四川地区地下水位对汶川地震的同震效应

系统地清理、分析了四川地区2008年汶川地震时在测水位观测到的同震效应.结果显示:汶川地震的水位同震效应以阶跃变化中的阶升变化为主,同时兼有持续缓慢变化、潮汐畸变变化、无变化、脉冲变化和突跳式变化.研究表明:阶升、阶降井点在空间上分布不均匀,相对于震中位置的关联性不强,但距离震中越近,阶升的台项越多.震时水位变化幅度不...     

2013年芦山MS7.0地震和2008年汶川MS8.0地震井水位同震变化的比较分析

以芦山、汶川地震震中为中心,选择了8个井点,对2个地震引起的井水位同震变化进行了比较,重点分析了3口同震变化反向的井点,即重庆的荣昌华江井、北碚柳荫井和四川的泸沽湖井。为使对比研究结果可靠,进一步收集了2011年3月11日日本9.0级地震、2012年4月11日苏门答腊北部海域8.6级地震引起的井水位同震变化资料。对汶川、芦山地震引起的同震体应变的计算结果显示：汶川地震时,荣昌华江井、北碚柳荫井和泸沽湖井水位同震变化与井点位置处的同震体应变一致,即位于同震体应变压缩区的井水位上升,位于体应变膨胀区的井水位下降;芦山地震时,3口井的水位同震变化与同震体应变不一致,表现出与日本、苏门答腊地震时相似的同震变化特征。     

Some isotopic and hydrological changes associated with the 1999 Chi-Chi earthquake, Taiwan

Abstract   The changes in the isotopic composition of, and the groundwater level in, the Choshui River alluvial fan near the ruptured Chelungpu Fault during and following the 1999 ( M _w = 7.5) Chi-Chi earthquake in Taiwan are reported. Three aspects of the hydrological changes are noticed. First, following the Chi-Chi earthquake, the lower aquifers beneath the Choshui River fan showed a significant shift in isotopic composition towards that of the surface water in the Choshui River, suggesting enhanced exchanges of water between the river and the groundwater. Second, in some wells, water levels and isotopic compositions in different aquifers converged to the same respective values during the Chi-Chi earthquake, suggesting coseismic exchanges of water between the different aquifers, which implies enhanced permeability due perhaps to the fracturing and breaching of aquitards between the aquifers. Third, the pattern of the coseismic water-level response is distinctly different from that of the shift in the isotopic composition, suggesting that they were produced by different mechanisms.     

北京太平庄井地下水物理动态研究

根据太平庄井地下水水位、流量、水温等物理动态特征，探讨了三项潮汐动态（水位、流量、水温）、洼地积水倒压传递效应、截流效应、水温同震阶降动态、震前流量突变异常动态等微观动态及其与地震的关系。最后讨论了三项潮汐动态机理，认为太平庄井对地震监测预报，特别是首都圈地震监测预报有重要作用     

Characteristics of coseismic water level changes at Tangshan well for the Wenchuan MS8.0 earthquake and its larger aftershocks

Coseismic water level changes which may have been induced by the Wenchuan M_S8.0 earthquake and its 15 larger aftershocks (M_S≥?5.4) have been observed at Tangshan well. We analyze the correlation between coseismic parameters (maximum amplitude, duration, coseismic step and the time when the coseismic reach its maximum amplitude) and earthquake parameters (magnitude, well-epicenter distance and depth), and then compare the time when the coseismic oscillation reaches its maximum amplitude with the seismogram from Douhe seismic station which is about 16.3 km away from Tangshan well. The analysis indicates that magnitude is the main factor influencing the induced coseismic water level changes, and that the well-epicenter distance and depth have less influence. M_S magnitude has the strongest correlation with the coseismic water level changes comparing to M_W and M_L magnitudes. There exists strong correlation between the maximum amplitude, step size and the oscillation duration. The water level oscillation and step are both caused by dynamic strain sourcing from seismic waves. Most of the times when the oscillations reach their maximum amplitudes are between S and Rayleigh waves. The coseismic water level changes are due to the co-effect of seismic waves and hydro-geological environments.     

