SEISMOGENIC STRUCTURE OF THE Ms7.0 EARTHQUAKE ON AUGUST 8, 2017 IN JIUZHAIGOU, SICHUAN
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摘要: 2017年8月8日21时19分,四川阿坝州九寨沟县发生7.0级地震,震中位于巴颜喀拉块体东边界虎牙断裂和东昆仑断裂带东段塔藏断裂交汇区域,地震构造背景较为复杂。地震导致了房屋和道路破坏、滑坡崩塌。根据高分辨率卫星影像解译、阶地坎变形的测量和测年数据得到:塔藏断裂东段晚第四纪以来以左旋走滑为主,兼逆分量,水平滑动速率为2.7~4.1 mm/yr,垂直滑动速率为0.56~0.6 mm/yr。结合此次地震的主余震分布、主震震源机制解等综合结果,初步建立了三维发震构造模型,分析认为此次地震属于走滑型地震,主破裂倾角57°~77°,发震断层可能是塔藏断裂的一条分支,是青藏高原块体向东推挤的一次地震事件。基于历史地震、活动断裂和形变观测方面的研究,巴颜喀拉块体具备显著的强震构造背景,对于该块体边界带周缘的强震活动和变形需要继续关注。
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关键词:
- 九寨沟Ms7.0级地震 /
- 塔藏断裂东段 /
- 活动断裂 /
- 发震构造 /
- 巴颜喀拉块体
Abstract: An Ms7.0 earthquake struck Jiuzhaigou county at 9:19 pm on August 8, 2017 in Aba Prefecture of Sichuan Province. The epicenter was located in the intersection area of the Huya fault on the east boundary of the Bayan Har block and the Tazang fault on the east section of the East Kunlun fault, with complicated seismotectonic settings. This earthquake caused damages to houses and roads, and landslides collapsed. According to the data of high-resolution satellite image interpretation, the measurement data of tectonic deformation and dating data, it shows that the east section of the Tazang fault has been dominated by left-lateral strike-slip accompanied with thrust faulting; the horizontal sliding rate is about 2.7~4.1 mm/yr, and the vertical sliding rate is about 0.56~0.6 mm/yr. Combined with the distribution of major earthquake and aftershocks and the results of major earthquake source mechanism solution, a three-dimensional seismic structure model is established. The analysis reveals that this earthquake belongs to strike-slip earthquake with the main rupture angle of 57°~77°. It was caused by the eastward push of the Qinghai-Tibet Plateau mass, and the seismogenic fault may be a branch of the Tazang fault. According to the study of historical earthquakes, active faults and deformation observation, the Bayan Kala block has significant strong earthquake tectonic background, and it is necessary to continue to pay attention to the seismic activity and deformation of the boundary of the block. -
0. 引言
东亚大陆经历燕山运动[1~12],受东亚汇聚作用控制,形成了以华北—华南地块为核心的陆缘造山带,即北部蒙古—鄂霍次克造山带、东部陆缘造山带和西部班公湖—怒江造山带[12],陆内则遭受强烈的陆内造山作用[12~25],形成分别以鄂尔多斯地块和四川地块为中心的周缘造山带[18~19]和陆内大尺度的叠加褶皱[20~25],奠定了东亚大陆的基本构造格局[12]。
