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1.
侵蚀作用诱发的黄土滑坡是黄土高原区域内一种主要的滑坡类型,对其破坏机制开展深入研究具有重要实际意义。以陕西省耀州区的庵里滑坡为例,对该类黄土滑坡的发生机制进行分析和探讨,建立了滑坡发生前侵蚀作用的不同阶段边坡的有限元模型,计算了相应的应力场和位移场,在此基础上求得各模型沿最终滑面上的正应力、剪应力和抗剪强度分布,采用极限平衡法计算边坡整体稳定系数。结果表明,随着侵蚀作用的不断加深,沿滑动面上的剪应力增大,抗剪强度减小,整体稳定性降低至最终破坏。试验结果表明,小的应变在饱和黄土中会产生显著的超孔隙水压力,因此,基岩面上饱和滑带中的超孔隙水压力加剧了该类滑坡的发生。比较滑面上的剪应力和抗剪强度发现,自前滑坡破坏从坡脚开始,向后逐步扩展,表明该类滑坡具有牵引式破坏特点。 相似文献
2.
本文分析了凤凰山矿田构造复合时序,厘定出D4及D5两期构造变形作用为主要的成岩成矿构造,确定了区内成矿构造应力场的最大剪应力方向为NNE向。在此基础上,建立数值模型,进行同成矿构造应力场的数学模拟。初步得出,矿田内岩体接触带边缘及两侧的韧性剪切带为应力、应变及变形能的异常密集处,在多组构造复合处应力得以调整形成应力低,有利成矿部位必须对应剪应力变化梯度较大处,在此基础上,进行了成矿预测。 相似文献
3.
2006年4月以来, 四川长宁、兴文、珙县交界区域相继出现注水诱发地震活动, 至2013年4月30日共发生M L4.0以上地震16次, 最大为2013年4月25日M L5.2地震.通过采用体波谱振幅相关系数方法研究长宁注水诱发地震序列M L3.0以上地震震源机制变化过程, 结果显示序列震源机制散乱; 利用CAP方法计算了序列中M L4.0以上12次地震的震源机制解, 结果同样表明其机制紊乱.分析认为: 钻孔加压注水引起附近岩体的孔隙压力增大及先存断层面的摩擦系数减小, 这2种变化均导致库仑应力变化Δσ f增大, 从而促进地震的发生.因此, 注水诱发地震活动期间, 研究区构造应力场的应力强度无明显增强, 对破裂方向也无明显的约束作用, 故地震序列震源机制发散. 相似文献
4.
位于长江中下游铁铜成矿带铜陵聚矿区的狮子山矿田,大部分矿床的主矿体具有顺层产出的特点,故有“多层楼”之称,本文在对狮子山矿田构造要素进行详细观测的基础上,进行了构造变形系统时序与形成机制的研究及构造复合效应的分析,重点对顺层滑动构造的特点和成因进行了较深入的剖析,认为狮子山矿田矿床的主要构造控制因素是多层顺层滑动,从而较合理地解释了该矿田的矿床在空间上呈“多层楼”分布的特征。 相似文献
5.
大量的野外观察和实验研究表明,高应变速率的变形作用会在岩石中留下特殊的构造特征。地震作为一种断层快速破裂变形行为,在其作用过程中会使震源及邻近岩石变形从而产生一些特征构造及矿物相组合。剥露地表的断裂带为研究地震相关变形及过程提供了很好的物质材料。识别其中的地震滑动标志,对于确定古地震事件及其发生的机制具有重要意义。Cowan(1999)将断层快速滑动摩擦使得断层面岩石熔融产生的假玄武玻璃作为断层中记录地震滑动的唯一可靠的标识。近年来断裂岩研究取得的一系列重大进展揭示,断层发生地震滑动造成的多种构造产物均可记录其滑动的信息,如碳酸岩和含水硅酸岩的脱挥发分作用、微量元素迁移特征、有机质成熟度、断层镜面构造、液化粒状流、碎屑-皮层集合体、同震晶体塑性变形以及非晶质物质等。此外,与地震破裂传播有关的、在极端瞬态应力条件下形成的,如注入脉、碎粉化作用等特征也可以作为地震发生的岩石记录。因此假玄武玻璃不再是地震破裂的唯一指示物。断层滑动速率在10–4~101 m/s范围内几乎都是动态的,也就是说在实验中10–4 m/s的滑动速率可能指示着地震滑动。本文总结地震滑动和破裂的岩石记录,对认识地震发生机制和完善地震断裂理论具有极其重要的意义。 相似文献
6.