云南丽江井水位与水温对印尼8．5级地震和汶川8．0级地震的同震响应特征分析

本文分析了云南丽江井在印尼8．5级、汶川8．0级地震时观测到的水位、水温同震变化特征,结果表明丽江井水位在2次地震中水震波都表现为振荡型。而温度则是印尼地震时上升,汶JIf地震时下降。研究表明：丽江井水温的不同表现形式与该井所处的地质构造及地震发生的季节相关。     

Case 21 water level and strain changes preceding and following the August 4, 1985 Kettleman Hills, California, earthquake

Two of the four wells monitored near Parkfield, California, during 1985 showed water level rises beginning three days before theM _w 6.1 Kettleman Hills earthquake. In one of these wells, the 3.0 cm rise was nearly unique in five years of water level data. However, in the other well, which showed a 3.8 cm rise, many other changes of comparable size have been observed. Both wells that did not display pre-earthquake rises tap partially confined aquifers that cannot sustain pressure changes due to tectonic strain having periods longer than several days. We evaluate the effect of partial aquifer confinement on the ability of these four wells to display water level changes in response to aquifer strain. Although the vertical hydraulic diffusivities cannot be determined uniquely, we can find a value of diffusivity for each site that is consistent with the site's tidal and barometric responses as well as with the rate of partial recovery of the coseismic water level drops. Furthermore, the diffusivity for one well is high enough to explain why the preseismic rise could not have been detected there. For the fourth well, the diffusivity is high enough to have reduced the size of the preseismic signal as much as 50%, although it should still have been detectable. Imperfect confinement cannot explain the persistent water level changes in the two partially confined aquifers, but it does show that they were not due to volume strain. The pre-earthquake water level rises may have been precursors to the Kettleman Hills earthquake. If so, they probably were not caused by accelerating slip over the part of the fault plane that ruptured in that earthquake because they are of opposite sign to the observed coseismic water level drops.     

Groundwater Level Changes in Taiwan Caused by The Wenchuan Earthquake on 12 May 2008

Widespread persistent coseismic groundwater level changes induced by the M _w 7.9 Wenchuan earthquake were recorded in 80 wells in Taiwan, located approximately 2,000?km from the epicenter. The timing and magnitude of these changes, ranging from ?40 to +23?cm, have been examined by statistical evaluation. The coseismic fall dominated in the plain area, but in the mountainous area most changes are coseismic rises. Both the coseismic rise and the coseismic fall were observed in wells of different depths at two monitoring stations. The processes of the coseismic changes can be shown by the high-frequency well water level data. Analysis of the 1?Hz water level data and the broadband seismogram revealed that a temporary water level change, ranging from 0.2 to 2.3?cm, occurred at the arrival of high-energy Love waves and Rayleigh waves. However, a water level change of 0.3–6.4?cm occurred in 7–20?min after the passing of high-energy surface waves. It is doubtful that such a change could be induced directly by ground shaking. The cross-formational flow due to fracturing or unclogging of sediment pores was possibly too slow to cause the coseismic change. Further studies are required to understand the mechanism of coseismic groundwater level changes induced by a distant earthquake.     

北京塔院井数字化观测水温的同震效应研究

基于北京塔院井数字化水温观测资料，分析了远震引起的水温同震效应，注意到塔院井水温同震变化总是具有下降－上升－恢复的过程，不受地震方位和震源机制的影响；水温同震下降幅度随震级的增大而增大，随震中距的增大而减小， 三者之间有较好的关系；震后水温后效恢复上升幅值受水位动态影响. 最后，对塔院井水温同震效应机理进行了探讨，初步研究结果显示，井孔中的水体受震荡激发而加速对流与掺混是导致水温先下降的主要原因:当井水受到地震波的作用时，对流加速，井内深部较热的水体上涌， 而浅部较冷的水体下沉，水温探头将先观测到温度下降现象； 震后水震波逐渐平息，探头附近井水温逐步恢复上升.      

