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1.
The mechanism of postseismic deformation related to strong earthquakes is important in geodynamics, and presumably afterslip
or viscoelastic relaxation is responsible for the postsesimic deformation. The 1999 Chi-Chi, Taiwan of China, earthquake occurred
in the region where GPS observation station is most densely deployed in the world. The unprecedented GPS data provides a unique
opportunity to study the physical processes of postseismic deformation. Here we assume that the interactions of viscoelastic
relaxation, afterslip, fault zone collapse, poroelastic rebound, flow of underground fluids, and all these combined contribute
to the surface displacements following the main shock. In order to know the essence of the postseismic deformation after the
strong event, fault zone collapse, poroelastic rebound, flow of underground fluids, and so on, are represented equivalently
by the variations of the focal medium properties. Therefore, the viscoelastic relaxation, afterslip, and the variations of
the equivalent focal medium properties are inverted by applying the GPS temporal series measurement data with viscoelastic
finite element method. Both the afterslip rate distribution along the fault and the afterslip evolution with time are obtained
by means of inversion. Also, the preliminary result suggests that viscosities of the lower crust and the upper mantle in Taiwan
region is 2.7×1018 and 4.2×1020 Pa·s, respectively. Moreover, the inversion results indicate that the afterslip contributing to postseismic deformation of
44.6% in 450 days after the Chi-Chi earthquake, with 34.7% caused by the viscous relaxation and 20.7% by other factors such
as fault zone collapse, poroelastic rebound, and the flow of liquids. 相似文献
2.
1999年台湾集集地震震后450天的GPS观测资料显示了几十到几百毫米的地表位移.下地壳的震后黏性松弛和断层无震蠕变产生的震后滑动是用来解释地表震后变形的两个主要机制.本文利用接触问题的黏弹性有限元(LDDA)方法,以GPS观测数据作为约束,分别考察了黏性松弛和震后滑动机制对地表震后变形的影响.计算结果表明,黏性松弛机制产生的地表位移与观测数据吻合较好,通过试错法由震后GPS观测约束得到的下地壳黏度为1017Pa·s,而上地幔黏度对计算结果影响不大.考察震后滑动机制对地表变形的影响时,在LDDA方法中结合了速率状态摩擦定律,结果显示震后滑动机制不能很好地解释震后450天的观测数据,它产生的地表变形只在震后50天内与观测大致吻合,之后位移值基本不随时间变化.这些结果有助于增进对集集地震震后变形机制的认识. 相似文献
3.
Rapid afterslip and short-term viscoelastic relaxation following the 2008 M_W7.9 Wenchuan earthquake
Zhigang Shao Rongjiang Wang Yanqiang Wu Langping Zhang Institute of Earthquake Science China Earthquake Administration Beijing China GFZ German Research Center for Geosciences D- Potsdam Germany 《地震学报(英文版)》2011,(2):163-175
Significant postseismic deformation of the 2008 M W 7.9 Wenchuan earthquake has been observed from GPS data of the first 14 days after the earthquake. The possible mechanisms for the rapid postseismic deformation are assumed to be afterslip on the earthquake rupture plane and viscoelastic relaxation of coseismiclly stress change in the lower crust or upper mantle. We firstly use the constrained least squares method to find an afterslip model which can fit the GPS data best. The afterslip model can explain n... 相似文献
4.
