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鲜水河断裂带色拉哈段是2014年康定MS6.3地震的发震断裂段, 其最新一次地表破裂事件(1725年康定7级地震)的离逝时间较长, 是最可能发生7级以上地表破裂型大震的危险地段之一。获得色拉哈段最新地震地表破裂的展布范围对确定断裂带的地震活动历史、评估断裂带的未来地震危险性以及防震减灾具有重要意义。然而, 迄今色拉哈段最新地表破裂的北西端位置仍存有较大争议。对此, 在以往资料认为没有同震地表破裂的中谷村一带开挖了探槽组, 获得了这一带的破裂历史, 其最新一次事件(E6)的限定年代为A.D.746±51之后。综合探槽剖面证据和附近的断错地貌特征以及历史地震资料, 探槽揭露的最新事件E6可能对应1725年康定7级地震, 色拉哈段的地表破裂北西端至少已延伸到中谷村一带。 相似文献
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川藏铁路是中国正在规划建设的重点工程,穿越地形地貌和地质构造都极为复杂的青藏高原东部。铁路沿线活动断裂发育、地震频发,新建铁路雅安—林芝段直接穿越或近距离展布于龙门山断裂带、鲜水河断裂带等10条大型区域性活动断裂带,部分断裂活动速率值达10 mm/a,潜在强震危险性高。在内外动力耦合作用下,铁路沿线地质灾害极为发育,密集分布于大渡河、雅砻江、金沙江、澜沧江、怒江和雅鲁藏布江及其一级支流、活动断裂带和公路沿线,其中高位远程滑坡及链式灾害、深层蠕变-剧滑型滑坡、地震滑坡等灾害危害严重,成为了铁路建设的“拦路虎”。铁路沿线处于以水平构造应力为主导的高地应力环境,穿越华南主体应力区、龙门山—松潘应力区、川滇应力区、墨脱—昌都应力区和喜马拉雅应力区等5个大的一级构造应力区;雅安—康定段最大主应力方向为NWW—NW向,并向林芝方向呈现NNE向偏转,地应力在平面和垂向空间上表现为强烈局部差异性,如折多山某隧道地应力测试结果揭示了在垂向上存在应力释放区。在高地应力条件下,铁路沿线深埋隧道潜在围岩岩爆和大变形危害风险大。铁路建设应加强活动断裂安全避让、重大地质灾害早期识别和监测预警、深埋隧道地应力和岩爆大变形超前预测预报等工作,科学指导铁路选线与防灾减灾。 相似文献
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川藏铁路鲜水河构造带地质选线研究 总被引:1,自引:0,他引:1
川藏铁路康定过境段线路穿越了鲜水河活动构造带,存在高烈度地震与活动断裂、高位崩滑流、高陡岸坡失稳、高地应力岩爆和大变形、高地温、高压突涌水等系列重大工程地质问题,是全线地震和地质风险最大的一段,现有的选线经验借鉴困难,定线难度大。该段选线过程历时数十年,在不断摸索中选取了地质风险相对可控的三道桥设站-折多塘露头-折多山垭口越岭的可实施方案。本文通过系统梳理鲜水河构造带地质选线成果,总结出在构造活跃区地质选线应遵循区域稳定性选线-明线工程地质灾害选线-地下工程“极难处理”工程地质问题选线-不良地质综合选线-地质横断面选线等5个阶段逐渐深入的顺序。在遵守基本选线原则的同时,各阶段应充分考虑“构造、岩性、地下水”等3大地质基本要素,针对深大断裂构造应遵循“优先避让,其次正穿”、针对岩性应遵循“优先避开工程性质极差的特殊岩性(可溶岩、蚀变岩、构造软岩等),其次选择强度和完整性适中的岩性,并坚持走硬不走软”、针对地下水应遵循“岩溶水发育区应尽量减短水平循环带长度,地下水发育区尽量靠边走高实现顺坡排,地热异常区应走在低温廊道”的原则。该研究成果可为川藏铁路金沙江缝合带、嘉黎构造带以及规划中的滇藏铁路选线提供借鉴。 相似文献
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为了能在川藏铁路色拉哈段隧道选址过程中最大限度地规避地质灾害体,本文针对色拉哈断裂及邻区开展了音频大地电磁三维阵列探测研究,获得了研究区可靠的三维精细电性结构.结合地表活动断裂调查结果,对区内三维电性分布特征进行了综合解释.研究表明,色拉哈断裂及邻区地表至500 m,整体表现为高阻特征,局部受断裂控制的区域为低阻特征;500 m以下电阻率下降显著,推测是断裂带在500 m以下的深部构造富含水体所致;此外,位于色拉哈断裂北侧的木格措南阶区以及南侧的断裂交汇区东侧发育两处高导体C1和C2,推测为区内含水的构造软岩,在设计隧道路线的过程中,应尽量避让. 相似文献
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陈紫云 《地质灾害与环境保护》2019,30(2):41-51
康定至炉霍公路走廊沿鲜水河活动断裂带展布,断层活动造成区域地形地质条件非常复杂:地震频发、山地灾害多发,路线方案的合理布设事关项目成败。本文通过系统地搜集、整理和分析前人成果,研究论述了区域宏观构造格架、鲜水河断裂带及活动性、山地灾害等内外动力地质作用特征及相关的重大工程地质问题,在此基础上分析了断裂活动对路线方案的影响与控制作用,提出了路线方案的宏观思路见解和地震、地质灾害的专题研究建议。为路线方案设计及行业工程技术人员提供参考。 相似文献
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川藏铁路康定隧址区穿越鲜水河断裂带,属地热异常区,对铁路建设造成一定的热害威胁。采用野外调查、水化学分析和氢氧同位素测试等技术方法,开展了川藏铁路康定隧址区地热水成因研究。结果表明,康定隧址区地热水水化学类型主要为HCO3·Cl—Na和HCO3—Na型,聚集于折多塘、康定和中谷3个热水区。地热水均为未成熟水,热储温度为104~172 ℃,深部初始地热水温度为186~250 ℃,冷水混合比例为0.56~0.81。氢氧同位素显示地热水补给高程为3768~4926 m。在康定隧址区,地热水受到高海拔水源补给,主体断裂构造为导热构造,次级分支断裂和发育节理、裂隙的断层破碎带为导水构造,地热水形成后沿浅部断层破碎带出露形成温泉。FEFLOW数值模拟分析表明研究区100 m深度地温场温度为35.4~95.1 ℃,研究区内三个热水区之间存在低温通道。隧道建设时应重点关注康定热水区的高温水热灾害。 相似文献