2019年长宁M6.0和2018年兴文M5.7地震引起的井水位同震响应对比分析

2019年长宁M6.0地震和2018年兴文M5.7地震引起了华蓥山断裂及其附近区域8口观测井水位不同程度的响应变化。 本文对比分析各观测井水位的同震响应特征, 从地震波能量密度、 同震破裂体应变、 含水层渗透性参数变化以及断裂带控制作用几个方面探讨了其同震响应机理。 结果显示, 井水位同震响应的幅度与地震波能量密度有一定关系; 2019年长宁M6.0地震引起的井水位同震响应形态符合同震破裂体应变四象限空间分布特征, 但2018年兴文M5.7地震则不符合; 两次地震引起的含水层渗透性参数变化存在空间上的不一致性和单点各向异性, 并且断裂带自身的水文条件对井水位同震响应形态和幅度有一定的控制作用。 综合分析认为, 目前已有的几种机理无法完全解释两次地震引起的井水位同震响应现象。     

中国大陆井水位与水温动态对汶川M_S 8.0地震的同震响应特征分析

分析了汶川MS8.0地震在中国大陆引起的水位、水温同震变化特征,对比研究了2007年9月12日印尼苏门答腊MS8.5远震和汶川MS8.0近震在四川及其附近地区引起的水位、水温同震变化差异,结果表明:汶川地震在中国大陆引起的水位同震变化以上升为主,同时水位上升与下降的井点空间分布表现出一定的分区性;水位、水温同方向阶变的井点数比例高于两者反方向阶变井点数比例,当水位同震变化为振荡型时,水温以下降型为主;相对于远震,近震引起的水位、水温同震变化井点数量增加,无变化井点数量减少;所有井水位和大多数井水温同震阶变的方向都不因地震的远近、大小、震源机制或地震方位的变化而改变,个别发生水温同震升降方向变化的井点是由于水的自流状态和水位同震阶变由振荡转为阶变的改变所引起;水位同震升降性质受控于当地的地质构造环境和水文地质条件,而水温同震变化还与地震波引起的井孔中水的运动方式、水温探头放置的位置等因素有关,其机理更为复杂     

黄骅井水位对苏门答腊5次地震的同震响应初步研究

利用ARX模型分析了河北省黄骅井水位对气压和固体潮的响应特征,并利用该模型消除气压和固体潮对该井水位的影响,准确地提取了5次苏门答腊大震引起的同震水位变化异常.分析了该井水位对这5次地震的同震响应模式与震级和震源机制解的关系,初步探讨了引起该井水位同震变化复杂性的可能原因.认为,即使发生在同一地区,震源机制解基本相同的地震也会引起远距离同一井水位不同的响应特征,其响应幅度与发震震级有关,响应方式可能与井孔所处地区的局部应力应变状态或井-含水层系统的结构变化有关.     

山东省井水位对几次大地震同震响应的比较分析

采用多井对多震的方式,选取山东省地下流体观测井网中同震响应较好的6口观测井作为研究对象,分别从水位变化形态和幅度对比分析2011年日本M_W9.0地震、2012年苏门答腊M_W8.6地震和2015年尼泊尔M_W7.8地震引起的井水位变化特征,探讨引起该变化的可能机理。研究结果显示:水位同震变化形态以振荡为主;通过定量分析认为聊古一井井水位的阶升是由含水层渗透系数增大所致;位于同一断裂带上的聊古一井和鲁27井井水位在同一地震中所表现的变化形态不同,可能与两个观测井所处的地质构造条件和地震活动背景不同有关;区域应力场的变化会影响栖霞鲁07井的水位同震变化形态;水位同震变化幅度与震级、井震距存在一定关系,同时也取决于含水层水文地质条件的变化量。      

Coseismic effects of water temperature based on digital observation from Tayuan well, Beijing

On the basis of digital records from Tayuan well,we study coseismic effects of water temperature caused by re-mote earthquakes.The records show that the water temperature changes are consistently following the process ofdrop-rise-recovery regardless of focal mechanism or epicentral directions.The step amplitude of water temperatureincreases with the increase of earthquake magnitude,and decreases with the decrease of epicentral distances.Theyhave rather well correlation.Water temperature rising after earthquake is influenced by water level variations.Fi-nally,the mechanisms of coseismic effects of water temperature have been discussed.Preliminary study shows thataccelerated convection and mixing of different temperature water in virtue of seismic wave are the main causes ofwater temperature drops.Seismic wave accelerates water convection,which causes warm water to move up fromdeeper part of the well and cold water to go down from the upper part.Temperature probe will detect water tem-perature drops at early stage.After the occurrence of earthquake,as the fluctuation of water level gradually quietsdown,water temperature near the probe begins to rise.     

