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1.
Yeeping Chia Jessie J. Chiu Yi-Hsuan Chiang Tsai-Ping Lee Chen-Wuing Liu 《Pure and Applied Geophysics》2008,165(1):5-16
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
Mw 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. 相似文献
2.
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。 相似文献
3.
Masao Ohno Tsutomu Sato Kenji Notsu Hiroshi Wakita Kunio Ozawa 《Pure and Applied Geophysics》2006,163(4):647-655
Anomalous water level changes were observed at two wells associated with seismic swarm activity off Izu Peninsula on March,
1997. These are coseismic water level drops followed by gradual postseismic water level rise at the time of large earthquakes
during the swarm activity. The post-seismic water level rises, which can be fitted by an exponential function with a time
constant of about six hours, are explained in terms of the horizontal pressure diffusion due to the pressure gradient in the
aquifer induced by the coseismic static strain. 相似文献
4.
许多地下流体监测井在地震发生时都能记录到同震水位变化,而利用地下水位的同震响应特征以及水位固体潮效应可以反演地震对含水层产生的体应变量.本文尝试从大尺度上对大地震引起的体应变变化进行研究,为此收集了位于我国大陆不同构造活动区5口地下流体监测井两年半的水位数据资料进行分析,去除干扰项,提取出水位固体潮成分,进行调和分析求取潮汐因子,并反演出汶川MS8.0地震对这5口井所在含水层产生的体应变量.结果显示,汶川大地震对这5口井 含水层造成的体应变量基本在10-7量级. 地震引起的体应变随距离的衰减规律比较复杂,其不仅与震中距有关,而且与活动断裂带的展布和地壳岩体结构等密切相关. 相似文献
5.
Tsai-Ping Lee Yeeping Chia Hsin-Ying Yang Ching-Yi Liu Yung-Chia Chiu 《Pure and Applied Geophysics》2012,169(11):1947-1962
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. 相似文献
6.
The study on coseismic step-like changes of water-level is of theoretical and practical significance to the mitigation of secondary hazards, identification of earthquake precursors, tracking of the subsequent shocks, and the research of crustal activity (Nur and Booker, 1972; WANG et al, 1988). A lot of researches have been done by previous geoscientists. Among them, ZHANG et al (1994) inverted stress variation in the aquifers through the analysis of coseismic step-like changes of well water level. LI (1995), WANG (2000), and FU et al (2002) studied the relationship between coseismic step-like changes of water level and future seismic activity. HUANG et al (2000) investigated the water-level changes in many wells after the occurrence of one great earthquake. However,the analysis of the quantitative relation between the coseismic step-like changes of water level and earthquakes in China has not been reported so far. This paper describes the coseismic step-like changes of water level in the Dazhai well, Simao city, Yunnan Province, and tries to discuss the possible mechanism of these changes. 相似文献
7.
Some isotopic and hydrological changes associated with the 1999 Chi-Chi earthquake, Taiwan 总被引:1,自引:0,他引:1
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. 相似文献
8.
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MW9.0地震、2012年苏门答腊MW8.6地震和2015年尼泊尔MW7.8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。 相似文献
9.
Coseismic responses of groundwater levels in the Three Gorges well-network to the Wenchuan MS8.0 earthquake 下载免费PDF全文
We systematically analyze coseismic responses and post-seismic characteristics of groundwater levels in the Three Gorges well-network to the MS8.0 Wenchuan earthquake on 12 May 2008. The results indicate that these characteristics differ among wells. On the conditions of similar borehole configurations, the differences are associated with geological structural sites of wells, burial types of aquifers monitored, and transmissivities of aquifer systems. We explored coseismic and post-seismic step-rise and step-drop mechanical mechanisms and their implication to earthquake prediction. We validated the inference that the residual step-rise zone is a possible earthquake risk zone based on recent seismic activity on the Xiannüshan fault in the area. 相似文献
10.
11.
介绍了信宜1、2号井水文地质环境,总结了近年来两井水温的同震响应现象,并对其机理进行了初步的探讨。认为两口井的同震响应虽然形态不一致,但机理是相近的,主要是由于地震波的扰动,随着振动效应的作用,加大了不同含水层间的垂直运动速率,而产生水温上升或下降现象,震后一段时间随着混合通道的闭合或运动速率的恢复,2号井的水温逐渐恢复到原有的水平上。 相似文献
12.
13.
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。 相似文献
14.
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 总被引:6,自引:0,他引:6
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 相似文献
15.
Characteristics of coseismic water level changes at Tangshan well for the Wenchuan MS8.0 earthquake and its larger aftershocks 下载免费PDF全文
Baojun Yin Li Ma Huizhong Chen Jianping Huang Chaojun Zhang Wuxing Wang 《地震科学(英文版)》2009,22(2):149-157
Coseismic water level changes which may have been induced by the Wenchuan MS8.0 earthquake and its 15 larger aftershocks (MS≥?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. MS magnitude has the strongest correlation with the coseismic water level changes comparing to MW and ML 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. 相似文献
16.
