航片判读新疆东天山巴里坤活动断裂带展布及变位地形特征     

江娃利 《内陆地震》1993,7(4):350-355

据航空像片活断层变位地形判读,巴里坤活动断裂带包括西盐池断裂及托来泉断裂。这2条断裂又分别由3条及4条次级断层组成。次级断层呈左阶方式排列。这些断层形成山前平直陡崖,错断洪积扇及河漫滩,形成地表陡坎、凹沟及淤积塘,组成地表地震形变带。这2条断裂是否分别对应1842年及1914年东天山2次7.5级地震,仍需进一步探讨。  相似文献   

洪积扇顶部活动走滑断裂的断错地貌分析 ——以新疆塔城盆地东缘阿合别斗河冲洪积扇为例     

苗树清  胡宗凯  张玲  杨海波  杨晓平 《地震地质》2021,(3):488-503

依据山前洪积扇顶部的扇形地形和向下游方向逐渐降低的地形特征,文中首先分析了断层面直立、向河流上游倾斜、向河流下游倾斜3种条件下左旋走滑断层错动在洪积扇顶部形成的断层陡坎的坡向和高度变化.其次,分析了左旋逆走滑断层、左旋正走滑断层在不同断层倾向条件下,断层错动在洪积扇顶部形成的断层陡坎的坡向和高度变化.利用无人机实测地形...  相似文献   

用地震断层陡坎的形态方程确定古地震事件的年代     

石树中  柏美祥 《内陆地震》1997,11(2):148-153

通过对地震断层陡坎演为过程的分析，应用均匀物质扩散理论建立地震断层陡坎的形态方程，推断古地震断层陡坎的年龄，从而确定古地震事件的期次及年代。用该方法对二台活断层古地震断层陡坎进行计算，所得结果与用其它方法确定的古地震事件的期次及年代对应较好。  相似文献   

秦岭北麓晚第四纪断层陡坎的初步研究   总被引：4，自引：1，他引：4  

中屠炳明  宋方敏 《地震地质》1991,13(1):15-25

根据航片解译和野外调查,发现在秦岭北麓第四纪松散沉积物中发育有断层陡坎,本文依据对这些陡坎的地质地貌分析、地形剖面测制、探槽揭露及测年数据,讨论了断层陡坎的空间分布和形态学特征、生成时代和断距,评估了秦岭北麓断裂在晚第四纪的活动强度。由断层陡坎高度经过校核获得断距变化范围在1.1至7.9米之间,由此求得秦岭北麓断裂中段全新世中晚期以来平均滑动速率接近1mm/a,西段在眉县一带为0.5mm/a左右。晚更新世以来,发生过3—4次古地震事件  相似文献   

山西交城断裂错断全新世洪积扇   总被引：1，自引：1，他引：1       下载免费PDF全文

江娃利  聂宗笙 《地震地质》1992,14(3):216-216,T001

航片判读及野外调查发现,位于山西太原盆地西界,交城至清徐县长约26km的山前地带,展布着一系列断续分布、总体呈NEE走向的洪积扇陡坎(图1)。 这些冲洪积扇陡坎展布在山前各冲沟沟口处,位于人山寺沟、大峪沟、桃园沟、泽鱼沟、市儿口沟、方山口沟及胡石井等沟沟口均可见到。这些陡坎的高度在1～10m不等。陡坎西北侧抬升,表现为冲洪积台地,陡坎组成台地  相似文献   

基于扩散方程的陡坎形貌测年方法进展     

许建红  陈杰  魏占玉  李涛 《地震地质》2023,(4):811-832

陡坎是一种自然界常见的台阶状地貌,但其形成年龄通常很难直接测定。发育在松散堆积物中的陡坎经过初期短暂的重力垮塌之后,将经历漫长的低能退化过程。如果陡坎剖面形态的演化可基于扩散方程来模拟,且扩散系数可独立标定,即可利用陡坎地形剖面估算其年龄,这种方法被称为形貌测年。文中简要回顾了陡坎形貌测年的研究历史,介绍并讨论了陡坎退化的概念模型与扩散模型,特别是非线性扩散模型的建立及求解、参数在扩散模型中所起的作用、最佳陡坎形貌年龄的确定流程等,分析了陡坎上、下地貌面坡度对陡坎退化的影响,编制了非线性扩散模型的年龄图版,给出了图版的应用实例,验证了形貌测年方法的有效性。线性扩散模型和非线性扩散模型均可用于单次事件陡坎的退化分析,但对于年轻的单次事件陡坎推荐使用非线性扩散模型。断层重复活动形成的陡坎的退化分析则需要谨慎对待,恒定滑动速率陡坎的非线性扩散模型适用于模拟年龄<10ka、活动速率高的断层陡坎的演化;多次事件陡坎模型(包括线性扩散和非线性扩散)需要仔细评估每次事件在陡坎剖面上的断错位置及其位移量。尽管陡坎形貌测年方法存在很多假设条件,但目前快速获取一定范围内的高分辨率地形数据已成为现实,...  相似文献   

