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1.
传统断层自主剖分技术进行地震断层滑动对地质形变的测绘研究时,未考虑走滑位移量、倾滑位移量和张开位移量对地质形变测绘研究的影响,无法对差异断层转动角下的地质形变情况实施有效测绘,提出基于矩形位错模型的地质形变的测绘研究方法,采用矩形断层位错模型通过点源位错公式,获取地震断层滑动时地质形变的走滑位移量、倾滑位移量和张开位移量;基于地震矩形断层三维滑动对地表产生的位移进行测绘时,获取各位移量同地面形成的三维位移场,采用二维高斯-勒让德求积计算断层三维位移场转动形成的地表位移,实现地质形变的测绘研究。实验结果表明,所提方法可对不同矩形断层转动角下的地质变形情况进行准确测绘,实际应用价值高。 相似文献
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余震精定位资料显示,芦山7.0级地震破裂面可能为弯曲程度较高的三维弯曲断层.相关研究显示,这种弯曲断层的位错方式和破裂面同震应力加卸载模式与普通平直断层有明显不同.文中采用无限半空间位错模型模拟显示,隐伏弯曲断层和平直逆断层引起的地表位移特征相似,但是弯曲断层引起的地表水平位移更接近区域整体的地壳缩短方向,缩短方向水平位移的量明显高于同等规模的平直逆断层,因此能更好地传递断层上盘大范围物质的水平运动.相对于平直断层,弯曲断层下盘水平位移随距离衰减十分明显.同等规模的弯曲断层导致的同震地表抬升小于平直逆断层或左旋逆断层引起的同震抬升,但能造成更明显的地表下降.由于地震规模较小,GPS等低密度空间分布的形变观测可能无法有效分辨芦山地震震源结构是否为弯曲断层.对震源结构的细节研究,还有待于利用高空间密度和高分辨率的形变观测资料. 相似文献
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本文利用GPS观测的1999-2007年汶川震前3期地表变形数据和2008年汶川同震地表变形数据,结合地震位错理论,通过高斯变换和坐标旋转建立断层模型,运用遗传算法,反演了龙门山断裂带断层震前3期和同震滑动参数。结果表明龙门山断层震前3期平均走滑位移为-5.39mm,倾向位移为2.66mm,与同震断层滑移相比较,发现震前断层的滑移趋势与同震断层滑移一致,均为逆冲兼右旋的挤压运动。比较震前3期逆冲方向的滑移量,发现逆冲滑移有加速的现象。并根据震前和同震的断层滑动量估算了汶川地震复发周期。 相似文献
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中国青海省门源县于2022年1月8日发生6.9级地震。依据该地震震源断层信息设置4种不同的位错分布模式,基于Okada提出的地表位移解析解分别计算4种模式下地表同震位移场,结合现场观测数据,探讨发震断层的滑动形式及其对周边地表产生的影响。结果表明,此次地震发震断裂初步判断主要为冷龙岭断裂西侧延伸至托莱山断裂,以左旋走滑断层为主,断层面上最大位错量达到4 m左右;震中西南侧向NE方向运动,东南侧向SE方向运动,西北侧和东北侧分别向NW以及SW方向运动;震中附近小范围区域产生了超过1.5 m的地表水平位移,破裂带上存在竖向地表位移超过0.5 m的区域;现场监测到局部产生最大约2.1~2.3 m的水平位错,以及部分区段垂直位错量最大达到0.7 m;以震中位置为中心,断层引起的地表位移影响范围达到约30 km×36 km,此范围内产生的地表位移大于0.1m。研究为此次地震的震后恢复工作以及此区域后续的工程设防等提供参考。 相似文献
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活动断层运动的重力场反演 总被引:4,自引:0,他引:4
阐述了断层错动引起地表地表重力变化的基本原理,给出了弹性半无限空间点源位错到矩形位错引起的重力变化的基本解析式,并将结论推广到多个断层,介绍了利用重力变化反演断层运动的基本思路。以滇西实验场作为实用实例,对1996年2月丽江7.1级地震发生前后场区内的活动断层运动进行了演算,给出了断层位位移解,并与已有资料相比较,结果基本一致,但误差分析结果表明本文错模型还有待于改善。 相似文献
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本文利用GPS观测对丽江—小金河断裂带的现今断层运动和变形状态进行了分析和探讨.丽江—小金河断裂带两侧地块地壳变形差异显著,GPS速度剖面结果显示断裂带两侧存在地壳变形不连续现象;进一步以GPS速度场为约束,基于负位错模型反演的丽江—小金河断裂带的断层闭锁空间分布结果显示,以木里为界,北东段断层强闭锁从地表向深部延伸至15km左右,西南段断层闭锁程度较高的区域位于5~15km范围内,浅层表现为弱闭锁的状态;滑动亏损速率结果显示,两闭锁段的滑动亏损速率相差近4mm·a~(-1),说明丽江—小金河断裂带西南段的背景滑动速率明显高于北东段.基于数值模拟分析了西南段浅层蠕滑运动对周边断层的影响,结果表明西南段的浅层左旋滑动对北东段闭锁区和西南段深部强闭锁区均为正影响. 相似文献
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使用GPS同震位移资料和远场P波记录,研究了1999年台湾集集地震震源破裂过程.根据地质构造和余震分布引入了一个由弯曲断层面构造的三段“铲状”断层模型.在使用静态GPS位移资料反演集集地震的断层破裂滑动分布时,由于集集地震断层北部近地表破裂的复杂性,在位错模型中考虑拉张分量对地表同震位移的贡献,可更好地同时拟合GPS观测资料的水平和垂向分量.而纯剪切位错弹性半空间模型和分层地壳模型都无法同时拟合水平和垂向GPS观测资料.在此基础上,同时使用静力学同震位移资料和远场地震波形记录,反演集集地震的震源破裂过程.结果表明,一种垂直于断层面的“挤压性”(负)拉张分量几乎集中分布于地震断层的浅部和北部转折处,而这一带地表破裂远较没有(负)拉张分量出现的南部断层复杂.“冒起构造”的数字模拟表明,这种在集集地震破裂转折处及北部断裂带广为出现的典型破裂造成的地表位移可以用具有负拉张分量(挤压)的逆冲断层更好地模拟.而这种负拉张分量(挤压)的分布正是地震破裂性质和几何复杂性的综合反映,震源破裂过程也显示北部转折处破裂在空间和时间上的复杂性.高滑区域与余震分布表现为负相关. 相似文献