已有的研究表明,中—晚侏罗世东亚大陆几乎同时受古太平洋板块、特堤斯洋板块、西伯利亚板块汇聚作用,形成了3条陆缘造山带[12~13]。东亚大陆北部蒙古—鄂霍茨克造山带由于其两侧陆块(西伯利亚克拉通和华北克拉通),自西向东呈“剪刀式”汇聚碰撞[3, 26~30],其西部汇聚碰撞始于中侏罗世[29, 31~33],东部的碰撞一直持续到侏罗纪末期或白垩纪初期(175~135 Ma)[28, 32, 34~38],形成与大洋板块俯冲相关的侏罗纪—早白垩世的岩浆岩带[39, 40]。东亚大陆东缘造山带缘于古太平洋板块俯冲作用形成安第斯型造山带[2, 4, 41~45],其来自陆缘增生杂岩的年龄测试表明其主要发育时间为中—晚侏罗世到早白垩世[41, 45~47]。同时大量的东亚陆缘岩浆岩与火山岩[42~44, 47~49]与下白垩统之下的区域性角度不整合[11, 50~53],证实该带形成于中侏罗世—早白垩世期间(170~135 Ma)。
东亚大陆西缘班公湖—怒江构造带是青藏高原中部分割北侧羌塘地体和南侧拉萨地体的一条地块边界带[54~56]。已有的岩石学研究显示该带南侧拉萨地体经历中侏罗世晚期(170 Ma)和晚白垩世初期(90 Ma)两期变质事件[56~59],但对班公湖—怒江缝合带变形时代与汇聚方向仍然缺乏直接的依据。本文通过对班公湖—怒江构造带中段安多微地块的韧性剪切带开展同构造年代学研究,获得东亚大陆西缘侏罗纪聚合方位与时限。
1. 地质构造背景
班公湖—怒江构造带是分割羌塘地块与拉萨地块的一条巨型构造带,总体走向为南东东—北西西(见图 1),该带既构成古特提斯冈瓦纳大陆与欧亚大陆的分界线,又是三叠纪以来羌塘陆块和冈底斯陆块之间岩石圈结构和组成的重要分界线[54~55, 60~62]。该带西起阿里的班公湖,向东经日土、改则、双湖、东巧、安多、查吾拉、索县、丁青、嘉玉桥转向八宿县上林卡、在穿过左贡扎玉后沿怒江直下与沪水—龙陵结合带相连,再向南穿过滇西瑞丽江进入泰国,可能与清迈—清莱结合带和马来西亚劳勿—文冬结合带相接,中国境内长达2800 km,宽约20~160 km[63]。该带具有明显的布格重力梯度和剩余重力异常梯度,其南北两侧地壳结构、岩石圈厚度、热流值、地表位移量也存在显著差异[64]。班公湖—怒江构造带由前石炭纪变质岩系、古生界、晚三叠世确哈拉组和中—晚侏罗世木嘎岗日群深海复理石沉积岩、断续分布的晚古生代蛇绿岩、早—中侏罗世蛇绿岩以及沿构造侵位的晚三叠世、晚侏罗世—早白世世蛇绿质、泥砂质构造混杂岩组成(见图 2)。沿班公湖—怒江结合带分布有大量的蛇绿质构造混杂岩片,主要由变质橄榄岩、方(二)辉橄榄岩、辉长(绿)岩、枕状玄武岩和伴生的放射虫硅质岩组成。该带西段(班公错—那屋错—改则—色哇段)蛇绿岩呈长条状、透镜状、豆英状,以岩片形式产出,面积几平方公里,彼此间及其与确哈拉组、木嘎岗日群之间呈冲断层或剪切带接触。其中的玄武岩属拉班系列,被早白垩世阿普特—阿尔布期朗山组灰岩、东巧组角度不整合覆盖,蛇绿岩形成于早—中侏罗世(角闪石K-Ar同位素年龄179 Ma)。中段(尼玛—东巧—安多—索县段)蛇绿岩层序保存完好,超基性岩体似豆英状构造侵位于木嘎岗日群中,为早白垩世晚期东巧组不整合覆盖;硅质岩中发育晚侏罗世—早白垩世的放射虫化石,构造侵位时间为早白垩世晚期。东段(索县—巴青—丁青—八宿段)蛇绿岩呈北西西向长条状,由纯橄榄岩、斜辉橄榄岩、斜辉辉橄岩、层状辉长岩、辉绿岩、枕状玄武岩及放射虫硅质岩等岩片组成[56],蛇绿岩形成时代为中—晚侏罗世,构造侵位于中侏罗世末期[65]。
图 1 青藏高原及其邻区构造纲要图与东亚大陆晚中生代构造简图F1—喜马拉雅主冲断层;F2—雅鲁藏布江缝合带;F3—班公湖-怒江缝合带;F4—金沙江缝合带;F5—昆仑山断裂带;F6—阿尔金断裂带;F7—海原-祁连山构造带;F8—喀喇昆仑断裂带;F9—龙门山断裂带Figure 1. Tectonic outline map of the Qinghai-Tibet Plateau and its adjacent areas and simplified tectonic map of the East Asia continent in late Mesozoic班公湖—怒江构造带中段(安多段)发育平面呈椭圆形的安多-聂荣基底隆起(见图 2),基底主要为新元古代结晶基底(变质年龄为920~820 Ma)和寒武系—奥陶系(540~460 Ma)[56~57],并被早侏罗世花岗岩侵位[66],局部为早白垩世花岗岩侵入[67]。结晶基底以二长片麻岩和斜长片麻岩为主,夹有斜长角闪岩、英云闪长岩等透镜体,发育镁铁质高压麻粒岩相的峰期矿物组合,峰期变质的温-压条件为860~920 ℃和1.5~1.6 Gpa,变质时限为170 Ma[59, 68],指示班公湖—怒江缝合带东段可能形成于中—晚侏罗世[56, 69]。该基底隆起北缘发育蛇绿混杂岩带,内部及边缘发育多条近东西向韧性剪切带,以发育糜棱岩征为特征(见图 2)。
2. 构造变形及其年代学
构造编图与野外调查表明,安多—聂荣地块内部及其南、北两侧均发育韧性剪切带,剪切带总体上围绕眼球状的基底隆起近东西向展布。本文主要对安多-聂荣基底隆起内部发育的多条近东西—北西向韧性剪切带开展构造变形与构造年代学研究,获得了构造变形和年代学证据。
野外调查主要对不同方向剪切带进行构造测量,结果显示剪切带面理产状变化较大,但线理产状基本一致,其方位总体上为北东—南西方向。面理和线理构造统计分析,指示安多—聂荣地块韧性剪切带的形成主要受北东—南西向挤压应力场控制(见表 1、图 3)。