岷江上游的大、小海子是两个相连的地震滑坡、崩塌堰塞湖。几十年来对湖泊东岸较场镇台地的认识不一,其岸坡稳定问题是利用该天然湖泊建设水电站的关键。通过现场调查与钻探、测试,发现岷江上游的较场台地是一个向岷江凸出的、1万a前形成的湖相沉积台地。1933年,在强烈地震作用下,较场台地发生了强烈裂陷,未发生大规模的滑移,在台地上形成了两组近于垂直的地裂缝。进一步研究表明,这两组地裂缝虽然是在同一诱发因素下,在同一时间、同一地点形成的,但它们的形成机制却不同。一组走向近SN,是在强烈地震作用下,追踪岩体中原有的两组构造节理进一步裂开的产物,可称为地震构造追踪型地裂缝;另一组走向近EW,是顺向边坡中的层状岩体,在地震作用下沿软弱层发生层间滑动,地面被拉开、沉陷而形成的,可称为地震层间滑动型地裂缝。两种类型的地裂缝与层面的空间组合,控制着台地的稳定与演化。特别是当遇到类似1933年那样的地震,甚至由于两种地震地裂缝与层间错动面的存在,不需要那么高强度的地震,就可能诱发大规模的边坡稳定问题。这应该引起天龙湖水电站与213国道等管理部门的重视。 相似文献
7.
江汉盆地江陵凹陷内的高温高压高盐度卤水,富含钾、锂、硼、溴、碘、铷、铯等,达到工业品位或超过综合利用品位,构成富钾锂卤水矿,长期以来其矿体定位一直是难题,对于钾锂卤水的富集与矿田构造的关系还没有完全查清。本研究以现代矿田地质学为指导,以地球物理勘探、钻井和野外地质等资料为基础,综合分析江陵富钾锂卤水的矿田建造、矿田构造与矿田成矿作用。江陵凹陷富钾锂卤水矿田建造分为构造沉积岩相矿田和构造火山岩相矿田。江陵凹陷内各地区由于受所处构造位置的影响,在不同时期发育了不同类型的局部构造,这些局部构造在空间上有序的分布与叠置形成了大量的构造圈闭,为钾锂卤水的聚集提供了有利的场所。从古新世沙市组到早始新世新沟嘴组沉积时期,江汉盆地的古气候条件总体为高温干旱,利于古盐湖的蒸发作用,火山活动带来丰富的钾锂物质,从而利于钾锂卤水的富集。江陵凹陷富钾卤水属构造—储层耦合成藏模式:江陵凹陷盐湖沉积特征,决定了有大量卤水储存在其地层中。这些卤水最大的储集体就是砂岩孔隙,而构造产生的大量裂缝大部分位于泥岩和火成岩中,也成为储集卤水的场所。在构造褶皱及埋藏作用下,卤水开始从盐类晶间,首先进入砂岩体孔隙内,而后可能进入裂隙系统及火山岩系统。 相似文献
8.
沃克巷是西部大盆地中NW向延伸的地带,长700km,宽100-300km.Krantz的奇数轴模式被用来建立内华达西部沃克巷中沃克湖和Excelsior-Coaldale两构造片的三维应变模型。地震震源机制断层/辅助平面与航天飞机成像雷达-B(SIR-B)图像上的一条构造线平行或近于平行。地震震源机制表明Excelsior-Coaldale构造片断层为走向滑动,而沃克湖构造片断层以倾向滑动为主。三 相似文献
9.
系统查阅谷德振先生的生前论著,发现他不仅是国内外著名的工程地质学家,而且还是我国工程地震研究的开拓者。早在治淮工程开始就注意工程建设中的地震问题,1959年新丰江水库诱发地震后,特别关注工程地震问题,提出了工程区域地震稳定性评价的科学思路与技术方法,提出了活动断层的新概念,建议把晚更新世以来活动断裂称为活断层,并提出了从区域构造发展历史出发识别活断层的方法,提出了水库诱发地震是水库水体荷载与沿断裂带库水下渗引起的强度弱化和孔隙压力共同作用的科学观点等。他把上述观点、思路与方法,成功应用到新丰江水库诱发地震治理、葛洲坝工程与丹江口工程坝址勘选等一系列重大工程实践之中。 相似文献
10.