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一、引言鲜水河断裂带是一条展布于川西北高原上的大型活动断裂带,无论在活动断裂类型,还是地震发育规律方面都极具代表性.对鲜水河活动断裂带的几何形态特征以及区域地质背景的研究,是研究该带地震发育规律及孕震性的基础资料与重要前提.但由于鲜水河活动断裂带地处高原地区,开展常规地质调查工作十分困难.作者试用TM图像进行鲜水 相似文献
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康定折多山花岗岩岩石学特征及其构造意义 总被引:2,自引:0,他引:2
折多山花岗岩作为鲜水河断裂带活动的同构造花岗岩为藏东地区高原隆升和构造演化提供了重要信息.区域地质调查填图表明,折多山岩体的岩石组合特征为:花岗闪长岩→粗粒似斑状二长花岗岩→中粒二长花岗岩→细粒二长花岗岩.其地球化学特征表明岩石属钾玄岩-高钾钙碱质岩石,稀土配分曲线显示其轻稀土富集,重稀土亏损,具有壳源岩浆特征,稀土-微量元素投点判别图表明花岗岩形成于造山后同构造环境.根据岩石学、地球化学研究,结合鲜水河断裂活动特征分析,认为折多山花岗岩不是断裂活动形成的地壳重熔的产物,而是断裂活动引起的下地壳流体上涌形成的.该项研究支持藏东地区下地壳流体存在的假说,并表明下地壳流体的向东迁移可能是造成鲜水河断裂分期活动和藏东地区逐步隆升的最主要的原因. 相似文献
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龙泉山断裂构造带作为龙门山推覆带的前陆隆起,严格控制了成都平原东边界,其活动性历来受到人们的关注。通过对龙泉山断裂带的氡气进行测量,可以有效地判断隐伏断层的位置及其活动性。测量结果显示,龙泉山断裂带北段东坡活动性强于西坡,主断层的活动性明显强于边缘隐伏断层,4条断层的活动性由强到弱依次为合兴场断层红花塘断层龙泉驿断层松林场断层。龙泉山断裂带同一条断层在地表由多个破碎带组成,其氡气异常特征与断层活动性和破碎带特征呈正相关性,即断层活动性越强,氡气异常特征越显著。龙泉山断裂带氡气平均异常浓度是背景值的9.6倍,将各异常带峰值浓度与背景值进行对比分析,大致归纳出了龙泉山地区隐伏断层活动性的相对判别标准。 相似文献
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Principal fault zone width and permeability of the active Neodani fault, Nobi fault system, Southwest Japan 总被引:2,自引:0,他引:2
A. Tsutsumi S. Nishino K. Mizoguchi T. Hirose S. Uehara K. Sato W. Tanikawa T. Shimamoto 《Tectonophysics》2004,379(1-4):93-108
The internal structure and permeability of the Neodani fault, which was last activated at the time of the 1891 Nobi earthquake (M8.0), were examined through field survey and experiments. A new exposure of the fault at a road construction site reveals a highly localized feature of the past fault deformation within a narrow fault core zone. The fault of the area consists of three zone units towards the fault core: (a) protolith rocks; (b) 15 to 30 m of fault breccia, and (c) 200 mm green to black fault gouge. Within the fault breccia zone, cataclastic foliation oblique to the fault has developed in a fine-grained 2-m-wide zone adjacent to the fault. Foliation is defined by subparallel alignment of intact lozenge shaped clasts, or by elongated aggregates of fine-grained chert fragments. The mean angle of 20°, between the foliation and the fault plane suggests that the foliated breccia accommodated a shear strain of γ<5 assuming simple shear for the rotation of the cataclastic foliation. Previous trench surveys have revealed that the fault has undergone at least 70 m of fault displacement within the last 20,000 years in this locality. The observed fault geometry suggests that past fault displacements have been localized into the 200-mm-wide gouge zone. Gas permeability analysis of the gouges gives low values of the order of 10−20 m2. Water permeability as low as 10−20 m2 is therefore expected for the fault gouge zone, which is two orders of magnitude lower than the critical permeability suggested for a fault to cause thermal pressurization during a fault slip. 相似文献