Christopher Rollins Sylvain Barbot Jean-Philippe Avouac 《Pure and Applied Geophysics》2015,172(5):1305-1358
Due to its location on a transtensional section of the Pacific-North American plate boundary, the Salton Trough is a region featuring large strike-slip earthquakes within a regime of shallow asthenosphere, high heat flow, and complex faulting, and so postseismic deformation there may feature enhanced viscoelastic relaxation and afterslip that is particularly detectable at the surface. The 2010 \(M = 7.2\) El Mayor-Cucapah earthquake was the largest shock in the Salton Trough since 1892 and occurred close to the US-Mexico border, and so the postseismic deformation recorded by the continuous GPS network of southern California provides an opportunity to study the rheology of this region. Three-year postseismic transients extracted from GPS displacement time-series show four key features: (1) 1–2 cm of cumulative uplift in the Imperial Valley and \(\sim\)1 cm of subsidence in the Peninsular Ranges, (2) relatively large cumulative horizontal displacements \(>\)150 km from the rupture in the Peninsular Ranges, (3) rapidly decaying horizontal displacement rates in the first few months after the earthquake in the Imperial Valley, and (4) sustained horizontal velocities, following the rapid early motions, that were still visibly ongoing 3 years after the earthquake. Kinematic inversions show that the cumulative 3-year postseismic displacement field can be well fit by afterslip on and below the coseismic rupture, though these solutions require afterslip with a total moment equivalent to at least a \(M = 7.2\) earthquake and higher slip magnitudes than those predicted by coseismic stress changes. Forward modeling shows that stress-driven afterslip and viscoelastic relaxation in various configurations within the lithosphere can reproduce the early and later horizontal velocities in the Imperial Valley, while Newtonian viscoelastic relaxation in the asthenosphere can reproduce the uplift in the Imperial Valley and the subsidence and large westward displacements in the Peninsular Ranges. We present two forward models of dynamically coupled deformation mechanisms that fit the postseismic transient well: a model combining afterslip in the lower crust, Newtonian viscoelastic relaxation in a localized zone in the lower crust beneath areas of high heat flow and geothermal activity, and Newtonian viscoelastic relaxation in the asthenosphere; and a second model that replaces the afterslip in the first model with viscoelastic relaxation with a stress-dependent viscosity in the mantle. The rheology of this high-heat-flow, high-strain-rate region may incorporate elements of both these models and may well be more complex than either of them. 相似文献
5.
2010年4月14日青海玉树MS7.1地震发生在青藏高原东南部甘孜-玉树地震带,在震后7~10天内,我们快速建立了由15个GPS测站组成的跨地震破裂带观测剖面,包括1个连续站,3个半连续站和11个流动站,对所有站进行了240多天的观测,获取了该次地震的震后形变时空特征.采用欧拉矢量和位错模型解算了背景速度场,并从GPS观测的形变场中扣除该分量.采用分层黏弹性位错模型计算余震引起的地表形变,结果表明余震对部分测站的位移造成不可忽视的影响.采用对数模型拟合位移时间序列,表明特征衰减时间为6.7±1.2天.利用最速下降法反演震后余滑时空分布,反演结果表明震后断层活动以左旋滑动为主,断层南盘具有少量的抬升.在空间分布上,余滑主要位于同震破裂区的两侧,西北侧的余滑几乎达到地表,而东南区的余滑基本在同震破裂区的下方,余滑最大的区域位于结古镇东南下方10~20 km的深度范围.随着震后离逝时间的增加,2个余滑区在空间上保持不变,余滑区的面积逐渐扩大.余滑的矩释放为(1.5~5.1)×1018Nm,相当于1个MW6.1~6.4地震释放的能量.分层岩石圈黏弹性模型计算的地壳孔隙弹性反弹形变与地表观测值相差较大,不能解释观测到的震后变形.采用麦克斯维尔流变体模型计算下地壳和上地幔松弛引起的地表形变,显示出其对地表形变的贡献较小.GPS观测得到的震后形变所具有的快速衰减特征,以及余滑模型能够较好地拟合GPS地表形变,表明2010年玉树MS7.1地震后早期阶段的地壳形变主要是由余滑机制决定的. 相似文献
6.
