点预报方法称为线性震中迁移交汇法。存在由源向场的迁移、由场向源的迁移及过源迁移３种多类型。这３种迁移的总特征是在未来震源区和其附近形成稳定的交汇区。着重讨论“交汇法”的物理基础,并用实例进行证明。     

The location and mislocation of subcrustal earthquakes

In regions, such as subduction zones, with systematic velocity variations from the travel-time model, the estimated hypocentres may be significantly mislocated and the estimated hypocentres may depend strongly on the stations and phases used. The estimated depths of earthquakes beneath the North Island, New Zealand, as determined by the International Seismological Centre and the New Zealand Seismological Observatory are used to illustrate this effect. Compared with ISC depths determined using local P phases only, the NZSO depths using local P and S phases are shallower by about 15 km while ISC depths using local and releseismic P phases are shallower again by about 30 km (and up to 70 km). Thus ISC depths which do not use teleseismic observations are not consistent with those which do and so care must be exercised when using both types of solution.     

Far-field effects of Eastern Mediterranean earthquakes in Lower Egypt

In this note we examine the decay of intensity with distance of earthquakesoriginating in the southern part of the Aegean, offshore Egypt and in theEastern Mediterranean regions, events chiefly with epicentres at sea, whichhave caused concern and occasionally some damage in Lower Egypt, particularlyin Cairo. Also we derive an empirical formula for the assessment of thesurface-wave magnitude of crustal and intermediate depth earthquakes in theregion.     

芦山7.0级地震序列的震源位置与震源机制解特征

基于中国国家和四川区域数字地震台网记录,采用HypoDD方法精确定位了四川芦山ML2.0级以上地震序列的震源位置,采用CAP方法反演了36次ML4.0级以上地震的最佳双力偶震源机制解,并利用小震分布和区域应力场拟合了可能存在的发震断层面参数,从而综合分析了芦山地震序列的震源深度、震源机制和震源破裂面特征,探讨可能的发震构造.结果显示,7.0级主震的震源位置为30.30°N、102.97°E,初始破裂深度为15 km左右,震源矩心深度为14 km左右,最佳双力偶震源机制解的两组节面分别为走向209°/倾角46°/滑动角94°和走向23°/倾角44°/滑动角86°,可视为纯逆冲型地震破裂,绝大多数ML4.0级以上余震的震源机制也表现出与主震类似的逆冲破裂特征.ML2.0级以上余震序列发生在主震两侧,集中分布的长轴为30 km左右,震源深度主要集中在5～27 km,ML3.5级以上较大余震则集中分布在9～25 km的深度上,并揭示出发震断层倾向北西的特征.利用小震分布和区域应力场拟合得到发震断层参数为走向207°/倾角50°/滑动角92°,绝大多数余震发生在断层面附近10 km左右的区域.综合地震序列分布特征、主震震源深度和已有破裂过程研究结果,可以推测主震破裂过程自初始点沿断层的两侧扩展破裂,南侧破裂比北侧稍长,滑动量主要集中在初始破裂点附近,可能没有破裂到地表.综合本文研究成果、地震烈度分布和现有的科学考察结果,初步推测发震构造为龙门山山前断裂,也不排除主震震中东侧还存在一条未知的基底断裂发震的可能性.     

Surface latent heat flux anomalies preceding inland earthquakes in China

Using data from the National Center for Environmental Prediction (NCEP), the paper analyzed the surface latent heat flux (SLHF) variations for five inland earthquakes occurred in some lake area, moist area and arid area of China during recent years. We used the SLHF daily and monthly data to differentiate the global and seasonal variability from the transient local anomalies. The temporal scale of the observed variations is 1-2 months before and after the earthquakes, and spatial scale is about 10°×10°. The result suggests that the SLHFs adjacent the epicenters all are anomalous high value (>μ+2σ) 8-30 days before the shocks as compared with past several years of data. Different from the abnormal meteorological phenomenon, the distribution of the anomalies was isolated and local, which usually occurred in the epicenter and its adjacent area, or along the fault lines. The increase of SLHF was tightly related with the season which the earthquake occurs in; the maximal (125 W/m², Pu'er earthquake) and minimal (25 W/m², Gaize earthquake) anomalies were in summer and winter, respectively. The abundant surface water and groundwater in the epicenter and its adjacent region can provide necessary condition for the change of SLHF. To further confirm the reliability of SLHF anomaly, it is necessary to explore its physical mechanism in depth by more earthquake cases.     