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2008年汶川地震促使人们思考青藏高原东南缘走向和规模与龙门山断裂带相近的丽江- 小金河断裂的活动历史,但受限于地质条件制约断裂尤其是其北段相关研究极其薄弱。基岩断裂带的物质组成与结构特征是断层长期活动的产物,蕴含丰富的历史活动信息。本文以丽江- 小金河断裂盐源段多个天然剖面为研究对象,通过详细的断裂带宏观结构调查、断层岩显微构造及XRD分析发现:① 断层破碎带以一套厚度>20 m的破裂面密集带为特征,优势破裂面走向为NE20°~30°,推测为丽江- 小金河断裂长期活动形成的张剪性破裂;② 断层带核部以断层角砾岩和断层泥为主,灰岩角砾岩黏土矿物含量~2%,以伊利石和伊蒙混层为主,粉砂岩断层泥黏土矿物含量~52%,以坡缕石和绿泥石为主,石英含量36%,缺失长石类矿物。断裂带宏观结构和断层岩微观结构特征均表现为角砾呈棱角状,砾径差异极大且呈零散状分布,符合快速滑动特征,指示断层滑移方式为黏滑。此外,核部断层岩带统计厚5~8 m,这一规模相对于龙门山映秀- 北川断裂带核部180~280 m和安县- 灌县断裂带核部40~50 m显著偏小,表明前者自形成以来的活动性远低于后者,两者的地震行为并不能简单类比。结合断裂在宏观结构特征、断层岩成分与种类以及所反映的滑动方式与隆升剥蚀量的差异,认为丽江- 小金河断裂更可能是鲜水河断裂切断锦屏山- 龙门山构造带之后形成的,晚新生代与龙门山断裂带具有不同的活动历史。 相似文献
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通过野外地质调查及对各断陷典型地震剖面和构造发育史剖面的综合研究,系统探讨了研究区深大断裂对断陷盆地群的控制作用。以西拉木伦河-长春-延吉板块拼接带、赤峰-开原超岩石圈断裂为边界,将研究区自南向北分为辽西盆地区、辽北盆地区和吉西盆地区等3个一级构造分区;根据控盆断裂及其断陷盆地群的时空分布、断陷构造样式、不同时期伸展量等特征将辽北盆地区分为西部、中西部、中东部等3个二级断陷区。西拉木伦河断裂控制了西部区断陷的形成和分布;嫩江—八里罕断裂和孙吴—大庆—阜新断裂对中西部断陷区的控盆效应大体相近;孙吴—大庆—阜新断裂与佳木斯—伊通断裂共同对中东部断陷区起着重要的控制作用;昌图断陷主要受佳木斯—伊通断裂所控制。辽北盆地区主要表现为双断式地堑,断陷群的形成和分布不仅受北北东向断裂控制,也受到近东西向的西拉木伦河断裂和赤峰—开原断裂重新活动的控制。中西部断陷区伸展率具有从九佛堂组沉积期—沙海组沉积期—阜新组沉积期依次减小的变化规律。中东部断陷区与中西部断陷区存在明显差异,NNE向与近EW向深大断裂对两区构造分区控制程度不同。 相似文献
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利用地面LiDAR精细化测量活断层微地貌形态——以毛垭坝断裂禾尼处断层崖为例 总被引:1,自引:1,他引:0
受地壳内部持续运动和沉积、风化等自然动力及人类生产与生活活动影响,活断层微地貌形态往往比较复杂,传统测量方法较难快速、高效地获取大范围内精细化的活断层微地貌形态,激光雷达扫描技术的出现和发展为活断层微地貌的精细化与定量化研究提供了新的技术手段。以川西理塘毛垭坝盆地北缘的正断层崖为研究对象,利用地面LiDAR获取活断层微地貌高精度点云后,经过点云配准、滤波、重采样和三角构网处理后,建立了0.05 m分辨率的数字高程模型和真彩色三维模型,在此基础上分析了断层崖地貌特征,并获取了正断层错动两期最新地貌面的精确垂直位错量。研究结果表明,地面LiDAR技术是精细测量活断层微地貌形态和量化相关地貌特征参数的有效手段,提高了活断层微地貌形态测量的精度和认识水平。 相似文献
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柯坪断隆内断裂发育,笔者根据野外及地震数据对各主要断裂和二级断裂进行了分析,认为柯坪塔格断裂形成于晚第三纪,沙井子断裂早期与柯坪塔格具有不同的发育历史,阿合奇断裂形成于挤压而非走滑的背景下,皮羌断裂和印干走滑断裂其实是协调作用的捩断层。萨尔干断裂是一条假走滑断层,实际上应该是一条撕裂断层。在挤压背景下形成了二类主要的断裂构造组合样式;叠瓦推覆体、构造窗。笔者认为柯坪断隆上的构造其实是印度板块和欧亚板块远程碰撞造山和板内变形的一种表现。 相似文献
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《International Geology Review》2012,54(13):1575-1615
Salinia, as originally defined, is a fault-bounded terrane in westcentral California. As defined, Salinia lies between the Nacimiento fault on the west, and the Northern San Andreas fault (NSAF) and the main trace of the dextral SAF system on the east. This allochthonous terrane was translated from the southern part of the Sierra Nevada batholith and adjacent western Mojave Desert region by Neogene-Quaternary displacement along the SAF system. The Salina crystalline basement formed a westward promontory in the SW Cordilleran Cretaceous batholithic belt, relative to the Sierra Nevada