Source parameters of the Gonghe,Qinghai Province,China,earthquake from inversion of digital broadband waveform data

ＳｏｕｒｃｅｐａｒａｍｅｔｅｒｓｏｆｔｈｅＧｏｎｇｈｅ，ＱｉｎｇｈａｉＰｒｏｖｉｎｃｅ，Ｃｈｉｎａ，ｅａｒｔｈｑｕａｋｅｆｒｏｍｉｎｖｅｒｓｉｏｎｏｆｄｉｇｉｔａｌｂｒｏａｄｂａｎｄｗａｖｅｆｏｒｍｄａｔａＬＩ－ＳＨＥＮＧＸＵ（许立生）ａｎｄＹＵＮ...     

Cround vertical deformation in earthquake of Gonghe,Qinghai Province

ＣｒｏｕｎｄｖｅｒｔｉｃａｌｄｅｆｏｒｍａｔｉｏｎｉｎｅａｒｔｈｑｕａｋｅｏｆＧｏｎｇｈｅ，ＱｉｎｇｈａｉＰｒｏｖｉｎｃｅＳｈｏｕ－ＷｅｎＧＯＮＧ（巩守文）ａｎｄＦｅｎｇ－ＹｉｎｇＧＵＯ（郭逢英）（ＳｅｃｏｎｄＣｒｕｓｔａｌＤｅｆｏｒｍａｔｉｏｎＭｏ...     

Study of the earthquake of the January 23, 1880, in San Cristóbal,Cuba and the Guane fault

All available data on the January 23, 1880, earthquake near San Cristobal, Western Cuba, are compiled and presented here. The earthquake reached a maximum intensity of eight degrees (MSK) and caused three fatalities. It was accompanied by 65 aftershocks and was felt as far away as the Florida Keys. Twentieth century specialists has associated this event, in its day the strongest recorded (Ms = 6.2) in the region, with the Pinar fault. The Pinar fault is well expressed topographically as the boundary between the Guaniguanico Range in the north and an alluvial plain to the south. Most of the major damage caused by the earthquake was located on the alluvial plain, which in consequence has been considered the epicenter area. In the study presented here, the data compiled from the first reports of Father Benito Vines Martorell, S.J., and Pedro Salteraín y Legarra, indicate that the seismic structure was located in the alluvial plain, and that it was the Guane fault, and not the Pinar fault, that was responsible for the earthquake. The Guane fault, found below the alluvial sediments, extends NE-SW for over 110 km. Its eastern extreme, near San José de las Lajas (La Habana), is linked to another active fault which represents a seismoactive knot responsible for the earthquake of March 9, 1995 (I = 5 degrees, MSK). Seismic events of the Western Cuban region are related to the transpressive interaction of the North American and Caribbean Plates, damped by oceanic structures.     

Strong earthquake activity all over the world and strong-moderate earthquake activity within and near China (December, 1999～January, 2000)

Illustration All the data in this catalog are chosen from the 2 Preliminary Seismological Report of Chinese Seismic Stations2 (Its abbreviation is 2 Monthly Report2 ). The catalog includes the events of M3 4.7 in and near China and M3 6 all over the world. The 2 Monthly Report2 is monthly compiled by the Ninth Section of Institute of Geophysics, CSB.     

Strong earthquake activity all over the world and strong-moderate earthquake activity within and near China (December, 2000～January, 2001)

IllustrationAll the data in this catalog are chosen from the (Preliminary Seismological Report of Chinese Seismic Stations( (Its abbreviation is (Monthly Report(). The catalog includes the events of M(4.7 in and near China and M(6 all over the world. The (Monthly Report( is monthly compiled by the Ninth Section of Institute of Geophysics, CSB.The origin times of earthquakes in the catalog adopt coordinated universal time (UTC) in accordance with international convention. The location…     

Strong earthquake activity all over the world and strong-moderate earthquake activity within and near China (December, 2001～January, 2002)