对1812年3月8日新疆尼勒克8级地震发震构造的初步探讨          下载免费PDF全文

杨章  张勇  李军  尹光华 《地震学报》1985,(4)

本文根据现场考察,航片解译和历史记载资料,对1812年3月8日尼勒克地震的震级及地震地质背景进行了讨论。根据地震主断裂带的展布和运动特征与喀什河断裂带相一致等特点,指出1812年尼勒克8级大震是喀什河断裂作右旋逆冲的结果。 喀什河断裂是一条控制伊犁盆地北界和喀什河河谷的活断裂,它错断了喀什河阶地和古尼勒克沟,有着明显的新活动性。在震区还发现了一些古地震遗迹。对比1812年地震陡坎和古地震陡坎角度变化情况,对断层运动速率进行了估计,并估算出喀什河断裂带发生M≥8地震的重复周期为800—1600年。  相似文献   

对1812年3月8日新疆尼勒克8级地震发震构造的初步探讨a          下载免费PDF全文

杨章  张勇  李军  尹光华 《地震学报》1985,7(4):434-444

本文根据现场考察,航片解译和历史记载资料,对1812年3月8日尼勒克地震的震级及地震地质背景进行了讨论。根据地震主断裂带的展布和运动特征与喀什河断裂带相一致等特点,指出1812年尼勒克8级大震是喀什河断裂作右旋逆冲的结果。 喀什河断裂是一条控制伊犁盆地北界和喀什河河谷的活断裂,它错断了喀什河阶地和古尼勒克沟,有着明显的新活动性。在震区还发现了一些古地震遗迹。对比1812年地震陡坎和古地震陡坎角度变化情况,对断层运动速率进行了估计,并估算出喀什河断裂带发生M8地震的重复周期为800——1600年。   相似文献   

黄土覆盖的阶地陡坎附近渭河断裂活断层探测   总被引：2，自引：1，他引：1       下载免费PDF全文

师亚芹  冯希杰  种瑾  卞菊梅  张安良  许国昌  戴王强  李晓妮 《地震地质》2009,31(1):9-21

陕西咸阳渭河北岸窑店、石何杨、杜家堡渭河断裂活断层探测结果表明,对于有黄土覆盖的、与阶地陡坎重合的活断层探测,要综合采用地形地貌分析、浅层人工地震、钻探和探槽等方法进行。特别是对于钻孔探测,要深、中、浅孔结合。首先用中、深孔确定断层在深部的位置,再用浅孔确定断层在近地表的位置和活动性。由于河流侵蚀,阶地陡坎区的河流相沉积地层是倾斜的,风成的古土壤层披盖在已有的倾斜地层上亦呈倾斜状态,因此,用以上地层判断断层的位置和活动量时,钻孔孔距一定要小,以2～3m为宜,孔距太大,会把侵蚀形成的已有陡坎高度加入断层的错距中,严重放大断层的错动量。探测结果表明,渭河断裂在窑店、石何杨、杜家堡等处与Ⅲ级阶地陡坎重合。该断裂在阶地陡坎上的活动量很小,错断晚更新世第1古土壤层1～2m,远小于2个阶地面的高差。可见,以前认为S1错距4.8m、17.94m是不准确的。  相似文献   