根据1990年青海共和地震震后地表垂直形变,通过模型拟合得到了支配共和地区震后形变场时空演化的形变源及其力学机制.分析穿过断层的震前1期和震后6期水准数据,结果表明震后垂直形变具有以下特征:①震后震区上盘继续发生继承性的大幅度上升,其中震后头一年上升速率最大;②震后上升区范围显著,范围随时间变化不大,但较同震形变上升区范围增大;③震后相邻测站高差观测值的时间序列明显具有对数衰减特征或指数衰减特征,衰减特征时间分别为0.165年和1.344年.本文还发展了一个利用水准数据与连续介质位错模型研究震后形变机制的新方法.该方法用相邻水准点之间的原始高差观测值而非它们相对参照点的积分值来约束连续介质位错模型,可以有效减少误差累积带来的偏差并充分利用观测数据.利用这一方法的初步分析结果表明,断层震后滑移和介质黏弹性松弛共同导致了共和地震震后形变.前者表现为发生在断层面及其延伸部分的滑移,特别是位于主破裂上方沉积层内的滑移;后者则表现为下地壳与上地幔内的黏弹性松弛,黏滞系数为1020Pa.s量级. 相似文献
7.
2010年智利马乌莱MW8.8地震发生在纳斯卡板块与南美板块的板块边界处,引起了显著的同震和震后效应。GPS台网数据显示记录到的同震海向位移最大约5 m,垂向沉降最大约50 cm。在经过对俯冲效应、季节变化等效应的校正后,震后6年的海向最大位移约68 cm,垂向抬升最大约20 cm。马乌莱地震显著的震后形变对该区域的地下三维黏弹性结构有良好的约束。本文建立了智利中南部俯冲带区域的三维有限元模型,黏弹性的地幔楔及海洋地幔均使用伯格斯体材料,并在断层面上设置2 km厚的软弱层以模拟震后余滑。在与GPS台站震后位移数据进行比较后,模拟结果表明,大洋地幔顶部存在约120 km厚,黏度为1×1019 Pa·s的软流圈。模拟震后余滑效应的软弱层黏度为5×1017 Pa·s,其等效震后余滑的最大值在震后前两年接近2 m,且随着时间的增长而快速衰减。 相似文献
8.
Relaxation of the coseismic stresses following an earthquake causes postseismic crustal deformation, which can last for days
to years. Continuous monitoring of postseismic deformation facilitates the understanding of the mechanism of deformation and
postseismic relaxation and viscous rheology. After the October 8, 2005 Kashmir earthquake, global positioning system data
for 8 months, starting from October, 2005 have been analyzed from three continuous sites located at Gulmarg, Amritsar, and
Jaipur. The average velocity during the observation period at Gulmarg (8.6 cm/year) is significantly higher than the Indian
plate velocity exhibiting postseismic crustal deformation. The velocity at Amritsar (5.9 cm/year) and Jaipur (5.1 cm/year)
is comparable to the Indian plate velocity. At Gulmarg, the logarithmic function fits well to the north–south component of
postseismic transients (~in the coseismic slip direction). The nature of decay in these transients suggests that the deformation
is mainly due to an afterslip, and the second possible contribution may be from the viscous relaxation process. This paper
presents the characteristics of postseismic transients and possible contributions from various postseismic mechanisms subsequent
to the Kashmir earthquake. 相似文献
9.
Using global positioning system (GPS) technology, significant postseismic surface displacements were observed within the first
4 months after the 2001 Mw 7.8 Kunlun earthquake which occurred in China. In this study, we investigated the mechanisms that
may have possibly contributed to the postseismic deformations that have been observed. Based on the modeling results, we find
that an afterslip model can interpret postseismic displacements in the near field even when the fault plane is extended to
the bottom of the crust (~70 km). Models based on the viscoelastic relaxation theory showed a large discrepancy in the spatial
pattern of the deformation compared with what has been observed. Thus, we infer that both mechanisms cannot interpret the
observed postseismic deformation independently. A combination of afterslip and viscoelastic relaxation can further improve
the data fit, especially at sites far from the fault. With maximum afterslip of ~0.4 m occurring at a depth of 10 km in the
central section, the combined model shows that the estimated afterslip occurred mostly on and below the coseismic rupture
plane, as well as on its eastern extension. The estimated moment released by the afterslip in the first 4 months is almost
40% of that released by the coseismic slip. The best-fitting viscoelastic relaxation model shows a “weak” upper mantle with
a viscosity of ~1.0 × 1018 Pa s. The combined model also suggests the existence of a lower crust with viscosity larger than 1.0 × 1018 Pa s, although it cannot be constrained accurately. 相似文献
10.