表 1 安多—聂荣地块韧性剪切变形测量结果与北东—南西向挤压构造应力场Table 1. Results of ductile shear deformation analysis and the NE-SW direction compressional tectonic stress field in the Ando-Nyainrong block点号 经度(E) 纬度(N) 数据量 σ1(az°/pl°) σ2(az°/pl°) σ3(az°/pl°) R D20 92°20′01″ 32°07′16″ 19 333/41 085/22 196/39 0.7 D21 92°18′45″ 32°07′29″ 5 186/34 047/47 292/21 0.7 D22 92°17′44″ 32°06′26″ 5 153/29 248/08 353/58 0.2 D25 92°12′14″ 32°03′23″ 4 320/43 111/42 215/15 0.3 D28 92°04′05″ 31°47′32″ 4 NNE-SSW D45 93°06′34″ 31°50′10″ 9 320/18 097/65 225/15 0.1 D53 91°42′06″ 31°52′51″ 7 244/24 137/33 002/46 0.8 D55 91°41′49″ 32°06′05″ 4 063/05 157/29 323/59 0.5 D56 91°42′45″ 32°07′15″ 7 100/17 209/45 355/39 0.5 D70 91°40′56″ 32°02′05″ 5 030/15 297/11 172/70 0.4 注:σ1—最大主应力;σ2—中间主应力;σ3—最小主应力;az—倾伏向;pl—倾伏角;R=(σ2-σ3/σ1-σ3) 
图 3 安多—聂荣地块韧性剪切带北东—南西向构造应力场特征(下半球等角投影(吴氏网))Figure 3. The characteristics of the NE-SW direction tectonic stress field of the ductile shear belts in the Ando-Nyainrong block在位于安多—聂荣微地块西南缘的观测点D53(见图 3),英云闪长岩内发育北东—南西走向的糜棱岩带,沿糜棱面理,黑云母与钾长石呈定向排列,形成矿物线理。糜棱面理总体倾向为北东东向,线理倾伏向为北东向或西南向,旋转碎斑指示剪切方向由南西转向北东。剪切变应力分析指示为北东—南西向挤压(见图 4)。鉴于该点位于眼球状安多—聂荣基底隆起区的西缘,且剪切方向由南向北,可能指示该基底块体南缘在挤压和缩短过程中,主要受其南侧地层仰冲影响。对该点糜棱岩中的同变形矿物钾长石和黑云母进行40Ar/39Ar年代学研究,获得一个白云母的坪年龄为167.1±1.8 Ma(见图 4、表 2)。尽管黑云母的40Ar/39Ar年代学测试结果没有形成一个统一的坪年龄,但这些视年龄范围介于160 Ma和168 Ma之间,与钾长石测试结果基本一致。一般认为,钾长石和黑云母的40Ar/39Ar封闭温度介于350 ℃和150 ℃之间[72]。这表明,目前暴露在安多—聂荣微地块西南缘的剪切带的形成深度大约为5~10 km,时间为中—晚侏罗世。
图 4 安多—聂荣地块西南缘韧性剪切带(观测点D53)40Ar/39Ar坪年龄与等时线年龄Figure 4. 40Ar/39Ar plateau age and isochron age of the ductile shear belts at the southwest margin of the Ando-Nyainrong block(Site D53)表 2 安多—聂荣地块西南缘韧性剪切带(观测点D53)40Ar/39Ar坪年龄与等时线年龄Table 2. 40Ar/39Ar plateau age and isochron age of the ductile shear belts at the southwest margin of the Ando-Nyainrong block(Site D53)T/℃ (40Ar/ 39Ar) m (36Ar/ 39Ar) m (37Ar 0/ 39Ar) m (38Ar/ 39Ar) m 40Ar/% F 39Ar/10 -14mol 39Ar(Cum.)/% Age/Ma ±1σ/Ma D53-1钾长石 W=27.71 mg J=0.002684 Total age=161.0Ma 700 165.8118 0.1561 0.7508 0.0540 72.22 119.8151 0.06 0.33 503.0 5.9 800 31.5490 0.0041 0.0206 0.0137 96.14 30.3332 1.28 6.84 141.2 1.4 860 28.0541 0.0010 0.0474 0.0129 98.90 27.7466 0.80 10.93 129.6 1.3 920 28.3819 0.0031 0.1538 0.0141 96.81 27.4801 0.62 14.06 128.4 1.3 980 28.7767 0.0015 0.1156 0.0130 98.46 28.3349 0.35 15.83 132.2 1.4 1040 30.5556 0.0048 0.0293 0.0139 95.30 29.1211 0.64 19.07 135.8 1.4 1100 34.8159 0.0072 0.0410 0.0148 93.85 32.6757 1.03 24.32 151.6 1.5 1160 37.8379 0.0090 0.0237 0.0147 92.95 35.1694 1.65 32.70 162.7 1.6 1210 38.8774 0.0080 0.0170 0.0147 93.90 36.5066 3.23 49.13 168.6 1.6 1260 38.2769 0.0067 0.0052 0.0142 94.83 36.2989 6.82 83.80 167.7 1.6 1290 37.4411 0.0059 0.0204 0.0141 