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2008年汶川M_S8.0地震地表破裂变形定量分析——北川-映秀断裂地表破裂带 总被引:35,自引:14,他引:21
2008年汶川MS8.0地震在北川-映秀断裂产生了长达240km的同震地表破裂。通过详细的测量、基于测量标志与断裂变形的几何关系对数据的分析,给出了观测点的断裂同震地表变形的垂直位移、倾向水平缩短、走向滑动、断层上盘水平运动方向等参数。结果显示,断裂同震变形分布的空间变化很大,目前获得的最大水平位移位于虹口乡深溪沟,为4.98m,同时也是最大右旋走滑位移点,走滑量4.5m,而目前获得的最大垂直位移在其东北的支沟,为5.7~6.7m。NE向断裂水平位移多为1~2m,垂直位移多为3m左右,而小鱼洞-草坝分支断裂水平位移和垂直位移都更小,只有0.5~1.5m。擂鼓镇附近的数据则反映与断裂相关的巨型滑坡可能将重力变形叠加到构造变形中。由断层水平缩短和垂直位移计算的断层倾角表明,北川-映秀断裂是浅部陡倾的具有走滑分量的逆断层 相似文献
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利用于田震中300 km范围内的1个GPS连续站和12个GPS流动站数据,解算得到了2014年新疆于田MS7.3地震地表同震位移,并反演了发震断层滑动分布,探讨此次地震对周边断裂的影响.地表同震位移结果显示,GPS观测到的同震位移范围在平行发震断裂带的北东-南西向约210 km,垂直发震断裂带的北西-南东方向约为120 km,同震位移量大于10 mm的测站位于震中距约120 km以内;同震位移特征整体表现为北东-南西方向的左旋走滑和北西-南东方向的拉张特征,其中在北东-南西方向,I069测站位移最大,约为32.1 mm,在北西-南东方向,XJYT测站位移最大,约为28.1 mm;位错反演结果表明,最大滑动位于北纬36.05°,东经82.60°,位于深部约16.6 km,最大错动量为2.75 m,反演震级为MW7.0,同震错动呈椭圆形分布,以左旋走滑为主并具有正倾滑分量,两者最大比值约为2.5:1,同震错动延伸至地表,并向北东方向延伸,总破裂长度约50 km,地表最大错动约1.0 m;同震水平位移场模拟结果显示贡嘎错断裂、康西瓦断裂和普鲁断裂等不同位置主应变特征具有差异性,这种差异特征是否影响断裂带以及周围区域的应力构造特征,值得关注. 相似文献
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目前跨活动断层的线状工程的抗断设防仍采用确定性评价方法 ,考虑的是最大位错量 ,与抗御灾害的风险设计的实际要求不相符。文中将断层上最大位错点的位置分布及最大位错点两侧的位错展布 ,与可产生地表突发位移的强震复发模型联合 ,建立了评估活动断层各部位的地表潜在突发位移的概率性评价方法。最后 ,以怀涿盆地北缘正断裂中的沈庄 -长疃段为例 ,对其未来 10 0a潜在突发位移的危险性做出定量评估 ,给出了断层段上各点不同超越概率水平下的潜在位移。这一研究结果 ,可为跨断裂的线型工程进行抗御地表潜在突发位移的风险设计提供参考 相似文献
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渭河盆地是我国典型的断陷盆地,是中国大陆地裂缝活动、地面沉降活动最剧烈的地区之一.本文利用2004-2007年间的GPS数据,采用粒子群算法与位错理论模型相结合,对渭河盆地主要断裂的三维滑动速率进行了反演计算分析.结果表明:(1)断裂活动性质与地质测量方法获得的结果基本一致:除韩城—华县断裂以张裂为主外,渭河盆地主要断裂均以正倾滑为主,并具有走滑特征,呈张裂的运动趋势;(2)从滑动速率来看,秦岭北侧大断裂速率最大,可达4.5 mm/a.固关—宝鸡断裂活动最小,活动速率仅为1 mm/a左右;(3)在趋势上与现有的地质资料基本一致,以EW向断裂活动最强,NE方向较强,而NW方向较弱,并且分布上呈现南强北弱的特征. 相似文献
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Influence of 2008 Wenchuan earthquake on earthquake occurrence trend of active faults in Sichuan-Yunnan region 
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下载免费PDF全文 The Wenchuan earthquake coseismic deformation field is inferred from the coseismic dislocation data based on a 3-D geometric model of the active faults in Sichuan-Yunnan region. Then the potential dislocation displacement is inverted from the deformation field in the 3-D geometric model. While the faults' slip velocities are inverted from GPS and leveling data, which can be used as the long-term slip vector. After the potential dislocation displacements are projected to long-term slip direction, we have got the influence of Wenchuan earthquake on active faults in Sichuan-Yunnan region. The results show that the northwestern segment of Longmenshan fault, the southern segments of Xianshuihe fault, Anninghe fault, Zemuhe fault, northern and southern segments of Daliangshan