东大河阶地陡坎对民乐-大马营断裂垂直滑动速率的指示

doi:10.3969/j.issn.0253-4967.2017.06.011

地震地质 ›› 2017, Vol. 39 ›› Issue (6): 1256-1266.DOI: 10.3969/j.issn.0253-4967.2017.06.011

东大河阶地陡坎对民乐-大马营断裂垂直滑动速率的指示

雷惊昊¹, 李有利¹, 胡秀¹, 辛伟林¹, 熊建国^1,2, 钟岳志¹

1 北京大学, 城市与环境学院地表过程重点实验室, 北京 100871;
2 中山大学, 地球科学与工程学院, 广州 510275

收稿日期:2017-09-01 修回日期:2017-11-01 出版日期:2017-12-20 发布日期:2018-01-23
通讯作者: 李有利,男,教授,E-mail:liyouli@pku.edu.cn
作者简介:雷惊昊,男,1989年出生,北京大学自然地理学专业在读博士研究生,现主要研究方向为构造地貌学,电话:15120082019,E-mail:skatetangshan@vip.126.com。
基金资助:
中国地震局地震行业科研专项（201408023）与国家自然科学基金（41571001）共同资助

VERTICAL SLIP RATE OF MINLE-DAMAYING FAULT INDICATED BY SCARPS ON TERRACES OF DONGDA RIVER

LEI Jing-hao¹, LI You-li¹, HU Xiu¹, XIN Wei-lin¹, XIONG Jian-guo^1,2, ZHONG Yue-zhi¹

1 College of Urban and Environmental Science, Peking University, Beijing 100871, China;
2 School of Earth Sciences and Engineering, Sun Yat-Sen University, Guangzhou 510275, China

Received:2017-09-01 Revised:2017-11-01 Online:2017-12-20 Published:2018-01-23

摘要/Abstract

摘要： 祁连山北缘冲断带位于祁连山北缘与走廊盆地群的交界处，其中民乐-大马营断裂位于冲断带的东段民乐盆地和武威盆地之中，是民乐盆地南缘断裂。东大河由北至南横穿民乐-大马营断裂东段。其上游的支流横穿断层，其中的斜河发育了形态完整的阶地（T₁—T₆），被断层错断并在各级阶地上形成了形迹明显的断层陡坎。各级阶地上的陡坎走向近EW，并且由老至新高度依次降低，反映了断层位移量的累积。为了获得陡坎的横剖面，利用无人机对被错断的阶地实施了0.52km²范围内的扫描，生成了高精度的数字高程模型（DEM）影像，并利用它提取了各级阶地的横剖面形态。根据Thompson等（2002）的模式对各级阶地的上、下盘面分别进行线性拟合，通过蒙特卡洛模拟得到T₆—T₃的位错量95%置信区间分别为13.26～15.67m、9.74～10.13m、5.86～7.35m和5.03～5.60m。为了得到河流阶地的年代数据，在各级阶地的河流相砾石层顶部进行¹⁴ C采样，此位置的¹⁴ C年龄代表了阶地离开水面的年龄。获得T₆—T₂的年龄（Cal BP）分别为（16 405±210）a、（11 197±45）a、（5 697.5±52.5）a、（4 470.5±54.5）a和（3 137.5±77.5）a。利用各级阶地上陡坎的位错量和年代数据，对民乐-大马营断裂的垂直滑动速率线性拟合的结果为（0.91±0.09）mm/a，是1条全新世活动断裂。为人口稠密的民乐和永昌地区地震危险性分析提供了重要的地震活动性参数。