11.
Ya-Ju Hsu Jean-Philippe Avouac Shui-Beih Yu Chien-Hsin Chang Yih-Min Wu Jochen Woessner 《Pure and Applied Geophysics》2009,166(10-11):1853-1884
We use preseismic, coseismic, and postseismic GPS data of the 1999 Chi-Chi earthquake to infer spatio-temporal variation of fault slip and frictional behavior on the Chelungpu fault. The geodetic data shows that coseismic slip during the Chi-Chi earthquake occurred within a patch that was locked in the period preceding the earthquake, and that afterslip occurred dominantly downdip from the ruptured area. To first-order, the observed pattern and the temporal evolution of afterslip is consistent with models of the seismic cycle based on rate-and-state friction. Comparison with the distribution of temperature on the fault derived from thermo-kinematic modeling shows that aseismic slip becomes dominant where temperature is estimated to exceed 200° at depth. This inference is consistent with the temperature induced transition from velocity-weakening to velocity-strengthening friction that is observed in laboratory experiments on quartzo-feldspathic rocks. The time evolution of afterslip is consistent with afterslip being governed by velocity-strengthening frictional sliding. The dependency of friction, μ, on the sliding velocity, V, is estimated to be ${{\partial \mu }/{\partial \, {\rm ln}\, V}} = 8 \times 10^{ - 3}$ . We report an azimuthal difference of about 10–20° between preseismic and postseismic GPS velocities, which we interpret to reflect the very low shear stress on the creeping portion of the décollement beneath the Central Range, of the order of 1–3 MPa, implying a very low friction of about 0.01. This study highlights the importance of temperature and pore pressure in determining fault frictional sliding. 相似文献
12.
《地震研究进展(英文)》2021,1(1):100002
An improved understanding of postseismic crustal deformation following large subduction earthquakes may help to better understand the rheological properties of upper mantle and the slip behavior of subduction interface. Here we construct a three-dimensional viscoelastic finite element model to study the postseismic deformation of the 2014 MW8.1 Iquique, Chile earthquake. Elastic units in the model include the subducting slab, continental and oceanic lithospheres. Rheological units include the mantle wedge, the oceanic asthenosphere and upper mantle. We use a 2 km thick weak shear zone attached to the subduction fault to simulate the time-dependent stress-driven afterslip. The viscoelastic relaxation in the rheological units is represented by the Burgers rheology. We carry out grid-searches on the shear zone viscosity, thickness and viscosity of the asthenosphere, and they are determined to be 1017 Pa s, 110 km and 2 × 1018 Pa s, respectively. The stress-driven afterlsip within the first two years is up to ~47 cm and becomes negligible after two years (no more than 5 cm/yr). Our results suggest that a thin, low-viscosity oceanic asthenosphere together with a weak shear zone attached to the fault are required to better reproduce the observed postseismic deformation. 相似文献
13.
大地测量技术观测的震后变形是地壳和地幔岩石对同震应力扰动的变形响应,震后变形的强度及时空演化特征主要受断层面的摩擦性质、下地壳及上地幔岩石的流变参数等控制。震后大地测量被广泛用于研究断层及深部岩石的流变性质及其动力学过程,是对岩石力学实验、冰后回弹等手段探测结果的检验和补充。本文回顾性地总结了中国及邻域中强地震震后变形监测成效,这些震例主要集中在青藏高原内部和边界带。通过对包括昆仑山口西地震、汶川地震和尼泊尔地震在内的发生在青藏高原及周缘的强震震后变形机制、岩石圈流变参数约束等方面的研究,大大提升了对青藏高原不同区域深部岩石流变结构和性质的认识,为研究地震周期变形、地震危险性、青藏高原的形变模式、高原演化动力学提供了观测依据和定量参数。同时,指出进一步约束青藏高原深部岩石流变参数,一方面需要进一步提高西部地区连续GNSS监测能力,另一方面需要与地球物理成像技术进行融合。 相似文献
14.