95.33 35.6945 2.62 97.10 165.0 1.6 1330 37.8766 0.0080 0.1179 0.0146 93.74 35.5089 0.43 99.27 164.2 1.7 1400 40.3533 0.0196 0.3614 0.0165 85.72 34.5995 0.14 100.00 160.2 2.4 D56-1黑云母 W=33.07 mg J=0.002735 Total age=165.6Ma 700 56.7666 0.1419 1.2378 0.0440 26.28 14.9359 0.06 0.37 72.2 5.2 760 36.0626 0.0190 0.1219 0.0169 84.48 30.4678 1.00 6.30 144.4 1.4 800 36.3997 0.0037 0.0783 0.0139 96.99 35.3058 1.61 15.86 166.3 1.6 840 36.1519 0.0021 0.0000 0.0133 98.24 35.5169 1.64 25.62 167.3 1.6 880 36.0022 0.0024 0.1252 0.0138 98.05 35.3049 1.15 32.45 166.3 1.6 920 36.0515 0.0017 0.0771 0.0134 98.59 35.5449 1.15 39.31 167.4 1.6 960 36.0165 0.0019 0.1006 0.0134 98.47 35.4710 1.13 46.01 167.0 1.6 1000 36.2395 0.0019 0.0167 0.0131 98.46 35.6825 1.13 52.75 168.0 1.6 1040 35.9673 0.0014 0.0470 0.0134 98.82 35.5425 2.20 65.84 167.4 1.6 1080 36.0125 0.0015 0.0312 0.0133 98.78 35.5726 2.63 81.46 167.5 1.6 1200 36.1565 0.0014 0.0076 0.0130 98.88 35.7507 2.96 99.05 168.3 1.6 1400 39.5904 0.0179 0.7467 0.0179 86.78 34.3776 0.16 100.00 162.1 2.3 注:表中下标m代表样品中测定的同位素比值,F=40Ar*/39Ar, is the ratio of radiogenic Argon40 and Argon39 在安多—聂荣微地块西北缘(观测点D56),其结晶基底发育北东东走向韧性剪切带,糜棱面理主体倾向东,石英脉剪切变形特征指示由北东向南西剪切。结合该观测点位置,可以大致确定安多-聂荣地块北缘的变形以由北向南仰冲为特征。对糜棱面理上发生定向排列的黑云母进行了单矿物分离和40Ar/39Ar年代学测试,获得的坪年龄为167.1±1.1 Ma,等时线年龄为167.8±2.1 Ma,与反等时线年龄在误差范围内一致(见图 5、表 2),表明这期构造事件发生在中—晚侏罗世(大约167 Ma)。
图 5 安多—聂荣地块西北缘韧性剪切带(观测点D56)40Ar/39Ar坪年龄与等时线年龄Figure 5. 40Ar/39Ar plateau age and isochron age of the ductile shear belts at the northwest margin of the Ando-Nyainrong block(Site D56)上述对安多—聂荣地块同构造年代学结果表明,班公湖-怒江缝合带中段构造变形主要受北东—南西向构造挤压作用控制,变形方式在浅表以安多—聂荣微地块为中心,两侧地壳同时向地块仰冲缩短,其变形时代发生于中侏罗世中期(大约167 Ma)。
3. 讨论
大量的研究表明,班公湖—怒江带作为中特提斯洋闭合界线[60],是拉萨地块与羌塘地块于侏罗纪—白垩纪汇聚结果[56~58, 73]。但实际上班公湖—怒江带的闭合过程并非有统一时限,越来越多的研究表明,班公湖—怒江古大洋可能经历了呈剪刀式的东早西晚的穿时闭合过程[74~75],在班公湖—怒江带东段北北西走向的鲜水河断裂带,断裂带西侧发育170 Ma的同构造淡色花岗岩。且其构造解析结果显示,其变形时代为中侏罗世[76]。而班公湖—怒江带西段一般在早白垩世晚期闭合[56~57, 77],在改则地区至少在早白垩世晚期(大约106 Ma)地壳仍然正在生长[78]。在班公湖—怒江带中段,该带南侧拉萨地体经历中侏罗世晚期(170 Ma)和晚白垩世初期(90 Ma)两期变质事件[56~58],内部安多—聂荣陆块也记录侏罗纪变质事件,出现镁铁质高压麻粒岩的峰期矿物组合(单斜辉石+石榴石+石英+金红石),峰期变质的温-压条件为860~920 ℃和1.5~1.6 Gpa,变质时间为170 Ma[59, 68]。拉萨地块发育早白垩世(140~120 Ma)过铝质和强过铝质(S型)花岗岩[56, 69],这可能与拉萨地体和羌塘地体的碰撞(J3—K1)引起地壳增厚之后的减压熔融有关,这次汇聚导致在拉萨地块的南部和北部至少持续缩短约187 km[79]。前文对班公湖-怒江带中段分析表明,该段以北东—南西向汇聚为主,变形特征在地壳浅部表现为以安多—聂荣地块为中心,南北两侧分别向该地块仰冲,深部则可能表现为该地块南北两侧的中特提斯洋壳向南北的双向俯冲[80]。