batholith to the north and the Peninsular Ranges batholith to the south, making Salinia batholithic rocks susceptible to capture by the Pacific plate when the San Andreas transform system developed. Proper restoration of offsets on all branches of the San Andreas system is a critical factor in understanding the Salinia problem. When cumulative dextral slip of 171 km (106 mi) along the Hosgri–San Simeon–San Gregorio–Pilarcitos fault zone (S–N), or dextral slip of 200 km (124 mi) along the Hosgri–San Simeon–San Gregorio–Pilarcitos–northern San Andreas fault system, is added to the cumulative dextral slip of 315–322 km (196–200 mi) along the main trace of the SAF north of the San Emigdio–Tehachapi mountains, central California, there is a minimum amount of cumulative dextral slip of 486 km (302 mi) or a maximum amount of cumulative dextral slip of 522 km (324 mi) along the entire SAF system north of the Tehachapi Mountains. When these sums are compared with the offset distance (610–675 km or 379–420 mi) between the batholithic rocks associated with the Navarro structural discontinuity (NSD) in northern California, and those in the ‘tail’ of the southern Sierra Nevada granitic rocks in the San Emigdio–Tehachapi mountains, central California, a minimum deficit of from ~100 km (~62 mi) to a maximum deficit of ~189 km (~118 mi) is needed to restore the crystalline rocks associated with the NSD with the crystalline terranes within the San Emigdio and Tehachapi mountains – the enigma of Salinia. Two principal geologic models compete to explain the enigma (i.e. the discrepancy between measured dextral slip along traces of the SAF system and the amount of separation between the Sierra Nevada batholithic rocks near Point Arena in northern California and the Mesozoic and older crystalline rocks in the San Emigdio and Tehachapi mountains in southern California). (i) One model proposes pre-Neogene (>23 Ma), Late Cretaceous or Maastrichtian (<ca. 71 Ma) to early Palaeocene or Danian (ca. 66 Ma) sinistral slip of 500–600 km (311–373 mi) along the Nacimiento fault and of the western flank of Salinia from the eastern flank of the Peninsular Ranges (sinistral slip but in the opposite sense to later Neogene (<23 Ma) dextral slip along and within the SAF system. (ii) A second model proposes that the crystalline rocks of Salinia comprise a series of 100 km- (60 mi-) scale allochthonous (extensional) nappes that rode southwestward above the Rand schist–Sierra de Salinas (SdS) shear zone subduction extrusion channels. The allochthonous nappes are from NW–SE: (i) Farallon Islands–Santa Cruz Mountains–Montara Mountain, and adjacent batholithic fragments that appear to have been derived from the top