邙山东侧地貌陡坎与老鸦陈断层活动性关系讨论     

张军龙  申晋利  田勤俭  申旭辉  张小龙  李兵 《地震》2008,28(4):121-127

地貌陡坎的成因有许多种, 其中之一是由断层在新构造时期的活动造成。 因此, 地貌陡坎的存在可能指示了断层在新生代的活动性, 然而在运用地貌线性方法判定新生代以来断层活动的时候还需要有其他资料的相互验证, 否则可能得到相反的结论。 该文以邙山东侧陡坎与老鸦陈断层为例, 通过遥感影像解释、 中浅层地震探测、 联合钻孔对比、 地貌测量等方法, 得到了老鸦陈断层是一条倾向NE向的前第四纪正断层, 同时将陡坎分为三段, 陡坎总体走向NW—NWW向, 由北而南, 高差逐渐降低, 出郑州东南后消失。 分析两者之间的关系, 认为古黄河改道或其支流侵蚀切割形成邙山东侧陡坎, 与老鸦陈断层没有直接关系, 陡坎的形成时间不应早于晚更新世。  相似文献   

电阻率成像及浅层地震勘探在控盆构造探测中的应用——以万全断裂为例     

周月玲  尤惠川  温超  王燕 《地震地磁观测与研究》2018,39(2):62-69

万全断裂是洋河盆地北缘断裂带组成断裂之一,控制沿线构造活动及地貌发育。断裂走向NE,倾向SE,在沟口处隐伏于第四纪覆盖层,采用电阻率成像和浅层地震联合勘探方法,获得该断裂隐伏段落综合物探异常,结合地质地貌调查,判定隐伏段落展布的具体位置、产状、活动特征及地下结构特征等。研究结果表明,万全断裂隐伏段落走向NE,倾向SE,倾角约75°,上断点埋深约20 m,20—240 m深度可见断裂破碎带（宽约10—20 m）物探异常特征及断裂两侧地层结构差异。该联合探测模式可有效探测复杂地质构造条件下的隐伏活动断裂,具有较强实用性,值得推广。  相似文献   

西秦岭北缘断裂带黄香沟段晚第四纪水平位移特征及其微地貌响应   总被引：4，自引：2，他引：2       下载免费PDF全文

李传友  张培震  袁道阳  王志才  张剑玺 《地震地质》2006,28(3):391-404

西秦岭北缘断裂带是青藏高原东北部一条左旋走滑为主的活动断裂带,其在黄香沟一段活动性较强,活动现象典型。对沿断裂带分布的地貌、地质体等晚第四纪位移量的研究表明,在黄香沟一带,断裂晚更新世晚期以来的水平位移量最大为40~60m;最小为6~8m,可能是一次滑动事件的特征位错量。断裂带上的位移具有分组特征,各组位移值之间具有6~8m的稳定增量。位移值的分组性和增量特征反映了该段断裂具有特征地震的活动特征,而7组位错值则反映了断裂7次特征活动事件。关于黄香沟一带与断裂相关的微地貌分析,也获得了大致相对应的事件次数。并由此初步推测,晚更新世晚期以来,该断裂带有过多次强烈活动,活动期次明显  相似文献   

西藏尼木南北向活动构造带的初步研究   总被引：2，自引：0，他引：2  

龚宇  张文甫 《四川地震》1993,(1):13-19

西藏尼木南北向活动构造带是西藏高原上著名的当雄—羊八井—多庆错活动构造带的组成部份,具有强烈的第四纪活动性。它由活动断裂和裂陷型断陷盆地两大部份构成。盆地内的地貌特征显示它在第四纪持续沉降的特点。该带中的活动断裂主要有两组,即南北向和北北东向。第四记的强烈活动在带内留下了众多的断错地貌现象,南北向活动断裂的主要活动时期较早,在更新世。北北东向活动断裂的主要活动时期较晚,在全新世。  相似文献   

荥经-马边-盐津逆冲构造带断裂运动组合及地震分段特征   总被引：9，自引：5，他引：9       下载免费PDF全文

张世民  聂高众  刘旭东  任俊杰  苏刚 《地震地质》2005,27(2):221-233

逆冲构造带的分段性研究是评价该类发震构造地震危险性的基础工作。荥经-马边-盐津逆冲构造带是青藏高原东南边缘重要的NW向强震构造带,该构造带以逆冲错动为主要活动形式,其组合形式与逆冲强度存在南北差异。通过NE向横向断裂的构造地貌分析,发现横向断裂以右旋走滑活动为主,兼有倾滑活动。根据其与纵向断裂的交接关系,将横向断裂概括为横向分割断裂、横向撕裂断裂和横向转换断裂3种类型,讨论了3类横向断裂在逆冲构造带分段中所起的不同作用,进而将荥经-马边-盐津逆冲构造带分为独立的3段,并分析了各段的地震活动特征。研究表明,荥经-马边-盐津逆冲构造带以横向断裂为标志的3分段特点,既体现了段与段之间断裂活动强度、地震破裂强度与步调的差异,又体现了段内地震破裂步调的一致性,表明横向断裂在一定程度上控制了逆冲构造带的破裂分段,只是横向断裂的类型不同,其所起的作用也不同  相似文献   