已有的班公湖—怒江带的研究为其形成演化提供了大量岩石学和深部信息,本次研究选取班公湖—怒江带中段安多—聂荣地块,其韧性剪切带的构造测量与同构造年代学研究表明,班公湖—怒江缝合带形成于中—晚侏罗世羌塘地块与拉萨地块近南北向汇聚碰撞构造背景下,为恢复东亚大陆西缘侏罗纪构造提供了依据。这些侏罗纪构造变形过程可能与班公湖—怒江缝合带两侧的拉萨地块和羌塘地块之间的碰撞有关。虽然其具体特征还需要进一步的深入研究和验证,但上述构造和年代学资料无疑具有一定的借鉴意义。
4. 结论
本文通过安多—聂荣地块韧性剪切带的构造测量与同构造年代学研究,获得以下结论:(1) 班公湖—怒江带中段形成于中侏罗世中期(167 Ma);(2) 班公湖—怒江带中段形成于羌塘地块与拉萨地块北东—南西向汇聚碰撞的构造背景下。这一研究为重建东亚大陆西缘侏罗纪构造格局提供了关键构造证据。
致谢: 本论文野外工作得到中国地质科学院研究生陆露和赵珍的大力协助,中国地质科学院地质研究所完成了40Ar/39Ar年龄测试,在此深表感谢。 -
图 1 研究区断裂及余震分布图
ATF—阿尔金断裂带;HF—海原断裂带;KTF—昆仑断裂带;LMF—龙门山断裂带;JLF—嘉黎断裂带;RRF—红河断裂带;TZF—塔藏断裂;LRBF—龙日坝断裂;MJF—岷江断裂;BLGF—白龙江断裂;GGS-DSF—光盖山-迭山断裂;HYF—虎牙断裂
Figure 1. Distribution map of regional faults and aftershocks in the study area
图 2 地震精定位及余震分布图(据IGP-CEA)
Figure 2. Precise location of the earthquake and distribution map of aftershocks
图 3 下黄寨遥感解译及断层剖面
a-高分一号影像三维可视化解译(图中箭头指示断层位置);b-断层剖面;c-断层剖面示意图
Figure 3. GF-1 remote sensing image and fault profile of Xiahuangzhai
图 4 神仙池附近遥感解译及断错地貌
a-神仙池附近高分一号影像三维可视化;b-断错地貌照片;c-地层褶皱照片
Figure 4. GF-1 remote sensing image and fault profile of Shenxianchi area
图 5 漳扎镇附近遥感解译
a-漳扎镇一带高分一号三维可视化;b-彭布地貌照片;c-荷叶地貌照片;d-彭布断层剖面
Figure 5. GF-1 remote sensing image and landform near Zhangzha Town
图 6 草坡沟西北断错地貌
a-Google earth影像;b-山脊位错;c-断层陡坎
Figure 6. Dislocation landform in northwestern Caopogou
图 7 若也得附近冲洪积的断错
a-Google earth影像;b-高分一号影像;c-地貌位错图;d-T2阶断层陡坎地实测剖面;e-采样剖面洪积扇位错
Figure 7. Dislocation of alluvial fan near Ruoyedei area
图 8 唐寨无人机航拍与DGPS测量
a-唐寨断错地貌;b-无人机航拍图;c-DGPS实测地形;d-T2阶断层陡坎地实测剖面;e-T3阶地断层陡坎实测剖面;g、f-采样剖面图
Figure 8. UAV aerial image and DGPS measurement of Tangzhai
表 1 四川九寨沟7.0级地震的震源机制解参数
Table 1. Focal mechanism solutions of the Jiuzhaigou Ms7.0 earthquake
资料来源 断层节面Ⅰ 断层节面Ⅱ 震中 震源深度
/km震级 走向/° 倾角/° 滑动角/° 走向/° 倾角/° 滑动角/° CENC 326 62 15 64 77 151 103.82°E 33.20°N 20 M7.0 Global-CMT 150 78 13 242 77 150 103.90°E 33.21°N 14.9 Ms6.5 IGP-CEA 153 84 33 246 57 173 103.85°E 33.19°N 13.5 Mw6.5 
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表 2 AMS 14C样品测年结果
Table 2. The dating reults of AMS14C samples
样品编号 实验室样品编号 采样深度/m 13C/12C 样品岩性 年龄结果/a BP JZG-C-01 440594 1.8 25.4% 碳屑 2450±30 JZG-C-02 446948 1.2 24.9% 碳屑 5110±30 JZG-C-03 440593 1.0 26.9% 碳屑 1470±30 注:样品由美国BETA实验室测试
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[1] Tapponnier P, Zhiqin X, Roger F, et al. Oblique stepwise rise and growth of the Tibet plateau[J]. Science, 2001, 294(5547):1671. doi: 10.1126/science.105978 [2] Zhang P Z, Shen Z, Wang M, et al. Continuous deformation of the Tibetan Plateau from global positioning system data[J]. Geology, 2004, 32(9):809~812. doi: 10.1130/G20554.1 [3] Beaumont