of the deep-level Sierra Nevada batholith of the western San Emigdio–Tehachapi mountains; (ii) the Logan Quarry–Loma Prieta Peak fragments that appear to have been derived from the top of a buried detachment fault that forms the basement surface beneath the Maricopa sub-basin of the southernmost Great Valley; (iii) The Pastoria plate–Gabilan Range massif that appears to have been derived from the top of the deep-level SE Sierra Nevada batholith; and (iv) the Santa Lucia–SdS massif, which appears to be lower batholithic crust and underlying extruded schist that were breached westwards from the central to western Mojave Desert region. In this model, lower crustal batholithic blocks underwent ductile stretching above the extrusion channel schists, while mid- to upper-crustal level rocks rode southwestwards and westwards along trenchward dipping detachment faults. Salinian basement rocks of the Santa Lucia Range and the Big Sur area record the most complete geologic history of the displaced terrane. The oldest rocks consist of screens of Palaeozoic marine metasedimentary rocks (the Sur Series), including biotite gneiss and schist, quartzite, granulite gneiss, granofels, and marble. The Sur Series was intruded during Cretaceous high-flux batholithic magmatism by granodiorite, diorite, quartz diorite, and at deepest levels, charnockitic tonalite. Local nonconformable remnants of Campanian–Maastrichtian marine strata lie on the deep-level Salinia basement, and record deposition in an extensional setting. These Cretaceous strata are correlated with the middle to upper Campanian Pigeon Point (PiP) Formation south of San Francisco. The Upper Cretaceous strata, belonging to the Great Valley Sequence, include clasts of the basement rocks and felsic volcanic clasts that in Late Cretaceous time were brought to a coastal region by streams and rivers from Mesozoic felsic volcanic rocks in the Mojave Desert. The Rand and SdS schists of southern California were underplated beneath the southern Sierra Nevada batholith and the adjacent Salinia-Mojave region along a shallow segment of the subducting Farallon plate during Late Cretaceous time. The subduction trajectory of these schists concluded with an abrupt extrusion phase. During extrusion, the schists were transported to the SW from deep- to shallow-crustal levels as the low-angle subduction megathrust surface was transformed into a mylonitic low-angle normal fault system (i.e. Rand fault and Salinas shear zone). The upper batholithic plate(s) was(ere) partially coupled to the extrusion flow pattern, which resulted in 100 km-scale westward displacements of the upper plate(s). Structural stacking, temporal and metamorphic facies relations