九寨沟余震序列的震源机制和构造应力场有助于认识本次地震的发震构造和孕震机理。本文基于四川区域地震台网的波形资料, 采用波形拟合(CAP)方法和P波初动+振幅比(HASH)方法反演得到2017年8月8日九寨沟7.0级地震序列中59次ML≥3.0地震的震源机制解, 并基于该结果采用阻尼线性逆推法(DRSSI), 计算研究区域的平均构造应力场, 给出该区域的应力场特征。结果显示, 利用CAP方法反演得到的本次主震的最佳双力偶机制解节面I: 走向248°/倾角86°/滑动角–169°, 节面II: 走向157°/倾角79°/滑动角–4°, 矩震级为Mw6.31, 矩心深度5 km, 属走滑型地震事件; 大部分余震的震源机制解错动类型与主震一致, 矩心深度集中在3~10 km; 应力场反演结果显示, 该区域周边的应力性质为走滑型, 最大主应力方向呈NWW–SEE向, 与该区域的应力场方向一致, 表明本次地震主要受区域应力的控制。结合该区域的地震地质构造等已有研究成果, 分析认为此次地震的发震断层为走向NW–SE、倾向SW的左旋走滑断裂——树正断裂, 巴颜喀拉块体向E-SE向的水平运动受到华南块体的强烈阻挡导致此次地震的发生, 汶川地震的发生对本次地震具有一定的促进作用。 相似文献
11.
Changes in seismic activity have been related to the filling of large reservoirs in over thirty cases. These changes range from variations in the level of micro-earthquake activity detectable only with instruments of high sensitivity to destructive earthquakes with magnitudes greater than 6. On the other hand, the filling of many other large reservoirs has not been accompanied by increased seismicity. A number of factors may contribute to the generation or absence of post-impounding seismicity. Increased vertical stress due to the load of the reservoir and decreased effective stress due to increased pore pressure can modify the stress regime in the reservoir region. Whether or not these stress changes are sufficient to generate earthquake activity will depend on a complex interaction of the induced stress with the state of pre-existing stress near the reservoir, and on the geologic and hydrologic conditions at the site. The combined effect of increased vertical load and increased pore pressure will have the greatest tendency to increase activity in regions where the maximum compressive stress is vertical (normal faulting). In regions where the minimum compressive stress is vertical (thrust faulting) increased stress due to a vertical load should have a minimum effect. For all of the larger reservoir-induced earthquakes the stress system determined from fault plane solutions is in agreement with the pre-existing stress field in the region of the reservoir. These earthquakes are all of strike-slip or normal type, there being no reported cases of large induced earthquakes with thrusting mechanisms. The potential for major changes in seismicity may be highest in regions of moderate strain accumulation (low to moderate natural seismicity). In areas of high strain accumulation and high levels of natural seismicity, the stress changes induced by the reservoir will be small compared to natural variations. In aseismic areas, with low strain accumulation, the reservoir-induced stresses may be insufficient to raise the stress level to a state of failure. 相似文献
12.
In order to adopt the best safety procedures, man-made earthquakes should be differentiated as a function of their origin. At least four different types of settings can be recognized in which anthropogenic activities may generate seismicity: (I) fluid removal from a stratigraphic reservoir in the underground can trigger the compaction of the voids and the collapse of the overlying volume, i.e., graviquakes; the deeper the reservoir, the bigger the volume and the earthquake magnitude; (II) wastewater or gas reinjection provides the reduction of friction in volumes and along fault planes, allowing creep or sudden activation of tectonic discontinuities, i.e., reinjection quakes; (III) fluid injection at supra-lithostatic pressure generates hydrofracturing and micro-seismicity, i.e., hydrofracturing quakes; (IV) fluid extraction or fluid injection, filling or unfilling of artificial lakes modifies the lithostatic load, which is the maximum principal stress in extensional tectonic settings, the minimum principal stress in contractional tectonic settings, and the intermediate principal stress in strike-slip settings, i.e., load quakes; over given pressure values, the increase of the lithostatic load may favour the activation of normal faults, whereas its decrease may favour thrust faults. For example, the filling of an artificial lake may generate normal fault-related seismicity. Therefore, each setting has its peculiarities and the knowledge of the different mechanisms may contribute to the adoption of the appropriate precautions in the various industrial activities. 相似文献
13.