C, Jamieson R A, Nguyen M H, et al. Himalayan tectonics explained by extrusion of a low-viscosity crustal channel coupled to focused surface denudation[J]. Nature, 2001, 414(6865):738. doi: 10.1038/414738a [4] Wang Q, Zhang PZ, Freymueller JT, et al. Present-day crustal deformation in China constrained by global positioning system measurements[J]. Science, 2001, 294(5542):574. doi: 10.1126/science.1063647 [5] 马杏垣.中国岩石圈动力学地图集[M].北京:中国地图出版社, 1989. 16.MA Xingyuan. Lithospheric Dynamics Atlas of China[M]. Beijing:SinoMaps Press, 1989. 16. (in Chinese) [6] 周荣军, 蒲晓虹, 何玉林, 等.四川岷江断裂带北段的新活动、岷山断块的隆起及其与地震活动的关系[J].地震地质, 2000, 22(3):285~294. http://d.wanfangdata.com.cn/Periodical/dzdz200003009ZHOU Rongjun, PU Xiaohong, HE Yulin, et al. Recent activity of Minjiang fault zone, uplift of Minshan block and their relationship with seimicacity of Sichuan[J]. Seismology and Geology, 2000, 22(3):285~294. (in Chinese with English abstract) http://d.wanfangdata.com.cn/Periodical/dzdz200003009 [7] 唐文清, 刘宇平, 陈智梁, 等.岷山隆起边界断裂构造活动初步研究[J].沉积与特提斯地质, 2004, 24(4):31~34. http://d.wanfangdata.com.cn/Periodical/yxgdl200404004TANG Wenqing, LIU Yuping, CHEN Zhiliang, et al. The preliminary study of the tectonic activities along the boundary faults around the Minshan uplift, western Sichuan[J]. Sedimentary Geology and Tethyan Geology, 2004, 24(4):31~34. (in Chinese with English abstract) http://d.wanfangdata.com.cn/Periodical/yxgdl200404004 [8] 周荣军, 李勇, Densmore A L, 等.青藏高原东缘活动构造[J].矿物岩石, 2006, 26(2):40~51. http://d.wanfangdata.com.cn/Periodical/kwys200602007ZHOU Rongjun, LI Yong, Densmore A L, et al. Active tectonic of the eastern margin of the Tibet plateau[J]. Journal of Mineralogy and Petrology, 26(2):40~51. (in Chinese with English abstract) http://d.wanfangdata.com.cn/Periodical/kwys200602007 [9] 李勇, 周荣军, Densmor A L, 等.青藏高原东缘龙门山晚新生代走滑-逆冲作用的地貌标志[J].第四纪研究, 2006, 26(1):40~51. http://www.cnki.com.cn/Article/CJFDTotal-DSJJ200601005.htmLI YONG, ZHOU Rongjun, Densmore A L, et al. Geomorphic evidenve for the late Ceno Zo IC Strike-SL Ipping and thrusting in Longmen outain in at the eastern margin of the Tibetan plateau[J]. Quaternary Sciences, 2006, 26(1):40~51. (in Chinese with English abstract) http://www.cnki.com.cn/Article/CJFDTotal-DSJJ200601005.htm [10] 唐荣昌, 陆联康. 1976年松潘、平武地震的地震地质特征[J].