Active faults are commonly associated with spatially anomalously high concentrations of soil gases such as carbon dioxide
and Rn, suggesting that they are crustal discontinuities with a relatively high vertical permeability through which crustal
and subcrustal gases may preferably escape towards the earth's surface. Many earthquake-related hydrologic and geochemical
temporal changes have been recorded, mostly along active faults especially at fault intersections, since the 1960s. The reality
of such changes is gradually ascertained and their features well delineated and fairly understood. Some coseismic changes
recorded in ``near field' are rather consistent with poroelastic dislocation models of earthquake sources, whereas others
are attributable to near-surface permeability enhancement. In addition, coseismic (and postseismic) changes were recorded
for many moderate to large earthquakes at certain relatively few ``sensitive sites' at epicentral distances too large (larger
for larger earthquakes, up to 1000 km or more for magnitude 8) to be explained by the poroelastic models. They are probably
triggered by seismic shaking. The sensitivity of different sites can be greatly different, even when separated only by meters.
The sensitive sites are usually located on or near active faults, especially their intersections and bends, and characterized
by some near-critical hydrologic or geochemical condition (e.g., permeability that can be greatly increased by a relatively
small seismic shaking or stress increase). Coseismic changes recorded for different earthquakes at a sensitive site are usually
similar, regardless of the earthquakes' location and focal mechanism. The sensitivity of a sensitive site may change with
time. Also pre-earthquake changes were observed hours to years before some destructive earthquakes at certain sensitive sites,
some at large epicentral distances, although these changes are relatively few and less certain. Both long-distance coseismic
and preseismic changes call for more realistic models than simple elastic dislocation for explanation. Such models should
take into consideration the heterogeneity of the crust where stress is concentrated at certain weak points (sensitive sites)
along active faults such that the stress condition is near a critical level prior to the occurrence of the corresponding earthquakes.
To explain the preseismic changes, the models should also assume a broad-scaled episodically increasing strain field. 相似文献
17.
2011年3月11日的日本Mw9.0地震在中国引起了大范围的井水温度同震变化,而水温震后持续变化的井孔多数分布在井网密度较大、距震中较近的环渤海地区。本文分析了环渤海地区水温震后变化的特征和机理。结果表明,水温震后变化形态为上升,变幅0. 005~0.976°C,空间分布在同震位移较大、张性应变较明显和地震能量密度较大的区域;依据同井水位资料,一些井孔的水温和水位震后变化特征较一致,其水温震后升高可能是地震波增大含水层渗透性的结果;另一些井孔的水位震后变化不显著,其水温震后升高可能与地震波增大井区大地热流有关。 相似文献
18.
海南琼海加积井水温同震效应特征和机理初探 总被引:2,自引:1,他引:1
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... 相似文献
19.
金沙江水网对日本9.0级地震的同震响应及其特征与机理 总被引:1,自引:0,他引:1
本文系统介绍了金沙江水网6口观测井水位与水温动态对日本9.0级地震的同震响应, 分析了同震响应的特征与同震响应的机理。 结果表明, 4口井水位有同震响应, 同震响应形态全是振荡, 对地震波响应的时间、 振荡的幅度、 振荡的持续时间等的差异主要取决于井-含水层系统的导水系数。 结果还表明, 3口井水温有同震响应, 响应形态是不对称的V字或U字形; 水温的先期下降是井筒内上(冷)下(热)水混合作用引起的, 后期上升是井水与围岩之间的热传导引起吸热作用的结果, 各井水温升降的幅度、 持续时间等不同, 主要是井水温度梯度与水岩热传导系数不同引起的; 后期升幅总是大于先期降幅, 这可能与地震波作用使井区大地热流增强有关。 相似文献
20.
地震地下流体已成为一种重要的地震监测手段。 本文分析夏垫断裂带上观测井的同震响应特征, 探讨观测井水位、 水温同震变化对夏垫断裂带的影响机理, 收集和整理布设在夏垫断裂带上的赵各庄井和西集井两口观测井水位和水温同震响应资料, 从响应的地震次数及发震位置、 异常幅度、 时间和形态类型等方面对其响应特征进行分析, 从震中距、 震级和井-含水层岩性等方面探讨了地下流体地震前兆异常的成因。 结果显示, 赵各庄井和西集井水位地震响应能力强于水温, 响应形态以振荡型为主, 对于MS7.0以上地震具有显著的映震能力。 在水温资料中, 仅有赵各庄井对2008年汶川MS8.0地震有响应, 响应幅度为0.0129℃。 综合分析认为, 井-含水层岩性影响了两井同震响应形态特征, 远场大地震产生的动态应变导致了较大的水位变幅。 相似文献