共查询到18条相似文献,搜索用时 635 毫秒
1.
本文用流变断裂力学研究了地震孕育过程.与弹性力学不同,它是一个不可逆的时空过程.由于介质的粘性,外力功的一部分花在粘性耗散上,只有弹性应变能是地震发生及震后过程可利用的能量.我们将弹性应变能从总能量中分离出来,并就标准线性体给出了简洁公式.以海城地震为例,计算了两个共线不等长断层在地震孕育过程中其周围区域的应力场和能量场的时空变化图象及应变能积累曲线.结果表明,应变能分布复杂,在时间和空间上都很不均匀,能量积累在孕震初期较快而在后期渐趋平缓.由此讨论了某些地震前兆,认为当能量增加速率较大时某些早期前兆可能出现,比如唐山地震10年前出现的某些异常可能就是这种早期前兆表现. 相似文献
2.
本文用流变断裂力学研究了地震孕育过程.与弹性力学不同,它是一个不可逆的时空过程.由于介质的粘性,外力功的一部分花在粘性耗散上,只有弹性应变能是地震发生及震后过程可利用的能量.我们将弹性应变能从总能量中分离出来,并就标准线性体给出了简洁公式.以海城地震为例,计算了两个共线不等长断层在地震孕育过程中其周围区域的应力场和能量场的时空变化图象及应变能积累曲线.结果表明,应变能分布复杂,在时间和空间上都很不均匀,能量积累在孕震初期较快而在后期渐趋平缓.由此讨论了某些地震前兆,认为当能量增加速率较大时某些早期前兆可能出现,比如唐山地震10年前出现的某些异常可能就是这种早期前兆表现. 相似文献
3.
本文利用1997—2008年5月的汶川M_w7.9地震前川滇地区GPS水平速度场数据,采用负位错理论反演了汶川M_w7.9地震前龙门山断裂带的闭锁程度.在顾及断层闭锁影响下,获得了龙门山断裂带区域震前十年间地壳应变率场.结果表明在汶川地震前龙门山断裂带高度闭锁,在地表以下0~25 km范围内其平均闭锁程度为0.972±0.222,滑动亏损速率约为3 mm·a~(-1).震前龙门山断裂滑脱层的高度闭锁为汶川地震深部同震破裂提供了能量基础;在顾及断层闭锁影响下,龙门山断裂带附近应变积累缓慢,断层附近区域最大主应变率约为3.4~9.6 nanostrain·a~(-1),最小主应变率约为-2.5~-7.1 nanostrain·a~(-1);断层西北侧有明显的应变积累. 相似文献
4.
汶川8.0级地震前龙门山断裂带能量场变化 总被引:3,自引:0,他引:3
在大地震的孕育和发生过程中,沿断裂带的应力-应变状态与断裂带周围微震活动有着密切的关系.震前沿构造断裂带附近地震活动的能量释放更能反映地震孕育的动态过程.本文采用自然正交函数展开方法,讨论了2008年汶川8.0级地震前沿龙门山断裂带地震活动能量场的时间变化.结果表明,在汶川8.0级地震前,沿龙门山断裂带能量场的几个主要特征值对应的典型场的时间因子出现非常明显的短期上升变化,可能是该次地震短期异常信息.通过对比分析1976年唐山地震等震例认为,研究沿活动断裂带地震活动能量场的时间变化,可以对地震中长期判断有较大危险性的活动断裂区进行有目的的重点监测和预测. 相似文献
5.
本文以青藏高原东南缘为研究区域,利用G-R震级能量经验公式和Benioff地震应变能释放曲线,对该区域内1500a以来的历史地震应变能释放进行了系统研究。文中给出了各断裂带和断块区的地震应变能释放周期表及相应的地震活动性分析。分析发现研究区域地震应变能的释放具有东强西弱,南强北弱的特征,整体上各断层断块区的历史地震应变能释放符合准周期模式,某些断层和断块区上的地震周期具有某种程度的同步现象。青藏高原东南缘现今处于大释放期,地震的活动性不能忽视。对局部地区的研究结果显示,安宁河-则木河断裂带、小江断裂带的地震活动性较强,对于这些地区应重点跟踪研究。 相似文献
6.
7.