fault, Mabian fault got earthquake risks advanced of 305, 19, 12, 9.1 and 18, 51 years respectively in the eastern part of Sichuan and Yunnan. The Lijiang-Xiaojinhe fault, Nujiang fault, Longling-Lancang fault, Nantinghe fault and Zhongdian fault also got earthquake risks advanced in the western part of Sichuan-Yunnan region. Whereas the northwestern segment of Xianshuihe fault and Xiaojiang fault got earthquake risks reduced after the Wenchuan earthquake. 相似文献
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Formation and deformation processes of the late Paleogene sedimentary basins related to a strike–slip fault system in southern central Hokkaido are described by a combination of paleomagnetic study and numerical analysis. After correction of the Miocene counter‐clockwise rotation associated with back‐arc opening of the Japan Sea, paleomagnetic declination data obtained from surface outcrops in the Umaoi and Yubari areas show significant easterly deflections. Although complicated differential rotation is anticipated as a result of recent thrust movements, clockwise rotation in the study areas is closely linked with development of the Paleogene Minami‐naganuma Basin as a pull‐apart depression along the north–south fault system. Numerical modeling suggests that 30 km of strike–slip is required to restore the distribution and volume of the Minami‐naganuma Basin. The relative slip rate on the long‐standing fault system is about 10 mm/yr, which corresponds to global‐scale plate motion. It has inevitably caused regional rearrangement of the eastern Eurasian margin. A rotation field simulated by simplified dextral motion using dislocation modeling basically accords with the paleomagnetic data around the pull‐apart basin. 相似文献
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利用区域水系形态研究构造活动特征已有丰富经验,可知铁炉子—栾川—南召断裂带西段——铁炉子断裂,晚更新世以来左旋走滑速率为1.25 mm/a,而东段——栾川—南召断裂则为早—中更新世活动段,2段具有明显的活动性差异,研究二者的构造转换方式,有助于了解块体运动在该断裂带内不同段落间的平衡方式。铁炉子段在洛南盆地分为南北两支,南支断裂下盘发育的冲沟普遍流向北,呈“平行状”水系,而北支断裂下盘发育的冲沟则流向南,并在断层附近有左旋扭动迹象;卢氏盆地中部发育NE走向的沉降中心,剖面分析结果表明,该沉降中心东侧普遍高出西侧70—80 m,结合遥感影像,初步认为卢氏盆地的最新活动或已由盆地边缘向盆地内部迁移,并与铁炉子段尾端组成伸展转换区,最终导致铁炉子断裂与栾川—南召断裂的活动性差异。 相似文献
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利用渭河盆地2001—2008年高精度GPS监测资料,结合区域构造特点建立了渭河盆地有限元动力学模型,基于此研究了区域现今地壳应力场特征,深入分析了构造应力场与盆地内地裂缝群发之间的内在关系,首次基于空间大地测量定量的揭示出了区域构造应力场与盆地内地裂缝群发的内在动力学联系,及盆地东、西部地裂缝分布不均衡的根本成因.研究结果表明:渭河盆地现今地壳应力场差异性显著,主要呈现出中、东部以NW-SE向拉张为主,西部则以NW-SE向压缩应力为主,整体具有相对左旋运动趋势,与区域以往长期构造变形具有较好的继承性;分析揭示出区域NW-SE向拉张构造应力正是盆地内中、东部地裂缝群发的力源机制,而盆地内差异性构造应力场也正是导致盆地东、西部地裂缝发育不均衡的根本原因所在,由此进一步证实了渭河盆地地裂缝的强构造属性,其是由活断层在上述力源机制作用下,以蠕滑形式错断地层使土层破裂而形成的.本文研究结果为盆地地裂缝灾害防治、城市安全建设提供了重要信息. 相似文献