镇江地区主要NW向断裂的第四纪活动性     

张鹏  许奎  范小平  张媛媛  汪勇  郝景润 《地震地质》2021,43(1):144-157

五峰山-西来桥断裂和丹徒-建山断裂是镇江地区2条主要的NW向断裂,可能与镇江多次破坏性地震相关。文中通过浅层地震勘探和钻孔联合剖面探测方法,对五峰山-西来桥断裂和丹徒-建山断裂的展布特征及第四纪活动性进行了系统研究。五峰山-西来桥断裂在浅层地震剖面上倾向NE,倾角约为60°,断距约为5~9m,以正断活动为主;大路镇场地上,该断裂断错的最新地层为中更新统底部,位错量为2m,判断五峰山-西来桥断裂的最新活动时代为中更新世早期。丹徒-建山断裂在浅层地震剖面上倾向SW,倾角约为50°~55°,断距约为2~7m,以正断活动为主;访仙镇场地上,中更新统之上的地层没有被断错的迹象,中更新统底部可能被断层影响,判断丹徒-建山断裂的最新活动时代为早更新世—中更新世早期。  相似文献   

ANALYSIS OF EVOLUTION OF THE RIYUESHAN FAULT SINCE LATE PLEISTOCENE USING STRUCTURAL GEOMORPHOLOGY          下载免费PDF全文

LI Zhi-min  LI Wen-qiao  YIN Xiang  HUANG Shuai-tang  ZHANG Jun-long 《地震地质》2019,41(5):1077-1090

The northeastern margin of Tibetan plateau is an active block controlled by the eastern Kunlun fault zone, the Qilian Shan-Haiyuan fault zone, and the Altyn Tagh fault zone. It is the frontier and the sensitive area of neotectonic activity since the Cenozoic. There are widespread folds, thrust faults and stike-slip faults in the northeastern Tibetan plateau produced by the intensive tectonic deformation, indicating that this area is suffering the crustal shortening, left-lateral shear and vertical uplift. The Riyueshan Fault is one of the major faults in the dextral strike-slip faults systems, which lies between the two major large-scale left-lateral strike-slip faults, the Qilian-Haiyuan Fault and the eastern Kunlun Fault. In the process of growing and expanding of the entire Tibetan plateau, the dextral strike-slip faults play an important role in regulating the deformation and transformation between the secondary blocks. In the early Quaternary, because of the northeastward expansion of the northeastern Tibetan plateau, tectonic deformations such as NE-direction extrusion shortening, clockwise rotation, and SEE-direction extrusion occurred in the northeastern margin of the Tibetan plateau, which lead to the left-lateral slip movement of the NWW-trending major regional boundary faults. As the result, the NNW-trending faults which lie between these NWW direction faults are developed. The main geomorphic units developed within the research area are controlled by the Riyueshan Fault, formed due to the northeastward motion of the Tibet block. These geomorphic units could be classified as:Qinghai Lake Basin, Haiyan Basin, Datonghe Basin, Dezhou Basin, and the mountains developed between the basins such as the Datongshan and the Riyueshan. Paleo basins, alluvial fans, multiple levels of terraces are developed at mountain fronts. The climate variation caused the formation of the geomorphic units during the expansion period of the lakes within the northeastern Tibetan plateau. There are two levels of alluvial fans and three levels of fluvial terrace developed in the study area, the sediments of the alluvial fans and fluvial terraces formed by different sources are developed in the same period. The Riyueshan Fault connects with the NNW-trending left-lateral strike-slip north marginal Tuoleshan fault in the north, and obliquely connects with the Lajishan thrust fault in the south. The fault extends for about 180km from north to south, passing through Datonghe, Reshui coal mine, Chaka River, Tuole, Ketu and Xicha, and connecting with the Lajishan thrusts near the Kesuer Basin. The Riyueshan Fault consists of five discontinuous right-step en-echelon sub-fault segments, with a spacing of 2~3km, and pull-apart basins are formed in the stepovers. The Riyueshan Fault is a secondary fault located in the Qaidam-Qilian active block which is controlled by the major boundary faults, such as the East Kunlun Fault and the Qilian-Haiyuan Fault. Its activity characteristics provide information of the outward expansion of the northeastern margin of Tibet. Tectonic landforms are developed along the Riyueshan Fault. Focusing on the distinct geomorphic deformation since late Pleistocene, the paper obtains the vertical displacement along the fault strike by RTK measurement method. Based on the fault growth-linkage theory, the evolution of the Riyueshan Fault and the related kinetic background are discussed. The following three conclusions are obtained:1)According to the characteristics of development of the three-stage 200km-long steep fault scarp developed in the landforms of the late Pleistocene alluvial fans and terraces, the Riyueshan Fault is divided into five segments, with the most important segment located in the third stepover(CD-3); 2)The three-stage displacement distribution pattern of the Riyueshan Fault reveals that the fault was formed by the growths and connections of multiple secondary faults and is in the second stage of fault growth and connection. With CD-3 as the boundary, the faults on the NW side continue to grow and connect; the fault activity time on the SE side is shorter, and the activity intensity is weaker; 3)The extreme value of the fault displacement distribution curve indicates the location of strain concentration and stress accumulation. With the stepover CD-3 as the boundary, the stress and strain on NW side are mainly concentrated in the middle and fault stepovers. The long-term accumulation range of stress on the SE side is relatively dispersed. The stress state may be related to the counterclockwise rotation inside the block under the compression of regional tectonic stress.  相似文献   