Approximate recovery of coseismic deformation from Taiwan strong-motion records

Since 1990, digital strong-motion accelerographs and global positioning system (GPS) instruments have been widely deployed in the Taiwan region (Shin et al. 2003; Yu et al. 2001). The 1999 Chi-Chi, Mw 7.6 earthquake and the 2003 Chengkung, Mw 6.8 earthquake were well recorded by both digital accelerographs and GPS instruments. These data offer a good opportunity to determine coseismic displacements from strong-motion records and to compare the results with those derived from GPS measurements. As noted by Boore (2001), a double integration of the acceleration data often leads to unreasonable results, and baseline corrections are therefore required in most cases before the integration. Based on the works of Iwan et al. (1985) and Boore (2001), we developed an improved method for baseline correction and validated it using an extensive set of data from shake-table tests of a known “step” displacement on 249 accelerographs. Our baseline correction method recovered about 97% of the actual displacement from the shake-table data. We then applied this baseline correction method to compute coseismic displacements from the strong-motion data of the Chi-Chi and Chengkung earthquakes. Our results agree favorably with the coseismic displacements determined by the GPS measurements at nearby sites. The ratio of seismic to geodetic displacement varies from 0.78 to 1.41, with an average of about 1.05.     

Spatial and Temporal Changes of Groundwater Level Induced by Thrust Faulting

Changes of groundwater level, ranging from a fall of 11.10 m to a rise of 7.42 m, induced by thrust faulting during the 1999 M_w 7.6, Chi-Chi earthquake have been recorded in 276 monitoring wells in Taiwan. Most coseismic falls appeared near the seismogenic fault as well as other active faults, while coseismic rises prevailed away from the fault. Coseismic groundwater level rises and falls correlated fairly well with hypocentral distance in the vicinity of the thrust fault. We found a major difference of coseismic changes in wells of different depths at most multiple-well stations. The recovery process of coseismic groundwater level changes is associated with the confining condition of the aquifer. Cross-formational flow is likely to play an important role in groundwater level changes after the earthquake. In the hanging wall of the thrust fault, an abnormal decline of groundwater level was observed immediately before the earthquake. The underlying mechanism of the unique preseismic change warrants further investigation.     

山西大同镇川井水位各类异常特征与成因分析

对观测环境、观测仪器、地震等各类因素在镇川井水位动态中所表现出的特征进行系统地分析与研究。根据地下水干扰异常识别与排除的原则,探讨了2007年至2012年镇川井水位出现各类异常的成因,并对研究时段的异常进行分类。研究结果表明,影响镇川井水位动态变化的主要因素有仪器故障、通讯故障、电源干扰、检修线路、维修仪器、泄流口排水管堵塞、雷电干扰、供电故障以及同震阶跃等,异常形态主要有阶跃、突变和脉冲等。     

句容16井远大震同震效应的初步研究

通过分析江苏句容16井2001～2007年间几次远大震的同震效应现象,发现苏16井动水位和水温资料对震级大于Ms7．5,震中距800～5000km不等的远大震,有较明显的同震效应反映,且动水位和水温的同震阶变总是上升,幅值随震级的增大而增大,随震中距的增大而减小。本文对苏16井动水位和水温同震效应的同步变化机理进行了初步探讨。     

海南琼海加积井水温同震效应特征和机理初探

基于海南加积井数字化水温2007年1月-2010年4月震中距小于8 000 km、Ms≥7.8大震的同震响应资料,系统分析水温年月日正常动态特征,发现远震引起的水温同震效应特征为上升脉冲,与以往的非自流井水温同震效应以下降为主的认识不一致;水温变化幅度与震中距、震级有一定关系,加积井水温同震效应成因,可用“层内混合”作...     

地震地下水动态研究中的若干问题

综合分析了近年来国内外地震地下水研究中的一些热点问题, 包括地下水动态影响因素及其相关的数据处理方法、水位同震响应及机理解释、水温同震响应及其机理、地下水反映的断层活动低频信息几个方面, 探讨了地震地下水位变动与应力应变的关系, 展望了地震地下水研究的发展方向.