关键词: 民乐-大马营断裂, 东大河阶地, 断层陡坎, 垂直滑动速率

Abstract: The Qilianshan north-edge thrust (QNT)is located at the boundary between the northern margin of the Qilianshan mountain and Hexi Corridor, with a length over 700km. The Minle-Damaying fault (MDF), trending NWW, is part of the eastern section of the QNT, cutting through the Minle and Wuwei Basins. Hexi Corridor is a region of intense seismic activities, where many large earthquakes have been documented in history, such as the M7.5 Gaotai earthquake in 180, M8.5 Haiyuan earthquake in 1920, M8.0 Gulang earthquake in 1927 and the M7.6 Changma earthquake in 1932. While, there is no seismic record on the MDF. The Dongda River flows across the MDF from south to north. One of the tributary of the Dongda River, Xie River, has very well preserved terraces (T₆-T₁)which were offset by the MDF. On these terraces, there is clear trace of scarps, of which the height increases from terraces T₃ to T₆, indicating an accumulation of offset with time. In order to acquire the cross-section of scarps, unmanned aerial vehicle (UAV)scanning was implemented. With a digital camera mounted on, the UAV scanned an area of 0.52km² and digital elevation model (DEM)was generated with an accuracy of 0.2m vertically. The Thompson's method was utilized to conduct linear regressions on both the hanging wall and foot wall of the fault. The difference between the intercepts of the regression lines with the vertical line going through the intersection of the scarp surface on the fault surface is considered as the vertical offset. Terraces from T₆ to T₃ are very well preserved where MFD intercepts the Xie river, while T₂ and T₁ are badly eroded at the same location. Utilizing the cross-sections extracted from high resolution DEM, we estimate that the vertical offsets of T₆-T₃ are 13.26~15.67m, 9.74~10.13m, 5.86~7.35m and 5.03~5.60m, respectively, with 95%confidence interval. From the offsets of terraces, at least 4 paleo-seismic events are indentified. Terraces were dated by the AMS ¹⁴ C dating, yielding ages (cal BP)of T₆-T₂ as (16 405±210)a, (111 975±21)a, (5 697.5±210)a, (4 470.5±54.5)a and (3 137.5±77.5)a. Liner regression was performed for the relation between the ages and the offsets of terraces, resulting in the average vertical slip rate of MDF since the formation of T₆ as 0.91 average v. As the dip of MDF is about 35°, the shortening rate is estimated to be (1.3±0.13)mm/a. This study provides important parameters for the analysis of seismic activity in heavily populated Minle and Yongchang areas.

Key words: Minle-Damaying fault, offset terraces of Xie River, fault scarp, vertical slip rate

中图分类号:

P546

雷惊昊, 李有利, 胡秀, 辛伟林, 熊建国, 钟岳志. 东大河阶地陡坎对民乐-大马营断裂垂直滑动速率的指示[J]. 地震地质, 2017, 39(6): 1256-1266.

LEI Jing-hao, LI You-li, HU Xiu, XIN Wei-lin, XIONG Jian-guo, ZHONG Yue-zhi. VERTICAL SLIP RATE OF MINLE-DAMAYING FAULT INDICATED BY SCARPS ON TERRACES OF DONGDA RIVER[J]. SEISMOLOGY AND GEOLOGY, 2017, 39(6): 1256-1266.