本文以青藏高原东南缘为研究区域,利用G-R震级能量经验公式和Benioff地震应变能释放曲线,对该区域内1500年以来的历史地震应变能释放进行了系统性的研究。文中给出了各断裂带和断块区的地震应变能释放周期表,及相应的地震危险性。分析发现研究区域地震应变能的释放具有东强西弱,南强北弱的特征,整体上各断层断块区的历史地震应变能释放符合准周期模式,某些断层和断块区上的地震周期具有某种程度上的同步现象。青藏高原东南缘现今处于大释放期中,地震的危险性不能忽视。局部结果显示,安宁河-则木河断裂带、小江断裂带的危险性很高,对于这些危险区要重点跟踪研究。今后仍需结合不同研究方法来提高地震危险性评估的可靠性。 相似文献
8.
利用青藏高原东缘1999—2013年间多期GPS水平速率观测数据,基于多面函数拟合,计算球面坐标系下区域不同时期的面应变和最大剪应变,分析地应变的时空演化特征,结合不同时期发生的中强以上地震(MS6.0),研究期间大震分布与地应变时空演化特征的关系,主要结论如下:(1)青藏高原东缘面应变分布与地块有一定的对应关系,面应变的差异会在块体边界和内部形成不同的断层闭锁形式,与地震发生位置和震源机制有一定的关联;(2)区域最大剪应变的高值区对应于构造活动性较强的断裂带,这些断裂带鲜有地震发生;低值区对应于活动性较弱的断裂带,在区域地壳运动剧烈的背景下,在这些活动性相对较弱的断层上易形成应变能积累,因而会发生地震。区域绝大多数地震都发生在最大剪应变的低值区。 相似文献
9.
用三维流变非连续变形与有限元相结合(DDA+FEM)的方法,在青藏高原及邻近地区三维构造块体相互制约的大背景中,考虑了龙门山断裂带东西两侧地势、地壳厚度和分层的明显变化,及断裂带东侧四川盆地及鄂尔多斯块体坚硬地壳阻挡的影响,通过用GPS资料做位移速率边界约束和震源机制约束,计算得到研究区的速度场和应力场与该地区GPS测量结果和震源机制分布结果基本一致.在此基础上,模拟计算现今构造块体边界断层上表征剪应力及法向应力等综合影响的危险度分布.结果表明,上、中地壳层危险度分布中危险度较高的地段多数与近几十年来发生的七级以上大震区域基本一致.包括2008年汶川8.0级等大震的发震断层.通过分别对龙门山断裂带东西两侧的两种不同构造格局进行试算表明,龙门山断裂带东西两侧地势、地壳厚度、分层与物性明显变化对汶川大震的孕育发生均起了关键性作用.计算得到的应变率强度分布图可见,高原东部整个边缘地带均接近应变率强度的陡变带.其中以龙门山断裂带上的陡变最为明显,西侧应变率强度是东侧的近4倍,而且断裂带东侧应变率强度等值线衰减比西侧快.反映了汶川大震逆冲型发震断层地区独特的特征.此外,由计算得到的应变能密度分布图可见,龙门山断裂带在上、中地壳层中均位于宽度相同、其走向与龙门山断裂带走向一致的高应变能密度带中,在上地壳层这个带的东西两侧则是应变能密度较低的地区,而在中地壳层,其强度在断裂带东侧逐渐向东衰减,西侧应变能密度高,而东侧应变能密度较低.表明在印度板块强烈推挤作用和高原各构造块体相互制约及龙门山断裂带东西两侧特殊构造环境中,高原地壳物质向东水平运动,受到龙门山断裂带东侧介质刚性强度较大的四川盆地阻挡,使得汶川大震发震断层在大震前已积累了相当水平的应变能,并同时处于力学上的不稳定状态. 相似文献
10.
川西及邻区分布着中国大陆数条重要的活动断裂带,这些断裂带上的滑动速率与地震活动有很大差异,如鲜水河断裂带的滑动速率在10mm/a以上,该断裂带上大地震频繁发生;而龙门山断裂带的滑动速率很小,虽然该断裂带上地震活动不频繁,但也发生了2008年5月12日汶川Ms8.0级大地震.利用弹黏塑性三维有限元模型,研究川西地区断裂带的几何形态及走向变化对断层滑动速率及区域应变分配影响.结果表明:鲜水河-小江断裂带的滑动速率随着断裂带几何分布及其走向呈现分段特征.结构简单,走向平直的分段滑动速率大;结构复杂,走向变化大的分段滑动速率低,区域应变主要集中在断裂带走向发生急剧变化的分段附近.鲜水河-小江断裂带中段的应变分配受到安宁河-则木河断裂带与大凉山断裂带相互作用的影响.龙门山断裂带的走向与青藏高原的挤出方向近乎垂直,断层活动以逆冲为主,滑动速率较低. 相似文献
11.
12.