1996年丽江MS7.0地震的余震深度分布明显具有时间依赖性,主震发生后短时间内余震震源深度较深,随着时间的延续,余震震源深度变得越来越浅。余震的这种深度分布受地壳脆塑性转化带深度控制,而脆塑性转化带的深度变化与地震前后断层的应变速率有关。由震后GPS地表变形数据得到的地表变形模型表明,震后地表变形主要来自地壳深部,震后滑动与地壳深部弹性松弛有关。根据鲜水河断层地表的滑动数据和按Marone's(1991)给出的方程确定的震后滑动模型,估计的应变速率显示,主震发生后应变速率较高,随时间延续,应变速率逐渐下降。基于地壳P波速度结构和利用热流数据估计的丽江地区地壳温度,采用含水石英的塑性流变参数,估计了中地壳脆塑性转化带深度随震后应变速率的变化。结果表明,主震震源深度与余震深度分布下限与中地壳脆塑性转化带的深度随时间变化趋势一致。由于断层的震后快速滑动致使断层带深部具有很高的应变速率,高应变速率引起断层脆塑性转化带深度下移,主震之后短时间内发生了较深的余震;随着震后时间的延续,断层逐渐进入蠕变阶段,断层滑动速率逐渐减小,地壳应变速率逐渐降低,断层脆塑性转化带也逐渐恢复到间震期的深度,相应余震深度随之变化。因此,余震分布的深度变化是中地壳流变结构和脆塑性转化带深度变化的直接反映。 相似文献
15.
16.
大地震发生之后通常会诱发一系列的余震序列,对比1976年MS7.8唐山大地震和2001年MS8.1昆仑山大地震周边区域的地震事件可以看出,唐山大地震余震活动时间要明显长于昆仑山大地震余震活动时间.余震序列往往与震后形变密切相关,而影响震后形变的因素不仅与地震发震断层和震级有关,同时与岩石圈的结构有关.考虑到唐山大地震的发震区华北地块和昆仑山大地震的发震区青藏高原有着较大的岩石圈结构差异,本文采用PSGRN/PSCMP软件计算了岩石圈分层模型的大地震同震和震后形变,分析了地壳弹性模量、弹性厚度以及黏滞性系数对同震和震后形变的影响,进而讨论了影响唐山地震和昆仑山地震余震序列差异的原因.计算结果显示,震后形变会在黏弹性效应的作用下逐渐调整,震后形变的持续时间与地壳弹性模量、地壳弹性厚度和下地壳黏滞性系数有关.上地壳和下地壳弹性模量越大,震后形变达到稳定值的时间越短,弹性模量对震后形变稳定值影响很小.地壳弹性厚度越大,震后形变达到稳定值的时间越短,当断层面底端深度小于地壳弹性厚度时,地壳弹性厚度的增加会引起震后形变稳定值的减小;下地壳厚度对震后形变达到稳定值的时间和稳定值基本无影响.下地壳黏滞性系数越大,震后形变达到稳定值的时间越长,反之亦然.结合唐山地震区的华北地块和昆仑山地震的青藏高原深部结构发现,两者之间的上地壳弹性模型差别不大,唐山地震区地壳弹性厚度略大于昆仑山地震区,但昆仑山地震区下地壳黏滞性系数明显低于唐山地震区.这些因素均决定了昆仑山地震的震后形变持续时间短(余震时间序列短)而唐山地震的震后形变持续时间长(余震时间序列长).由此可见,岩石圈结构差异可能是导致唐山地震和昆仑山地震余震序列差异的主要因素之一. 相似文献
17.