Illustration All the data in this catalog are chosen from the Preliminary Seismological Report of Chinese Seismic Stations (Its abbreviation is Monthly Report). The catalog includes the events of M4.7 in and near China and M6 all over the world. The Monthly Report is monthly compiled by the Ninth Section of Institute of Geophysics, CSB. The origin times of earthquakes in the catalog adopt coordinated universal time (UTC) in accordance with international convention. The location of ev…     

Strong earthquake activity all over the world and strong-moderate earthquake activity within and near China(December,1997～January,1998)

ＳｔｒｏｎｇｅａｒｔｈｑｕａｋｅａｃｔｉｖｉｔｙａｌｏｖｅｒｔｈｅｗｏｒｌｄａｎｄｓｔｒｏｎｇｍｏｄｅｒａｔｅｅａｒｔｈｑｕａｋｅａｃｔｉｖｉｔｙｗｉｔｈｉｎａｎｄｎｅａｒＣｈｉｎａ（Ｄｅｃｅｍｂｅｒ，１９９７～Ｊａｎｕａｒｙ，１９９８）ＰＥＩ?..     

Strong earthquake activity all over the world and strong-moderate earthquake activity within and near China(December,1996～January,1997)

ｔｒｏｎｇｅａｒｔｈｑｕａｋｅａｃｔｉｖｉｔｙａｌｏｖｅｒｔｈｅｗｏｒｌｄａｎｄｓｔｒｏｎｇｍｏｄｅｒａｔｅｅａｒｔｈｑｕａｋｅａｃｔｉｖｉｔｙｗｉｔｈｉｎａｎｄｎｅａｒＣｈｉｎａ（Ｄｅｃｅｍｂｅｒ，１９９６～Ｊａｎｕａｒｙ，１９９７）ＰＥＩＳ...     

Strong earthquake activity all over the world and strong-moderate earthquake activity within and near China (December, 2003 ~ January, 2004)

Illustration All the data in this catalog are chosen from the Preliminary Seismological Report of Chi-nese Seismic Stations (Its abbreviation is Monthly Report). The catalog includes the events of M4.7 in and near China and M6 all over the world. The Monthly Report is monthly compiled by the Ninth Section of Institute of Geophysics, CSB. The origin times of earthquakes in the catalog adopt coordinated universal time (UTC) in accordance with international convention. The location of e…     

Is the September 5, 2022, Luding MS6.8 earthquake an ‘unexpected’ event?

Whether the September 5, 2022, Luding M_S6.8 earthquake is an ‘expected’ event in the context of earthquake forecast? This commentary discusses this issue mainly using the recently proposed ‘earthquake nowcasting’ approach.     

Spatial and temporal rupture process of the January 26, 2001, Gujarat, India, M_S=7.8 earthquake

Introduction An earthquake of MS=7.8 occurred near the Gujarat of India on January 26, 2001, which was one of the most deadly earthquakes since there was the record in the Indian history (Bendick, et al, 2001; Gupta, et al, 2001). The USGS of USA determined the origin time of the earthquake to be 3h16min41s (UTC), and the epicenter location to be 70.32篍, 23.40篘. Shortly after the earthquake, the moment tensor solutions or focal mechanisms and other related parameters were offered by s…     

Variation of stress during the rupture process of the 1995 M_L=4.1 Shacheng, Hebei, China, earthquake sequence

Introduction An earthquake could be caused by the failure of focal material or fast slip on the pre-existed faults under the tectonic stress based on the understanding of the occurrence process of earth-quakes in which the stress change could play a key role. Therefore to examine the stress change is beneficial to understanding the physic process actually occurring in the source region deeply. The apparent stress is defined as the product of seismic efficiency and the average stress on the foc…     

The fault plane of the 1991,Datong-Yang-gao,Shanxi,China,Ms=5.8 earthquake

Ｔｈｅｆａｕｌｔｐｌａｎｅｏｆｔｈｅ１９９１，Ｄａｔｏｎｇ－Ｙａｎｇ－ｇａｏ，Ｓｈａｎｘｉ，Ｃｈｉｎａ，Ｍｓ＝５．８ｅａｒｔｈｑｕａｋｅＭｉｎｇＷＡＮＧ（王鸣），Ｌｉａｎ－ＱｉａｎｇＺＨＡＮＧ（张廉强）ａｎｄＰｅｉ－ＤｅＷＡＮＧ（王培德）（Ｉｎｓｔｉ...     