W. Ashley Griffith Pablo F. Sanz David D. Pollard 《Pure and Applied Geophysics》2009,166(10-11):1595-1627
We combine detailed mapping and microstructural analyses of small fault zones in granodiorite with numerical mechanical models to estimate the effect of mesoscopic (outcrop-scale) damage zone fractures on the effective stiffness of the fault zone rocks. The Bear Creek fault zones were active at depths between 4 and 15 km and localize mesoscopic off-fault damage into tabular zones between two subparallel boundary faults, producing a fracture-induced material contrast across the boundary faults with softer rocks between the boundary faults and intact granodiorite outside the boundary faults. Using digitized fault zone fracture maps as the modeled fault geometries, we conduct nonlinear uniaxial compression tests using a novel finite-element method code as the experimental “laboratory” apparatus. Map measurements show that the fault zones have high nondimensional facture densities (>1), and damage zone fractures anastamose and intersect, making existing analytical effective medium models inadequate for estimation of the effective elastic properties. Numerical experiments show that the damage zone is strongly anisotropic and the bulk response of the fault zone is strain-weakening. Normal strains as small as 2% can induce a reduction of the overall stiffness of up to 75%. Fracture-induced effective stiffness changes are large enough to locally be greater than intact modulus changes across the fault due to juxtaposition of rocks of different lithologies; therefore mesoscopic fracturing is as important as rock type when considering material or bimaterial effects on earthquake mechanics. These results have important implications for earthquake rupture mechanics models, because mesoscopic damage zone fractures can cause a material contrast across the faults as large as any lithology-based material contrast at seismogenic depths, and the effective moduli can be highly variable during a single rupture event. 相似文献
13.
依据断裂活动时代,滑动速率,破裂位移,强震复发期和地震释放能量等要素,通过一些典型实例证明,断裂活动的平行消减作用具有普遍意义,讨论了与断裂活动平行消减作用有关几个问题,本的研究成果对确定断裂活动力源,认识断裂和地质活动规律以及地震预报和地震危险性分析重要意义。 相似文献
14.
本文描述了一个解时空反演问题的方法.通过把华北地区看成是由24条主要断裂带组成的地质构造骨架,在15公里深处按照平面应变的理想塑性体处理,用有限单元方法计算了本地区在均匀边界外力作用下发生地震危险的地带.然后用逐次降低断层内摩擦系数的办法,模拟近十二年来历次大地震,计算释放应力后应力场的变化、断层的错动.将计算结果和实测资料进行对比,对各个力学参数和构造骨架进行了多次修改,使它们尽量接近.结果说明本方法能够基本上重复近十二年来的地震迁移规律,并可望对未来的地震危险区提出参考意见.结果还说明地震以后在沿断层错动方向的左前方有一狭窄扇形地带安全度增加,而其余较大地区由于断层处的应力释放使剪破裂的危险度有些增加. 相似文献
15.
In this paper, progress in strain study of blocks and faults by GPS data are discussed, and the concept that active structures between blocks are the main body of crustal strain is clarified. By energy transfer principle of elastic mechanics, the relation between strain around faults and tectonic force on fault surfaces is set up and main body element model of crustal strain is constructed. Finally, the relation between mechanical evolution of model and seismogenic process of Kunlun earthquake (Ms=8.1) is discussed by continuous GPS data of datum stations. The result suggests that the relatively relaxed change under background of strong compressing and shearing may help to trigger moderate-strong earthquakes. 相似文献
16.
根据唐山地区莫霍面隆升、大地构造、新构造运动特征,探讨1976年唐山7.8级地震发生的地质构造背景。唐山地震区位于辽翼台向斜北部,北邻燕山台褶带,地表发育规模不大的基岩断裂,为燕山期活动形成,新生代断裂活动性不强;地下发育深切地幔的深大断裂,与地表断裂位置相当。由震前地震前兆及震后异常现象,提出了地震发生的成因机制。唐山地震是由震前地幔拱起、岩浆上涌垂直力作用下,受NEE-SWW向区域应力场水平挤压,NNE-NE向唐山右旋剪切逆断裂活动,受阻于NW向蓟运河左旋剪切正断裂,地壳岩石间摩擦、破裂,两断裂在深部共轭交汇区应力闭锁、释放,最终导致该次地震的孕育、发生。 相似文献
17.