新疆尼勒克1812年地震断层构造特征   总被引：5，自引：0，他引：5       下载免费PDF全文

尹光华  蒋靖祥  张勇  李军 《地震工程学报》2002,24(2):183-186

研究了1812年尼勒克地震断层的展布、构造类型和组合型式等地表特征，认为属倾滑型地盐碱地。破裂展布与逆冲性质的喀什河断裂一致，可分为三段。地震破裂的类型有正断层、走滑正断层、逆断层和地震裂缝四种，连续性较差，垂直错距约为水平位移的4倍，断裂带东西两端具有不同的特点。最后对发震构造与地表地震破裂的性质不一致问题进行了简单讨论。  相似文献   

氡(Rn)射气测量在胜利油田隐伏断裂研究中的应用   总被引：8，自引：1，他引：7  

刘江平  周斌  李庆红 《华北地震科学》2004,22(1):42-45

土壤氡(Rn)射气测量是探测隐伏断裂的存在,判定断裂的位置、走向、倾向的一种有效手段。通过在胜利油田进行的氡射气探测并结合其它勘探手段,发现该区主要的隐伏潘动断裂有无棣—益都断裂、胜北断裂和埕子口断裂。其中,无棣—益都断裂活动性最强。  相似文献   

Landslide distribution and size in response to Quaternary fault activity: the Peloritani Range,NE Sicily,Italy          下载免费PDF全文

Francesco Bucci  Michele Santangelo  Mauro Cardinali  Federica Fiorucci  Fausto Guzzetti 《地球表面变化过程与地形》2016,41(5):711-720

Landslides contribute to dismantle active mountain ranges and faults control the location of landslides. Yet, evidence of the long‐term, regional dependency of landslides on active faults is limited. Previous studies focused on the transient effects of earthquakes on slope stability in compressive and transcurrent regimes. Here we show that in the Peloritani range, NE Sicily, Italy, one of the fastest uplifting areas in the Mediterranean, a clear geographical association exists between large bedrock landslides and active normal faults of the Messina Straits graben. By interpreting aerial photographs, we mapped 1590 landslides and sackungs and 626 fault elements and their facets in a 300 km² area in the eastern part of the range. We used the new landslide and fault information, in combination with prior geological and seismic information, to investigate the association between bedrock landslides and faults. We find that the distribution and abundance of landslides is related to the presence of large active normal faults, and matches the pattern of the local historical seismicity. Landslide material is more abundant along the East Peloritani Fault System where the long‐term activity of the faults, measured by the average yearly geological moment rate, is larger than in the West Peloritani Fault System where landslides are less abundant. Along the fault systems landslide material concentrates where the cumulated fault throws are largest. We conclude that large landslides and their cumulated volume are sensitive to local rates of tectonic deformation, and discriminate the deformation of the single fault segments that dissect the Peloritani range. Our findings are a direct test of landscape evolution models that predict higher rates of landslide activity near active faults. Our work opens up the possibility of exploiting accurate landslide and fault maps, in combination with geological and seismic information, to characterize the long‐term seismic history of poorly instrumented active regions. © 2015 The Authors Earth Surface Processes and Landforms Published by John Wiley & Sons Ltd  相似文献   