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GPS data from Crustal Movement Observation Network of China (CMONOC) are used to derive far-field co-seismic displacements induced by the Mw 9.0 Tohoku Earthquake. Significant horizontal displacements about 30 mm, 10 mm, and 20 mm were caused by this large event in northeast China, north China, and on the Korean peninsula respectively. Vectors of relatively large horizontal displacements with dominant east components pointed to the epicenter of this earthquake. The east components show an exponential decay with the longitude, which is characteristic of the decay of the co-seismic horizontal displacements associated with earthquakes of thrust rupture. The exponential fit of the east components shows that the influence of the co-seismic displacements can be detected by GPS at a distance of about 3200 km from the epicenter of the earthquake. By considering the capability of the far field displacements for constraining the inversion of the fault slip model of the earthquake, we use spherically stratified Earth models to simulate the co-seismic displacements induced by this event. Using computations and comparisons, we discuss the effects of parameters of layered Earth models on the results of dislocation modeling. Comparisons of the modeled and observed displacements show that far field GPS observations are effective for constraining the fault slip model. The far field horizontal displacements observed by GPS are used to modify the slips and seismic moments of fault slip models. The result of this work is applicable as a reference for other researchers to study seismic source rupture and crustal deformation. 相似文献
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基于2009—2014年渭河盆地及邻区GPS资料,利用Shen提出的连续形变场与应变场计算方法,获得渭河盆地及邻区的水平形变场及应变率场,结合构造地质、地震目录等资料对渭河盆地及邻区的现今地壳形变及构造特征进行研究,并得到如下结论:(1)鄂尔多斯地块南缘西段和东段GPS形变场变化差异明显,六盘山—陇县—宝鸡断裂带形变场以挤压变形为主,渭河盆地中部西安—咸阳地区的形变场呈现EW向挤压、SN向拉张特征;(2)主应变率、剪应变率、面应变率变化明显的区域位于鄂尔多斯地块西南缘的六盘山—陇县—宝鸡断裂带、渭河盆地中部的长安—临潼断裂与渭南塬前断裂以及韩城断裂与双泉—临猗断裂附近;(3)未来需要警惕六盘山—陇县—宝鸡断裂带、长安—临潼断裂与渭南塬前断裂以及韩城断裂与双泉—临猗断裂附近的地震危险性。 相似文献
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The 03 February 2002 Çay Earthquake (Mw ~6.7) occurred on the fault segment between Eber and Ak?ehir Lakes followed by a large aftershock (Mw ~5.6) near the western end of the fault and two sequential aftershocks. We computed the coseismic surface displacements from static GPS measurements to determine the fault geometry parameters and uniform slip components. The coseismic displacements were obtained through combining the regional pre-earthquake and post-earthquake GPS data. Fault geometry and slips were acquired through the inversion of GPS data modeling the events as elastic dislocations in a half-space and assuming all four events took place on the same fault plane. Results suggest that one-segment fault of ~33 km length and dipping ~43° northward suffices to model the dislocation, assuming uniform slip distribution with 0.51 m dip slip, 0.26 m left-lateral slip extending to a depth down to ~11.5 km which is consistent with seismological evidence. The results also verify the normal faulting in the eastern flank of Isparta Angle which has long been assumed as a thrusting structure. While the available data cannot identify the four individual events on the same day, an attempted distributed slip model differentiates dip slip and left-lateral slips near the hypocenter with maximum values of ~1 and 0.6 m, respectively. 相似文献
20.
GEOLOGICAL AND GEOMORPHIC EVIDENCE FOR DEXTRAL STRIKE SLIP OF THE HELAN SHAN WEST-PIEDMONT FAULT AND ITS TECTONIC IMPLICATIONS 下载免费PDF全文
下载免费PDF全文 LEI Qi-yun ZHANG Pei-zhen ZHENG Wen-jun DU Peng WANG Wei-tao YU Jing-xing XIE Xiao-feng 《地震地质》2017,39(6):1297-1315
The horizontal movement of the Helan Shan west-piedmont fault is important to determination of the present-day boundary between the Alashan and North China blocks as well as to the exploration of the extent of the northeastward expansion of the Tibetan plateau. Field geological surveys found that this fault cuts the west wing of the Neogene anticline, which right-laterally offset the geological boundary between Ganhegou and Qingshuiying Formations with displacement over 800m. The secondary tensional joints (fissures)intersected with the main faults developed on the Quaternary flood high platform near the fault, of which the acute angles indicate its dextral strike slip. The normal faults developed at the southern end of the Helan Shan west-piedmont fault show that the west wall of this fault moves northward, and the tensional adjustment zone formed at the end of the strike slip fault, which reflects that the horizontal movement of the main fault is dextral strike slip. The dextral dislocation occurred in the gully across the fault during different periods. Therefore, the Helan Shan west-piedmont fault is a dextral strike slip fault rather than a sinistral strike slip fault as previous work suggested. The relationship between the faulting and deformation of Cenozoic strata demonstrates that there were two stages of tectonic deformation near the Helan Shan west-piedmont fault since the late Cenozoic, namely early folding and late faulting. These two tectonic deformations are the result of the northeastward thrust on the Alashan block by the Tibet Plateau. The influence range of Tibetan plateau expansion has arrived in the Helan Shan west-piedmont area in the late Pliocene leading to the dextral strike slip of this fault as well as formation of the current boundary between the Alashan and North China blocks, which is also the youngest front of the Tibetan plateau. 相似文献