Automatic recognition of damaged town buildings caused by earthquake using remote sensing information: Taking the 2001 Bhuj, India, earthquake and the 1976 Tangshan, China, earthquake as examples

Introduction As we well know, the hazard of earthquake is very wide especially in cities. The conventionalmethods to investigate the damage are difficult to meet the requirements in applications. In recentyears, with the rapid development of remote sensing, especially the successful launch and applica-tion of high-resolution commercial remote sensing satellite, it has become possible to recognize andextract damage information by using remote sensing. The researchers at home and abroad hav…     

A τ_c magnitude estimation of the 20 April 2013 Lushan earthquake,Sichuan, China

A crucial part of proposed earthquake early warning systems is a rapid estimate for earthquake magnitude.Most of these methods are focused on the first part of the P-wave train,the earlier and less destructive part of the ground motion that follows an earthquake.A method has been proposed by using the period of the P-wave to determine the magnitude of a large earthquake at local distance,and a specific relation for the Sichuan region was calibrated according to acceleration records of Wenchuan earthquake.The Mw 6.6 earthquake hit Lushan County,Sichuan,on April 20,2013 and the largest aftershocks provide a useful dataset to validate the proposed relation and discuss the risks connected to the extrapolation of magnitude relations with a poor dataset of large earthquake waveforms.A discrepancy between the local magnitude(ML)estimated by means ofτc evaluation and the standard ML(6.4 vs.7.0)suggests using caution when ML vs.τc calibrations do not include a relevant dataset of large earthquakes.Effects from large residuals could be mitigated or removed by introducing selection rules onτc function,by regionalizing the ML vs.τc function in the presence of significant tectonic or geological heterogeneity,and by using probabilistic and evolutionary methods.     

Strong motion characteristics of the M_w 6.6 Lushan earthquake,Sichuan,China——an insight into the spatial difference of a typical thrust fault earthquake

Near-field strong ground motions are useful for engineering seismology studies and seismic design, but dense observation networks of damaging earthquakes are still rare. In this study, based on the strong-motion data from the M w 6.6 Lushan earthquake, the ground motion parameters in different spatial regions are systematically analyzed, and the contributions from different effects, like the hanging-wall effect, directivity effect, and attenuation effect are separated to the extent possible. Different engineering parameters from the observed ground motions are compared with the local design response spectra and a new attenuation relation of Western China. General results indicate that the high frequency ground motion, like the peak ground acceleration, on two sides of the fault plane is sensitive to the hanging-wall effect, whereas the low frequency ground motion, like the long period spectral acceleration, in the rupture propagation direction is affected by the directivity effect. Moreover, although the M w 6.6 Lushan earthquake is not a large magnitude event, the spatial difference of ground motion is still obvious; thus, for a thrust faulting earthquake, in addition to the hanging effect, the directivity effect should also be considered.     

New insights on the tsunami recording of the May, 21, 2003, Mw 6.9 Boumerdès earthquake from tidal data analysis

We analyzed sea level data from a set of tide gauge stations located in the central and western Mediterranean Sea, that recorded the tsunami generated by the Mw 6.8 Boumerdès earthquake striking the coast of Algeria on May 21, 2003. This earthquake caused more than 2200 victims and thousands of injured. The causative fault was located a few kilometers offshore and during the rupture a tsunami was triggered. Waves were felt along a large part of the western and northern Mediterranean coasts, and in the Balearic islands waves higher that 2 m were measured. In this paper we analyze a more complete tidal data set, with respect to previous studies, now consisting of 22 tidal stations located in Italy, France and Spain. To characterize the change of the tidal signal at each station we used the Empirical Mode Decomposition (EMD). By means of this technique, which is suitable to analyze and to characterize the dynamical behavior of non-stationary time series, we provide a precise measurement of the arrival times and amplitudes at the tidal stations and identify how this tsunami affected the principal and long term tidal components. Our findings improve previous results for this earthquake, since they allow the detection of significant amplitude fluctuations associated with the tsunami in the majority of stations, including the farthest ones.