2010年以来四川地区中强地震震源机制反演及深度确定

2008年5月12日四川龙门山断裂带发生了汶川8.0级地震,之后四川境内发生了两次7.0级地震（其中一个是芦山地震）,为了研究汶川地震之后龙门山断裂带及周边区域的地震活动性,本研究收集了国家地震台网和四川区域地震台网2010年1月1日-2017年12月31日四川地区发生的17次M ≥ 5.0地震以及120多次5.0 > M ≥ 4.0地震的波形资料,利用波形拟合法反演了震源机制解及区域应力场.反演结果显示,位于龙门山断裂带上的地震,震源机制以逆冲型为主,鲜水河断裂带地震震源机制以走滑型为主,而川滇块体西南部的理塘断裂、金沙江断裂附近,震源机制解以正断层为主.根据震源机制解反演得到的龙门山地区、鲜水河地区的主压应力场方向为WNW、近EW向.川滇块体的巴塘、理塘等地区,其主压应力轴方向为12°左右,接近SN向,且仰角接近40°左右.本研究利用面波振幅谱特征对震源深度进行了精确定位,定位结果与中国地震台网中心（CENC）,美国地震调查局（USGS）,国际地震中心（ISC）等机构地震目录进行了对比.结果显示,四川地区强震震源深度主要分布在20 km以上的中上地壳.龙门山地区震源优势分布在10~20 km,鲜水河断裂地震震源深度在10 km左右,川滇块体西南部的理塘断裂,巴塘断裂,金沙江断裂等地区,震源深度一般在5~10 km范围.

     

用地震波波形拟合方法研究中小地震的震源机制

采用网格搜索方法,利用区域地震三分量全波形资料,对中小地震震源机制的反演方法进行了研究。反演采用初动约束、分段求相关系数,以及幅值加权的混合方法计算误差函数,通过格点搜索法确定震源深度。理论模型试验表明,反演结果具有较好的稳定性和可靠性。云南地区区域数字地震台网的观测资料反演表明,该方法可以合理地拟合观测波形资料。将2001年7月9日(24.93°N,101.47°E)发生的MS 5.3地震的震源机制解与哈佛大学CMT进行了对比,结果表明,Z分量波形拟合略比CMT拟合的好,R分量和T分量的波形拟合明显好于CMT的对应分量。 我们对2001年4月5日在(25.77°N,102.30°E)发生的mb 4.8地震进行了震源机制反演。结果表明,该地震主要表现为走滑断层,震源机制解为(180°,80°,11°)。根据这两个地震震源机制推断的主应力轴,与该地区现代构造应力场特征基本一致。     

Source mechanism of earthquakes in Peru

The source mechanism of 19 earthquakes that occurred in Peru (1990–1996) is studied using broad band data. Focal mechanisms are obtained using polarities of P wave and body wave form inversion. Shallow earthquakes show complex source time functions, intermediate and deep depth shocks have simpler ones. Stress distributions have been obtained from focal mechanisms estimated in this study and previous studies. Shallow earthquakes show reverse faulting with an ENE-WSW to E-W oriented pressure axes. Intermediate depth shocks indicate horizontal extension on E-W direction, normal to the Peru-Chilean trench. Earthquakes with foci at very deep depth show horizontal extension in the E-W direction in Peru-Brazil and N-S in Peru-Bolivia borders. This difference in stress orientation may indicate a different origin for deep activity at each region.     

Tsunami and mechanism of great earthquakes

The relation between tsunamis and sea-bottom deformations associated with the Kurile Islands earthquake of 1969 and the Tokachi-Oki earthquake of 1968 is studied on the basis of a fairly complete set of seismological and tsunami data. The seismic results are included in the calculation of static crustal deformations. The calculated deformations are compared with the tsunami source area as obtained by the inverse refraction diagram, the first motion of tsunami waves, and the height of the sea-level disturbance at the source. It is found that such deformations as predicted by the seismic results can quantitatively explain the source parameters of tsunamis. These findings strongly favor the idea that tsunamis are generated by tectonic deformations rather than by large submarine landslides and slumps. This conclusion is supported by additional analyses for the 1964 Niigata, 1944 Tonankai, 1933 Sanriku earthquakes. For the 1946 Nankaido earthquake, the source deformation responsible for the tsunami generation is of much greater magnitude than that for seismic waves.     

祁连山中东段地区中小地震震源机制和区域应力场

利用哥伦比亚大学 GCMT 目录给出的祁连山中东段地区中强地震震源机制资料,研究较大区域（34°-41°N,100°-106°E）的应力场;利用该地区布设的中法微震数字监测台网多年监测资料和甘肃数字监测台网资料,使用 P 波和 S 波初动及振幅比联合反演方法,反演中小地震震源机制解和发震应力场。结果表明,地区构造应力大致为北东40°-45°水平向压应力;景泰地区主压应力方向约北东45°,绝大多数地震为走滑型。天祝-古浪地区有相当部分的逆断层地震分布,主压应力方向约60°,P 轴仰角在10°左右优势分布,大致为水平应力场。这与大区域构造应力场和断层实际分布基本一致。     

Focal mechanism of volcanic earthquakes

The focal mechanism solutions for Type A volcanic earthquakes connected with eruptions of the Miake-sima, Tori-shima (Japan) and Beerenberg (Jan Mayen Island) volcanoes are presented. All the considered volcanic earthquakes show focal mechanism of the strike-slip type of faulting. Stresses acting in the volcanic earthquake foci can well be attributed to the regional stress systems.     