suggest that the Nacimiento (subduction megathrust) fault formed beneath the Rand-SdS extrusion channel. Metamorphic and structural relations in lower plate Franciscan rocks beneath the Nacimiento fault suggest a terminal phase of extrusion as well, during which the overlying Salinia underwent extension and subsidence to marine conditions. Westward extrusion of the subduction-underplated rocks and their upper batholithic plates rendered these Salinia rocks susceptible to subsequent capture by the SAF system. Evidence supporting the conclusion that the Nacimiento fault is principally a megathrust includes: (i) shear planes of the Nacimiento fault zone in the westcentral Coast Ranges locally dip NE at low angles. (ii) Klippen and/or faulted klippen are locally present along the trace of the Nacimiento fault zone from the Big Creek–Vicente Creek region south of Point Sur near Monterey, to east of San Simeon near San Luis Obispo in central California. Allochthonous detachment sheets and windows into their underplated schists comprise a composite Salinia terrane. The nappe complex forming the allochthon of Salinia was translated westward and northwestward ~100 km (~62 mi) above the Nacimiento megathrust or Franciscan subduction megathrust from SE California between ca. 66 and ca. 61 Ma (i.e. latest Cretaceous–earliest Palaeocene time). Much, or all, of the westward breaching of the Salinia batholithic rocks likely occurred above the extrusion channels of the Rand-SdS schists; following this event, the Franciscan Sur-Obispo terrane was thrust beneath the schists, perhaps during the final stages of extrusion in the upper channel. Later, the Sur-Obispo terrane was partially extruded from beneath the Salinia nappe terrane, during which time the upper plate(s) underwent extension and subsidence to marine conditions. Attenuation of the Salinia nappe sequence during the extrusion of the Franciscan Complex thinned the upper crust, making the upper plates susceptible to erosion from the top of the Franciscan Complex near San Simeon, where it is now exposed. In the San Emigdio Mountains, the relatively thin structural thickness of the upper batholithic plates made them susceptible to late Cenozoic flexural folding and disruption by high-angle dip–slip faults. The ~100 km (~62 mi) of westward and northwestward breaching of the Salinia batholithic rocks above the Rand-SdS channels, and the underlying Nacimiento fault followed by ~510 km (~320 mi) of dextral slip from ~23 Ma to Holocene time along the SAF system, allow for the palinspastic restoration of Salinia with the crystalline rocks of the San Emigdio–Tehachapi mountains and the Mojave terrane, resolving the enigma of Salinia. 相似文献
18.