Theories of the physical processes leading to the stimulation of seismic activity by underground explosions, fluid injection, and reservoir impoundment are summarized. In all cases, the materials must be pre-stressed to a substantial fraction of their breaking strength in order for seismicity to be induced. Stress concentrations due to the presence of old faults or to inhomogeneities in the material properties play an important role in localizing induced seismicity. For the few cases for which data are available, the stimulation of earthquakes by fluid injection in bore holes is adequately explained by a Coulomb-Mohr failure criterion and the concept of effective pressure in a water-filled porous mechanism. Reservoir-related earthquakes are most likely due to the same mechanism, but, in view of the low injection pressures, additional physical or chemical effects of the water on the materials may play an important role. There may be a weakening of the materials in old fault zones by the introduction of water or static fatigue in silicate rocks due to stress corrosion. 相似文献
14.
A growing body of evidence suggests that fluids are intimately linked to a variety of faulting processes. Yet, the particular mechanisms through which fluids and associated parameters influence the stress regime and thus the seismicity of a particular area are not well understood.We carry out a study of the spatio-temporal behavior of earthquakes, fluid-related parameters (groundwater levels) and meteorological observables (precipitation) in the swarm earthquake area of Bad Reichenhall, southeastern Germany. The small volume in which the earthquakes take place, almost yearly occurring earthquake swarms and a permanent, seismo-meteorological monitoring network, provide nearly controlled experimental conditions to study the physics of earthquake swarms and to infer characteristic properties of the seismogenic crust.In this paper we (1) describe this fairly unique study area in terms of geology, seismicity and atmospheric conditions; (2) present two cases of earthquake swarms that seem to follow above-average rainfall events; and (3) examine the observed migration of hypocenters with a simple pore pressure diffusion model.We find significant correlation of seismicity with rainfall and groundwater level increase, and estimate an average hydraulic diffusivity of D = 0.75 ± 0.35 m 2/s for Mt. Hochstaufen in 2002. 相似文献
15.
CO 2 capture and storage projects must consider the potential possibility ofinjection induced seismicity. Moderate earthquakes and strong earthquakes may endanger human life and property, and even felt earthquakes and microquakes also pose a threat to seal integrity of CO 2 reservoir and increase the risk of leakage. Underground fluid injection induced seismicity usually happens in some geoengineering projects such as waste fluid disposal, EOR and EGS, and it occurs when fluid is injected along the fault. Therefore, it can be studied through stress analysis. The density of supercritical CO 2 is smaller than water, which may develop density flow in the deep strata or water-rock interactions in pre-existing structures, and cause the variation in permeability and pressure to induce a seismic activity. In this paper, we reviewed the mechanism of underground fluid injection induced seismicity with the focus of CCS, combined with fluid injection projects and seismic monitoring analysis in both commercial scale and experimental scale, to investigate its impact on the integrity of the cap rock of the reservoir. Finally, we summarized the appropriate site selection, injection methods and monitoring programs to prevent the occurrence of induced seismicity. 相似文献
16.
Lower crustal earthquake occurrence in the Central Indian Tectonic Zone(CITZ) of the Indian sub-continent was investigated using magnetotelluric(MT) data. MT models across the CITZ, including the new resistivity model across the 1938 Satpura lower crustal earthquake epicenter, show low resistive(80 ?m) mid-lower crust and infer small volume(1 vol%) of aqueous fluids existing in most part of lower crust. This in conjunction with xenoliths and other geophysical data supports a predominant brittle/semi-brittle lower crustal rheology. However, the local deep crustal zones with higher fluid content of 2.2%–6.5% which have been mapped imply high pore pressure conditions. The observation above and the significant strain rate in the region provide favorable conditions(strong/moderate rock strength, moderate temperature, high pore pressure and high strain rate) for brittle failure in the lower crust. It can be inferred that the fluid-rich pockets in the mid-lower crust might have catalyzed earthquake generation by acting as the source of local stress(fluid pressure), which together with the regional stress produced critical seismogenic stress conditions. Alternatively, fluids reduce the shear strength of the rocks to favor tectonic stress concentration that can be transferred to seismogenic faults to trigger earthquakes. 相似文献
17.