Surface waves from earthquakes in Northern Atlantic-Arctic Ocean

Summary Earthquakes in the region of Jan Mayen exhibit two different appearances on records of near-by stations: classa with extremely well developed Love waves and less well developed Rayleigh waves, classb with poorly developed or missing Love waves but with clear Rayleigh waves. The difference between the two classes is ascribed to different focal depths. The Love waves of classa start simultaneously with theS wave and have initial periods over 40 sec; they have a small vertical component increasing along the wave train. They are unable to propagate beyond the continental margin for any considerable distance, probably due to a breakdown of the condition for constructive interference valid for their oceanic propagation.The oceanic dispersion curves both of Love and Rayleigh waves have been deduced using records at Kiruna, Uppsala, Bergen, Copenhagen, Scoresby Sund, Reykjavik, and Akureyri. The average thickness of the oceanic crust is around 15 km in the Norwegian Sea. For the Mid-Atlantic Ridge southwest of Reykjavik a crustal thickness of 10 km is obtained. The average thickness of unconsolidated sediments is around 2.4 km for the Norwegian Sea, and around 1.0 km in shallower regions of the ocean toward Iceland and Greenland.

---

Zusammenfassung Erdbeben in der Gegend von Jan Mayen zeigen zwei verschiedene Erscheinungen in den Aufzeichnungen naheliegender Stationen: Klassea mit ausserordentlich gut entwickelten Love-Wellen und weniger gut ausgebildeten Rayleigh-Wellen, Klasseb mit schwach entwickelten oder fehlenden Love-Wellen aber mit deutlichen Rayleigh-Wellen. Der Unterschied zwischen den beiden Klassen wird verschiedener Herdtiefe zugeschrieben. Die Love-Wellen der Klassea beginnen unmittelbar mit derS-Welle und haben Anfangsperioden über 40 sek; sie haben eine geringe vertikale Komponente, die im Laufe des Wellenzuges zunimmt. Sie können sich nicht über den Kontinentalrand beträchtlich weit fortpflanzen, was möglicherweise einem Aufhören der Voraussetzung für konstruktive Interferenz, die bei ihrer ozeanischen Ausbreitung vorhanden ist, zugeschrieben werden muss.Unter der Benutzung der Aufzeichnungen von Kiruna, Uppsala, Bergen, Kopenhagen, Scoresby Sund, Reykjavik und Akureyri wurden ozeanische Dispersionskurven sowohl für Love- als auch für Rayleigh-Wellen bestimmt. Die mittlere Mächtigkeit der ozeanischen Kruste beträgt ungefähr 15 km unter dem Europäischen Nordmeer. Für die Mittelatlantische Schwelle südwestlich von Reykjavik wurde eine Krustenmächtigkeit von 10 km erhalten. Die mittlere Mächtigkeit von unbefestigten Sedimenten ist ungefähr 2.4 km für das Europäische Nordmeer und ungefähr 1.0 km in Gegenden flacheren Meeres nach Island und Grönland hin.

     

关于速报深远震问题的探讨

通过分析云南数字地震台网1998~2006年的地震记录资料,给出了该台网的深远地震震相记录特征,避免了常规分析方法中将深远地震误作浅源地震而带来的定位误差;利用1978年1月~2005年8月的深远地震记录资料,绘制了全球深远地震震中分布图,以作为地震速报的参考。     

断-块模型中走滑型地震应力触发研究——以青藏高原北部几次强震为例

从发震断层与活动块体的分布关系出发,以青藏高原北部地区几次强震为例,研究了介质非连续的断－块构造模型中地震永久位移造成的区域断层静库仑应力变化．研究表明,在断块构造模型中,走滑型为主的地震位错引起的区域断层库仑应力变化在地震破裂面以外随距离衰减很快,影响范围仅为几十公里,和余震分布尺度相当;对有地表破裂数据的1937年M7.5花石峡地震、1997年M7.5玛尼地震和2001年M7.8可可西里地震的模拟结果显示,先前地震的断层位移在后续地震断层面所造成的库仑应力甚微,预示了远距离地震之间的静应力触发效应不明显．