正断层的阶区构造及生长机制:以狼山山前断层带为例 总被引:2,自引:0,他引:2
正断层带在生长过程中内部发育有阶区构造,阶区在正断层的相互作用、连接过程中起重要控制作用,同时阶区还影响地表径流和沉积盆地的发展、流体的运移和圈闭的形成。位于内蒙古河套断陷西缘的狼山山前断裂是晚新生代以来持续活动的大型正断层系统,断层带内部发育有不同类型的阶区构造。识别出了两种类型阶区的连接方式,一种是两条平行断层之间的斜坡从"软连接"到"硬连接"的演化过程;另一种是楔状阶区通过一条断层向另一条断层扩展的方式连接产生。基岩中的先存构造要素控制并影响山前正断层的展布方位及阶区的形态:基底内部NNE向糜棱面理控制山前断层带的走向,早期向SE倾斜的逆冲断层面被正断层局部利用。沿断层倾向方向,山前正断层逐渐向盆地方向扩展,最新活动的断层位于盆地边缘甚至盆地内部;沿断层走向方向,狼山山前正断层逐渐向南西侧扩展。 相似文献
19.
The Tan-Lu fault zone (TLFZ) is the largest of the major faults in eastern China. Many strong earthquakes have occurred on its section in North China, but no quake greater than M ⩾ 6 has been documented in history at its northeastern section, the Yilan-Yitong fault (YYF) in Northeast China. It is usually considered that this fault has been inactive since late Quaternary and incapable of generating moderate-sized quakes. This conclusion is, however, questioned by our recent work based on high-resolution satellite image interpretation and field investigation. We found a 70-km-long surface scarp near Fangzheng county in Heilongjiang province (HLJP) and a 20-km-long scarp near Shulan county in Jilin province (JLP), and both are associated with the YYF. The trenches across these two scarps reveal a 14C displacement date of 1730 ± 40 years BP at Fangzheng and of 4410 ± 30 years BP at Shulan. The dextral offsets of the Songhua River and Second Songhua River and nearly horizontal fault striations indicate that the new activity of the YYF has been dominated by dextral strike slipping with a normal component. These new data suggest that, at least for partial sections, the YYF has been active since the Holocene, implying a potential seismic hazard. However, current quake-protection standards in this region are very low due to the previous view that the YYF fault has not been active since the late Quaternary. If an M ⩾ 7 quake takes place on this fault, it will be a devastating event. Therefore, it is necessary to conduct a detailed study on the whole YYF and to reassess its future seismic risk. 相似文献
20.
张家口一蓬莱断裂带是一条北西西向活动断裂带。本文选取ETM+光学影像和SRTM高程影像作为主要数据源,结合研究区已有地质资料研究发现该带断裂构造的北西西向线性特征明显。从水系分布和错断地形等地貌标志判断,该断裂具有左阶组合样式和左行走滑活动特征。据遥感影像综合特征,可将该带分为张家口段、延庆-怀来段和北京一天津段,影像特征分段性显著,并与断裂带的分段性一致。研究结果表明,张家口-蓬莱断裂具有左行走滑的运动学特征,限制或错断北北东或北东向断裂,并且控制该区域的左阶雁列式第四纪盆地群和第四纪冲洪积物的分布。该断裂带各段对不同规模的水系分布和形态影响比较大,且北京-天津地区的华北平原段断裂对第四纪冲洪积扇和沿海地区的贝壳堤的形态和分布有一定的控制作用。地球物理深部数据和野外地质考察资料也证实了遥感解泽的结果,证明遥感技术在探查断裂构造空间展布和活动性鉴定中有着广泛的应用前景。 相似文献