The filling of the Koyna reservoir in western India and the associated triggered earthquakes have been well documented. Several studies have suggested that earthquakes are triggered on pre-existing faults in the region due to changes in pore pressure caused by pore pressure diffusion. To study in-situ pore pressure variations twenty-one borewells were drilled in the Koyna-Warna region under an Indo-German research program during 1995–1998. In most of these wells tidal signals are observed in well level variations indicating sensitivity to small strain changes in hydraulically connected, confined aquifers. Those signals, hence, are suitable to reflect variations in the stress field of local rock formations. More than a decade of well level monitoring has shown four types of earthquake related changes. The pre- and post-earthquake changes are mostly interpretative in nature and difficult to substantiate. The co-seismic and transient changes which are observed for local and large teleseismic events are well established. Wells connected to unconfined aquifers also showed changes related to seismicity in case of large magnitude earthquakes at closer distances. Some anomalous water level fluctuations are seen which are not associated with local or teleseismic earthquakes. These changes are coherent in nature and reflect aseismic regional volume strain. 相似文献
18.
The association between fluid injection and seismicity has been well documented and widely publicized. Less well known, but probably equally widespread are faulting and shallow seismicity attributable solely to fluid extraction, particularly in association with petroleum production. Two unequivocable examples of seismicity and faulting associated with fluid extraction in the United States are: The Goose Creek, Texas oil field event of 1925 (involving surface rupture); and the Wilmington, California oil field events (involving subsurface rupture) of 1947, 1949, 1951 (2), 1955, and 1961. Six additional cases of intensity I–VII earthquakes (M < 4.6) without reported faulting may be attributable to shallow production from other large oil and gas fields. In addition to these examples are thirteen cases of apparently aseismic surface rupture associated with production from California and Texas oil fields. Small earthquakes in the Eloy—Picacho area of Arizona may be attributable to withdrawal of groundwater, but their relation to widespread fissuring is enigmatic. The clearest example of extraction-induced seismicity outside of North America is the 1951 series of earthquakes associated with gas production from the Po River delta near Caviga, Italy. Faulting and seismicity associated with fluid extraction are attributed to differential compaction at depth caused by reduction of reservoir fluid pressure and attendant increase in effective stress. Surface and subsurface measurements and theoretical and model studies show that differential compaction leads not only to differential subsidence and centripetally-directed horizontal displacements, but to changes in both vertical- and horizontal-strain regimes. Study of well-documented examples indicates that the occurrence and nature of faulting and seismicity associated with compaction are functions chiefly of: (1) the pre-exploitation strain regime, and (2) the magnitude of contractional horizontal strain centered over the compacting materials relative to that of the surrounding annulus of extensional horizontal strain. The examples cited include natural systems strained only by extraction of fluids, as well as some subsequently subjected to injection. Faulting and seismicity have accompanied both decrease and subsequent increase of fluid pressures; reversal of fluid-pressure decline by injection may enhance the likelihood of subsurface faulting and seismicity due chiefly to earlier fluid pressure reduction. A consistent common denominator appears to be continuing compaction at depth; the relative effects of fluid extraction followed by injection are not easily separated. 相似文献
19.
自2002年7月温州珊溪水库首次发生地震后,其地震活动持续至今,但目前人们对水库地震成因了解较少.基于对库区所处的区域地震地质背景、库区地形地貌、岩性及新构造运动特征的分析,采用野外地质调查的方法,获得了库区主要断层的地质特征,并评价了其渗透性.在此基础上,结合地震活动特征及震源机制解的研究成果,探讨了水库地震时间序列及发震机理.结果表明珊溪水库地震活动与库区岩性、断层(尤其是库区内的双溪-焦溪垟断层)及库水特征关系密切.水库地震主要发生在侏罗系凝灰岩夹砂岩、泥岩等隔水性好的层状岩层中,而渗透性较好的双溪-焦溪垟断层结构面则更利于库水下渗,这种岩体结构面组合方式一方面使库水容易沿断层结构面向深部渗透,另一方面断层结构面上的孔隙压力容易升高,因此降低了断层结构面上的正应力,应力平衡被打破,进而诱发地震.在水的渗透和地震活动的相互作用下,水库地震沿双溪-焦溪垟断层(尤其是第三分支断层)从SE向NW持续发生. 相似文献
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