参考文献

蔡厚维. 1987. 试谈河西走廊的新构造运动［J］. 甘肃地质, 98-105.CAI Hou-wei. 1987. A tentative discussion on new tectonic movements in Hexicorridor Gansu［J］. Gansu Geology, 98-105(in Chinese).
国家地震局地质研究所. 1993. 祁连山-河西走廊活动断裂系[M]. 北京:地震出版社.Institute of Geology, State Seismological Bureau. 1993. The Qilian Mountain-Hexi Corridor Active Fault System[M]. Seismological Press, Beijing(in Chinese).
贾文雄, 何元庆, 李宗省, 等. 2008. 祁连山区气候变化的区域差异特征及突变分析［J］. 地理学报, 63(3):257-269.JIA Wen-xiong, HE Yuan-qing, LI Zong-xing, et al. 2008. The regional difference and catastrophe of climatic change in Qilian Mt. Region［J］. Acta Geographica Sinica, 63(3):257-269(in Chinese).
蒋梅, 侯维荣, 侯远文. 1997. 民乐盆地和邻近地区M-t剖面研究及其与地震活动的关系［J］. 西北地震学报, 19(2):67-72.JIANG Mei, HOU Wei-rong, HOU Yuan-wen. 1997. On M-t profiles in and around the Minle Basin and their relation to seismic activity［J］. Northwestern Seismological Journal, 19(2):67-72(in Chinese).
刘峡, 黄立人, 杨国华, 等. 2003. 北祁连-河西走廊地区垂直形变与构造应力场关系的初步研究:三维有限元拟合结果分析［J］. 地震地质, 25(2):307-316. doi:10.3969/j.issn.0253-4967.2003.02.016.LIU Xia, HUANG Li-ren, YANG Guo-hua, et al. 2003. The relationship between vertical deformation and tectonic stress field in north Qilian mountain-Hexi corridor region-an analysis based on 3-d finite element method［J］. Seismology and Geology, 25(2):307-316(in Chinese).
刘照祥, 朱小川, 姚智慧. 1992. 青海省门源地震构造背景遥感分析［J］. 国土资源遥感, 4(4):29-33.LIU Zhao-xiang, ZHU Xiao-chuan, YAO Zhi-hui. 1992. The analysis of the structure background for Menyuan earthquake with remote sensing method in Qinghai Province［J］. Remote Sensing for Land & Resources, 4(4):29-33(in Chinese).
闵伟, 张培震, 何文贵, 等. 2002. 酒西盆地断层活动特征及古地震研究［J］. 地震地质, 24(1):35-44. doi:10.3969/j.issn.0253-4967.2002.01.004.MIN Wei, ZHANG Pei-zhen, HE Wen-gui, et al. 2002. Research on the active faults and paleoearthquakes in the Western Jiuquan Basin［J］. Seismology and Geology, 24(1):35-44(in Chinese).
戚帮申, 胡道功, 杨肖肖, 等. 2015. 祁连山新生代古海拔变化的碳氧同位素记录［J］. 地球学报, 36(3):323-332.QI Bang-shen, HU Dao-gong, YANG Xiao-xiao, et al. 2015. Paleoelevation of the Qilian mountain inferred from carbon and oxygen isotopes of Cenozoic strata［J］. Acta Geoscientia Sinica, 36(3):323-332(in Chinese).
杨海波. 2016. 祁连山北缘佛洞庙-红崖子断裂晚第四纪活动速率. 北京:中国地震局地质研究所.YANG Hai-bo. 2016. Late quaternary slip rates of the Fodongmiao-Hongyazi fault, northern margin of Qilian Shan. Institute of Geology, China Earthquake Administration, Beijing(in Chinese).
杨树锋, 陈汉林, 程晓敢, 等. 2007. 祁连山北缘冲断带的特征与空间变化规律［J］. 地学前缘, 14(5):211-221.YANG Shu-feng, CHEN Han-lin, CHENG Xiao-gan, et al. 2007. Deformation characteristics and rules of spatial change for the Northern Qilianshan thrust Belt［J］. Earth Science Frontiors, 14(5):211-221(in Chinese).
业成之. 1990. 祁连山北缘断裂带的现代构造运动［J］. 地震地质, 12(3):275-281.YE Cheng-zhi. 1990. Recent tectonic movement along the north-frontal Qilianshan fault zone［J］. Seismology and Geology, 12(3):275-281(in Chinese).
张小军, 陶明信, 董新, 等. 2008. 北祁连地区新构造运动与成矿作用［J］. 西北地质, 36(4):8-15.ZHANG Xiao-jun, TAO Ming-xin, DONG Xin, et al. 2008. Neotectonic movement and mineralization of the North Qilian Area［J］. Northwestern Geology, 36(4):8-15(in Chinese).
Hetzel R, Tao M X, Stokes S, et al. 2004. Late Pleistocene/Holocene slip rate of the Zhangye thrust(Qilian Shan, China)and implications for the active growth of the northeastern Tibetan plateau［J］. Tectonics, 23(6):TC6006.
Shackleton N J, Lamb H H, Worssam B C, et al. 1977. The oxygen isotope stratigraphic record of the late Pleistocene［J］. Philosophical Transactions of the Royal Society B:Biological Sciences, 280(972):169-182.
Thompson S C, Weldon R J, Rubin C M, et al. 2002. Late quaternary slip rates across the central Tien Shan, Kyrgyzstan, Central Asia［J］. Journal of Geophysical Research:Solid Earth, 107(B9):ETG 7-1-ETG7-32.
Zheng W J, Zhang P Z, Ge W P, et al. 2013. Late Quaternary slip rate of the South Heli Shan Fault(northern Hexi Corridor, NW China)and its implications for northeastward growth of the Tibetan plateau［J］. Tectonics, 32(2):271-293.

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东大河阶地陡坎对民乐-大马营断裂垂直滑动速率的指示

VERTICAL SLIP RATE OF MINLE-DAMAYING FAULT INDICATED BY SCARPS ON TERRACES OF DONGDA RIVER

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