MECHANISM OF THE 2016 HUTUBI,XINJIANG, M_S6.2 MAINSHOCK AND RELOCATION OF ITS AFTERSHOCK SEQUENCES     

XU Zhi-guo  LIANG Shan-shan  ZOU Li-ye  LIU Jing-guang 《地震地质》2019,41(1):44-57

A strong earthquake with magnitude M_S6.2 hit Hutubi, Xinjiang at 13:15:03 on December 8th, 2016(Beijing Time). In order to better understand its mechanism, we performed centroid moment tensor inversion using the broadband waveform data recorded at stations from the Xinjiang regional seismic network by employing gCAP method. The best double couple solution of the M_S6.2 mainshock on December 8th, 2016 estimated from local and near-regional waveforms is strike:271°, dip:64ånd rake:90° for nodal plane I, and strike:91°, dip:26ånd rake:90°for nodal plane Ⅱ; the centroid depth is about 21km and the moment magnitude(M_W)is 5.9. ISO, CLVD and DC, the full moment tensor, of the earthquake accounted for 0.049%, 0.156% and 99.795%, respectively. The share of non-double couple component is merely 0.205%. This indicates that the earthquake is of double-couple fault mode, a typical tectonic earthquake featuring a thrust-type earthquake of squeezing property.The double difference(HypoDD)technique provided good opportunities for a comparative study of spatio-temporal properties and evolution of the aftershock sequences, and the earthquake relocation was done using HypoDD method. 486 aftershocks are relocated accurately and 327 events are obtained, whose residual of the RMS is 0.19, and the standard deviations along the direction of longitude, latitude and depth are 0.57km, 0.6km and 1.07km respectively. The result reveals that the aftershocks sequence is mainly distributed along the southern marginal fault of the Junggar Basin, extending about 35km to the NWW direction as a whole; the focal depths are above 20km for most of earthquakes, while the main shock and the biggest aftershock are deeper than others. The depth profile shows a relatively steep dip angle of the seismogenic fault plane, and the aftershocks dipping northward. Based on the spatial and temporal distribution features of the aftershocks, it is considered that the seismogenic fault plane may be the nodal plane I and the dip angle is about 271°. The structure of the Hutubi earthquake area is extremely complicated. The existing geological structure research results show that the combination zone between the northern Tianshan and the Junggar Basin presents typical intracontinental active tectonic features. There are numerous thrust fold structures, which are characterized by anticlines and reverse faults parallel to the mountains formed during the multi-stage Cenozoic period. The structural deformation shows the deformation characteristics of longitudinal zoning, lateral segmentation and vertical stratification. The ground geological survey and the tectonic interpretation of the seismic data show that the recoil faults are developed near the source area of the Hutubi earthquake, and the recoil faults related to the anticline are all blind thrust faults. The deep reflection seismic profile shows that there are several listric reverse faults dipping southward near the study area, corresponding to the active hidden reverse faults; At the leading edge of the nappe, there are complex fault and fold structures, which, in this area, are the compressional triangular zone, tilted structure and northward bedding backthrust formation. Integrating with geological survey and seismic deep soundings, the seismogenic fault of the M_S6.2 earthquake is classified as a typical blind reverse fault with the opposite direction close to the southern marginal fault of the Junggar Basin, which is caused by the fact that the main fault is reversed by a strong push to the front during the process of thrust slip. Moreover, the Manas earthquake in 1906 also occurred near the southern marginal fault in Junggar, and the seismogenic mechanism was a blind fault. This suggests that there are some hidden thrust fault systems in the piedmont area of the northern Tianshan Mountains. These faults are controlled by active faults in the deep and contain multiple sets of active faults.  相似文献