Abstract Bathymetric data from south of Hokkaido obtained during a cruise of R/V Hakuho-Maru are summarized, and their correlation with earthquake occurrence is discussed. There are structural lineations on the seaward slope of the Kuril Trench, oblique to the Kuril Trench axis and parallel to the magnetic lineations in the Pacific plate. The structural lineations comprise horst-grabens generated by normal faulting. This suggests that Cretaceous tectonic structures originating at the spreading centre affect present seismotectonics around the trench axis. The structural-magnetic relation is compared to the case of the Japan Trench. North-east of the surveyed area, there are two major fracture zones (Nosappu Fracture Zone and Iturup Fracture Zone) that divide the oceanic plate into three segments. If the fracture zones (FZ) and the zone of paleo-mechanical weakness, represented by magnetic lineations, can control the direction of normal faults at a trench, the extent of the resulting topographic roughness on the seaward slope of the trench would be different across an FZ because of the differences in ages. By studying recent large earthquakes occurring in the south Kuril region, it is shown that several main-aftershock distributions for large earthquakes in this region are bounded by the Nosappu FZ and the Iturup FZ. Two models (Barrier model and Rebound model) are presented to interpret earthquake occurrence near the south Kuril Islands. The Barrier model explains seismic boundaries seen in several examples for earthquake occurrence in the south Kuril regions. The fracture zone forming the boundary of two segments with different magnetic lineations is also the boundary of two different normal fault systems on their ocean bottom, and the difference in sea-bottom roughness between two normal fault systems should affect the seismic coupling at a plate interface. Due to the difference of seismic coupling, earthquake occurrence is controlled by an FZ and then the FZ acts as a seismic boundary (Barrier model). Existing normal faults created by plate bending of subducting oceanic plate should rebound after its subduction (Rebound model). This rebound of normal faults may cause intraplate earthquakes with a high-angle reverse-fault mechanism such as the 1994 Shikotan Earthquake. The energy released by an intraplate earthquake generated by normal-fault rebounding is not directly related to that of interplate earthquakes such as low-angle thrust earthquakes. It is a reason why large earthquakes occurred in the same region during a relatively short period. 相似文献
18.
MIGRATION OF LARGE EARTHQUAKES IN TIBETAN BLOCK AREA AND DISSCUSSION ON MAJOR ACTIVE REGION IN THE FUTURE 
下载免费PDF全文
下载免费PDF全文 YUAN Dao-yang FENG Jian-gang ZHENG Wen-jun LIU Xing-wang GE Wei-peng WANG Wei-tong 《地震地质》1979,42(2):297-315
On the basis of summarizing the circulation characteristics and mechanism of earthquakes with magnitude 7 or above in continental China, the spatial-temporal migration characteristics, mechanism and future development trend of earthquakes with magnitude above 7 in Tibetan block area are analyzed comprehensively. The results show that there are temporal clustering and spatial zoning of regional strong earthquakes and large earthquakes in continental China, and they show the characteristics of migration and circulation in time and space. In the past 100a, there are four major earthquake cluster areas that have migrated from west to east and from south to north, i.e. 1)Himalayan seismic belt and Tianshan-Baikal seismic belt; 2)Mid-north to north-south seismic belt in Tibetan block area; 3)North-south seismic belt-periphery of Assam cape; and 4)North China and Sichuan-Yunnan area. The cluster time of each area is about 20a, and a complete cycle time is about 80a. The temporal and spatial images of the migration and circulation of strong earthquakes are consistent with the motion velocity field images obtained through GPS observations in continental China. The mechanism is related to the latest tectonic activity in continental China, which is mainly affected by the continuous compression of the Indian plate to the north on the Eurasian plate, the rotation of the Tibetan plateau around the eastern Himalayan syntaxis, and the additional stress field caused by the change of the earth's rotation speed.
Since 1900AD, the Tibetan block area has experienced three periods of high tides of earthquake activity clusters(also known as earthquake series), among which the Haiyuan-Gulang earthquake series from 1920 to 1937 mainly occurred around the active block boundary structural belt on the periphery of the Tibetan block region, with the largest earthquake occurring on the large active fault zone in the northeastern boundary belt. The Chayu-Dangxiong earthquake series from 1947 to 1976 mainly occurred around the large-scale boundary active faults of Qiangtang block, Bayankala block and eastern Himalayan syntaxis within the Tibetan block area. In the 1995-present Kunlun-Wenchuan earthquake series, 8 earthquakes with MS7.0 or above have occurred on the boundary fault zones of the Bayankala block. Therefore, the Bayankala block has become the main area of large earthquake activity on the Tibetan plateau in the past 20a. The clustering characteristic of this kind of seismic activity shows that in a certain period of time, strong earthquake activity can occur on the boundary fault zone of the same block or closely related blocks driven by a unified dynamic mechanism, reflecting the overall movement characteristics of the block. The migration images of the main active areas of the three earthquake series reflect the current tectonic deformation process of the Tibetan block region, where the tectonic activity is gradually converging inward from the boundary tectonic belt around the block, and the compression uplift and extrusion to the south and east occurs in the plateau. This mechanism of gradual migration and repeated activities from the periphery to the middle can be explained by coupled block movement and continuous deformation model, which conforms to the dynamic model of the active tectonic block hypothesis.