岩石圈流变学结构是控制不同构造环境下岩石圈形变的关键因素之一. 随着空间大地测量观测技术的发展, 基于空间大地测量数据的震后形变研究对揭示断裂带内的力学性质和区域性岩石圈流变学结构已成为可能. 该文首先基于岩石力学的摩擦和流变学实验, 对余滑和分布式韧性流的构造物理背景进行了分别阐述, 并介绍了震后形变数值模拟中本构关系和数值模型的发展. 数值模型主要有解析、 半解析和纯数值3类, 涉及的本构关系包括基于速率-状态摩擦准则的余滑以及分布式韧性流中常用的线性流变学模型(麦克斯韦尔体和标准线性固体)和瞬态流变学模型(宏观经验性的伯格斯(Burgers)体和微观幂律流变律). 然后以美国南加州1992年Landers MW7.3地震和1999年Hector Mine MW7.1地震震后形变研究为例, 介绍了震后形变的研究进展. 最后回顾了大陆岩石圈流变学结构的研究进展, 并以震后形变研究中的流变学结构(“三明治模型”和“焦糖布丁模型”)存在的争议为例, 说明了岩石圈流变学结构研究所具有的挑战性. 相似文献
18.
In this paper, we firstly use finite element method (FEM) with Burgers model to simulate the postseismic viscoe-lastic relaxation taking 1960 Chile earthquake as an example. The postseismic deformation modeled with Burgers model includes co-seismic deformation, transient postseismic deformation and long-term postseismic deformation. So if we apply Burgers model to calculate postseismic deformation of 1960 Chile earthquake, there is no discrep-ancy phenomenon due to different durations of postseismic deformations that happens in Maxwell model. 相似文献
19.
Kiyoo Mogi 《Pure and Applied Geophysics》1984,122(6):765-780
The temporal variation in precursory ground tilt prior to the 1944 Tonankai (Japan) earthquake, which is a great thrust-type earthquake along the Nankai Trough, is discussed using the analysis of data from repeated surveys along short-distance leveling routes.Sato (1970) pointed out that an anomalous tilt occurred one day before the earthquake at Kakegawa near the northern end of the focal region of the earthquake. From the analysis of additional leveling data, Sato's result is re-examined and the temporal change in the ground tilt is deduced for the period of about ten days beginning six days before the earthquake. A remarkable precursory tilt started two or three days before the earthquake. The direction of the precursory tilt was up towards the south (uplift on the southern Nankai Trough side), but the coseismic tilt was up towards the southeast, perpendicular to the strike of the main thrust fault of the Tonankai earthquake. The postseismic tilt was probably opposite of the coseismic tilt. The preseismic tilt is attributed to precursory slip on part of the main fault. If similar precursory deformation occurs before a future earthquake expected to occur in the adjacent Tokai region, the deformation may help predict the time of the Tokai earthquake. 相似文献
20.
2001年11月14日,在青海和新疆交界处发生了昆仑山Ms8.1级强烈地震,GPS后观测显示,此次地震震后形变不仅在断裂南北两侧存在很大的差异,而且在短时间调整后断裂南北两侧表现为同向运动.本文以观测的地震形变为约束,通过有限元数值模拟分析昆仑山地震震后形变的物理机制.建立有关的有限元虚功方程,通过有限元数值方法模拟震后形变,从理论上分析介质的非均匀性、黏滞性松弛、流体调整对震后形变的影响.采用网格搜索确定昆仑断裂南北两侧下地壳的黏滞系数分别为5.0×1017Pa·s, 9.0×1018Pa·s左右,正是这十余倍的差异引起了断裂两侧震后形变的非对称性和同向运动,这一差异既是长期地质作用的结果,又是现代地球动力学环境的决定因素之一.通过数值模拟定性讨论了断裂北侧地表形变在震后短期内的调整,对于靠近断裂附近的测点可能是黏弹性松弛和孔隙流体调整共同作用的结果,所以在分析短期震后形变时综合考虑黏弹松弛和孔隙流体调整是很有必要的. 相似文献