地震地质, 1981, 3(2):41~47. http://chinasciencejournal.com/index.php/DZDZ/article/view/226642TANG Rongchang, LU Liankang. On the seismic geological characteristics of 1976 Songpan-Pingwu Earthquakes[J]. Seismology and Geology, 1981, 3(2):41~47. (in Chinese with English abstract) http://chinasciencejournal.com/index.php/DZDZ/article/view/226642 [11] 胡朝忠. 塔藏断裂晚第四纪活动性研究[D]. 北京: 中国地震局地震预测研究所, 2011.HU Chaozhong. Late Quaternary activity of the Tazang fault[D]. Beijing:Institute of Earthquake Science, CEA, 2011.(in Chinese with English abstract) [12] Kirby E, Harkin N, Wang E Q, et al. Slip-rate gradients along the eastern kunlun fault[J]. Tectonics, 2006, 26(2):TC2010. [13] 张军龙, 任金卫, 陈长云, 等.东昆仑断裂带东部晚更新世以来活动特征及其大地构造意义[J].中国科学:地球科学, 2014, 44(4):654~667. http://www.doc88.com/p-2059722541243.htmlZHANG Junlong, REN Jinwei, CHEN Changyun, et al. The Late Pleistocene activity of the eastern part of east Kunlun fault zone and its tectonic significance[J]. Science China:Earth Sciences, 2014, 57(3):439~453. http://www.doc88.com/p-2059722541243.html [14] Ren J, Xu X, Yeats R S, et al. Millennial slip rates of the Tazang fault, the eastern termination of Kunlun fault:implications for strain partitioning in eastern Tibet[J]. Tectonophysics, 2013, 608(8):1180~1200. http://www.sciencedirect.com/science/article/pii/S0040195113003922 [15] 盛书中, 万永革, 王未来, 等. 2010年玉树Ms 7.1地震发震断层面参数的确定[J].地球物理学进展, 2014, 29(4):1555~1562. doi: 10.6038/pg20140409SHENG Shuzhong, WAN Yongge, WANG Weilai, et al. The fault plane parameter determination of the 2010 Yushu Ms 7.1 earthquake[J]. Process in Geophysics, 2014, 29(4):1555~1562. (in Chinese with English abstract) doi: 10.6038/pg20140409 [16] 马晓雪, 吴中海, 李家存, 等.龙门山构造带南段向西南延伸的遥感影像证据及地震地质意义[J].地质力学学报, 2016, 22(3):548~567. http://journal.geomech.ac.cn/ch/reader/view_abstract.aspx?file_no=20160311&flag=1MA Xiaoxue, WU Zhonghai, LI Jiacun, et al. Remote sensing evidence of the south segment of Long Menshan fault zone extending to southwest and its seismic geological significance[J]. Journal of Geomechanics, 2016, 22(3):548~567. (in Chinese with English abstract) http://journal.geomech.ac.cn/ch/reader/view_abstract.aspx?file_no=20160311&flag=1 [17] 李凯, 吴中海, 李家存, 等.江西九江及邻区主要断裂活动性遥感综合分析[J].地质力学学报, 2016, 22(3):577~593. http://journal.geomech.ac.cn/ch/reader/view_abstract.aspx?file_no=20160313&flag=1LI Kai, WU Zhonghai, LI Jiacun, et al. Comprehensive remote sensing analysis on activities of the main faults in Jiujiang and adjacent areas, Jiangxi[J]. Journal of Geomechanics, 2016, 22(3):577~593. (in Chinese with English abstract) http://journal.geomech.ac.cn/ch/reader/view_abstract.aspx?file_no=20160313&flag=1 [18] Anderson J G. Estimating the seismicity from geological structure for seismic-risk studies[J]. Bulletin of the Seismological Society of America, 1979, 69(1):135~158. http://www.mendeley.com/research/estimating-seismicity-geological-structure-seismicrisk-studies/ [19] Molnar P. Earthquake recurrence intervals and plate tectonics[J]. Bulletin of the Seismological Society of America, 1978, 69(1):115~133. http://bssa.geoscienceworld.org/cgi/content/abstract/69/1/115 [20] Thiel C C. "Probabilities of large earthquakes in the San Francisco bay region" and "probabilities of large scale earthquakes occurring in California on the San Andreas fault"[J].Earthquake Spectra, 1990, 6(4):811~814. doi: 10.1193/1.1585598 [21] Nishigami K. Deep crustal heterogeneity along and around the San Andreas fault system in central California and its relation to the segmentation[J]. Journal of Geophysical Research Solid Earth, 2000, 105(B4):7983~7998. doi: 10.1029/1999JB900381 [22] 邵志刚, 傅容珊, 薛霆虓, 等.昆仑山Ms 8.1级地震震后变形场数值模拟与成因机理探讨[J].地球物理学报, 2008, 51(3):805~816. http://www.cqvip.com/Main/Detail.aspx?id=27237798SHAO Zhigang, FU Rongshan, XUE Tingxiao, et al. The numerical simulation and discussion on mechanism of postseismic deformation after Kunlun Ms 8.1 Earthquake[J]. Chinese Journal of Geophysics, 2008, 51(3):805~816. (in Chinese with English abstract) http://www.cqvip.com/Main/Detail.aspx?id=27237798 [23] 张岳桥, 董树文, 侯春堂, 等.四川芦山2013年Ms7.0地震发震构造初步研究[J].地质学报, 2013, 87(6):747~758. doi: 10.1360/zd2015-45-8-1198ZHANG Yueqiao, DONG Shuwen, HOU Chuntang, et al. Preliminary study on the Seismotectonies of the 2013 Lushan Ms7.0 earthquake, West Sichuan[J]. Acta Geologica Sinica, 2013, 87(6):747~758. (in Chinese with English abstract) doi: 10.1360/zd2015-45-8-1198 [24] Molnar P. The growth of the Tibetan Plateau and Mio-Pliocene evolution of East Asian climate[J]. Palaeontologia Electronica, 2005, 8(1):131~142. [25] 张培震, 徐锡伟, 闻学泽, 等. 2008年汶川8.0级地震发震断裂的滑动速率、复发周期和构造成因[J].地球物理学报, 2008, 51(4):1066~1073. http://www.oalib.com/paper/4870683ZHANG Peizhen, XU Xiwei, WEN Xueze, et al. Slip rates and recurrence intervals of the Longmen Shan active fault zone, and tectonic implications for the mechanism of the May 12 Wenchuan earthquake, 2008, Sichuan, China[J]. Chinese Journal of Geophysics, 2008, 51(4):1066~107. (in Chinese with English abstract) http://www.oalib.com/paper/4870683 -
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