A comprehensive analysis shows that the Kunlun-Wenchuan earthquake series, which has lasted for more than 20a, is likely to come to an end. In the next 20a, the main active area of the major earthquakes with magnitude 7 on the continental China may migrate to the peripheral boundary zone of the Tibetan block. The focus is on the eastern boundary structural zone, i.e. the generalized north-south seismic belt. At the same time, attention should be paid to the earthquake-prone favorable regions such as the seismic empty sections of the major active faults in the northern Qaidam block boundary zone and other regions. For the northern region of the Tibetan block, the areas where the earthquakes of magnitude 7 or above are most likely to occur in the future will be the boundary structural zones of Qaidam active tectonic block, including Qilian-Haiyuan fault zone, the northern margin fault zone of western Qinling, the eastern Kunlun fault zone and the Altyn Tagh fault zone, etc., as well as the empty zones or empty fault segments with long elapse time of paleo-earthquake or no large historical earthquake rupture in their structural transformation zones. In future work, in-depth research on the seismogenic tectonic environment in the above areas should be strengthened, including fracture geometry, physical properties of media, fracture activity behavior, earthquake recurrence rule, strain accumulation degree, etc., and then targeted strengthening tracking monitoring and earthquake disaster prevention should be carried out. 相似文献
Since 1900AD, the Tibetan block area has experienced three periods of high tides of earthquake activity clusters(also known as earthquake series), among which the Haiyuan-Gulang earthquake series from 1920 to 1937 mainly occurred around the active block boundary structural belt on the periphery of the Tibetan block region, with the largest earthquake occurring on the large active fault zone in the northeastern boundary belt. The Chayu-Dangxiong earthquake series from 1947 to 1976 mainly occurred around the large-scale boundary active faults of Qiangtang block, Bayankala block and eastern Himalayan syntaxis within the Tibetan block area. In the 1995-present Kunlun-Wenchuan earthquake series, 8 earthquakes with MS7.0 or above have occurred on the boundary fault zones of the Bayankala block. Therefore, the Bayankala block has become the main area of large earthquake activity on the Tibetan plateau in the past 20a. The clustering characteristic of this kind of seismic activity shows that in a certain period of time, strong earthquake activity can occur on the boundary fault zone of the same block or closely related blocks driven by a unified dynamic mechanism, reflecting the overall movement characteristics of the block. The migration images of the main active areas of the three earthquake series reflect the current tectonic deformation process of the Tibetan block region, where the tectonic activity is gradually converging inward from the boundary tectonic belt around the block, and the compression uplift and extrusion to the south and east occurs in the plateau. This mechanism of gradual migration and repeated activities from the periphery to the middle can be explained by coupled block movement and continuous deformation model, which conforms to the dynamic model of the active tectonic block hypothesis.
A comprehensive analysis shows that the Kunlun-Wenchuan earthquake series, which has lasted for more than 20a, is likely to come to an end. In the next 20a, the main active area of the major earthquakes with magnitude 7 on the continental China may migrate to the peripheral boundary zone of the Tibetan block. The focus is on the eastern boundary structural zone, i.e. the generalized north-south seismic belt. At the same time, attention should be paid to the earthquake-prone favorable regions such as the seismic empty sections of the major active faults in the northern Qaidam block boundary zone and other regions. For the northern region of the Tibetan block, the areas where the earthquakes of magnitude 7 or above are most likely to occur in the future will be the boundary structural zones of Qaidam active tectonic block, including Qilian-Haiyuan fault zone, the northern margin fault zone of western Qinling, the eastern Kunlun fault zone and the Altyn Tagh fault zone, etc., as well as the empty zones or empty fault segments with long elapse time of paleo-earthquake or no large historical earthquake rupture in their structural transformation zones. In future work, in-depth research on the seismogenic tectonic environment in the above areas should be strengthened, including fracture geometry, physical properties of media, fracture activity behavior, earthquake recurrence rule, strain accumulation degree, etc., and then targeted strengthening tracking monitoring and earthquake disaster prevention should be carried out. 相似文献