SLIP OFFSET ALONG STRIKE-SLIP FAULT DETERMINED FROM STREAM TERRACES FORMATION

doi:10.3969/j.issn.0253-4967.2019.03.004

Abstract

Abstract: Slip rate is one of the most important parameters in quantitative research of active faults. It is an average rate of fault dislocation during a particular period, which can reflect the strain energy accumulation rate of a fault. Thus it is often directly used in the evaluation of seismic hazard. Tectonic activities significantly influence regional geomorphic characteristics. Therefore, river evolution characteristics can be used to study tectonic activities characteristics, which is a relatively reliable method to determine slip rate of fault. Based on the study of the river geomorphology evolution process model and considering the influence of topographic and geomorphic factors, this paper established the river terrace dislocation model and put forward that the accurate measurement of the displacement caused by the fault should focus on the erosion of the terrace caused by river migration under the influence of topography. Through the analysis of the different cases in detail, it was found that the evolution of rivers is often affected by the topography, and rivers tend to migrate to the lower side of the terrain and erode the terraces on this side. However, terraces on the higher side of the terrain can usually be preserved, and the displacement caused by faulting can be accumulated relatively completely. Though it is reliable to calculate the slip rate of faults through the terrace dislocation on this side, a detailed analysis should be carried out in the field in order to select the appropriate terraces to measure the displacement under the comprehensive effects of topography, landform and other factors, if the terraces on both sides of the river are preserved. In order to obtain the results more objectively, we used Monte Carlo method to estimate the fault displacement and displacement error range. We used the linear equation to fit the position of terrace scarps and faults, and then calculate the terrace displacement. After 100, 000 times of simulation, the fault displacement and its error range could be obtained with 95%confidence interval. We selected the Gaoyan River in the eastern Altyn Tagh Fault as the research object, and used the unmanned air vehicle aerial photography technology to obtain the high-resolution DEM of this area. Based on the terrace evolution model proposed in this paper, we analyzed the terrace evolution with the detailed interpretation of the topography and landform of the DEM, and inferred that the right bank of the river was higher than the left bank, which led to the continuous erosion of the river to the left bank, while the terraces on the right bank were preserved. In addition, four stages of fault displacements and their error ranges were obtained by Monte Carlo method. By integrating the dating results of previous researches in this area, we got the fault slip rate of(1.80±0.51)mm/a. After comparing this result with the slip rates of each section of Altyn Tagh Fault studied by predecessors, it was found that the slip rate obtained in this paper is in line with the variation trend of the slip rate summarized by predecessors, namely, the slip rate gradually decreases from west to east, from 10~12mm/a in the middle section to about 2mm/a at the end.

Key words: offset stream terraces, strike-slip fault, slip offset, topographic effect, Altyn Tagh Fault

摘要： 滑动速率是活动断裂定量研究的重要参数，是指在一段时间内断裂两盘相对运动的平均速度，是断裂带上应变能累积速率的重要表现，常被用于评价断裂的地震危险性。区域河流地貌特征及水系演化会受到构造活动的显著影响，因此分析河流地貌演化是研究构造变化特征的重要方法，也是限定断裂滑动速率较为可靠的方法。在总结河流地貌演化过程模式的基础上，考虑地形地貌因素的影响，建立了河流阶地位错模式和位错量的测量方法，并以阿尔金断裂东端断裂近垂直穿过的高岩沟为例，建立了其河流阶地的演化过程及其与断裂位错的关系，得到了不同阶地因断裂活动形成的位错量。结合前人的阶地测年结果，估算得到了阿尔金断裂在该段的水平滑动速率为（1.80±0.51） mm/a。

关键词: 河流层状地貌, 走滑断裂, 断错位移, 地形效应, 阿尔金断裂

CLC Number:

P315.2

XU Bin-bin, ZHANG Dong-li, ZHANG Pei-zhen, ZHENG Wen-jun, BI Hai-yun, TIAN Qing-ying, ZHANG Yi-peng, XIONG Jian-guo, LI Zhi-gang. SLIP OFFSET ALONG STRIKE-SLIP FAULT DETERMINED FROM STREAM TERRACES FORMATION[J]. SEISMOLOGY AND GEOLOGY, 2019, 41(3): 587-602.

许斌斌, 张冬丽, 张培震, 郑文俊, 毕海芸, 田晴映, 张逸鹏, 熊建国, 李志刚. 冲积扇河流阶地演化对走滑断裂断错位移的限定[J]. 地震地质, 2019, 41(3): 587-602.

References

毕海芸, 郑文俊, 曾江源, 等. 2017. SfM摄影测量方法在活动构造定量研究中的应用［J］. 地震地质, 39(4):656-674. doi:10.3969/j.issn.0253-4967.2017.04.003.
BI Hai-yun, ZHENG Wen-jun, ZENG Jiang-yuan, et al. 2017. Application of SfM photogrammetry method to the quantitative study of active tectonics［J］. Seismology and Geology, 39(4):656-674(in Chinese).
陈桂华, 徐锡伟, 闻学泽, 等. 2006. 数字航空摄影测量学方法在活动构造中的应用［J］. 地球科学(中国地质大学学报), 31(3):405-410.
CHEN Gui-hua, XU Xi-wei, WEN Xue-ze, et al. 2006. Application of digital aerophotogrammetry in active tectonics［J］. Earth Science(Journal of China University of Geosciences), 31(3):405-410(in Chinese).
邓起东, 陈立春, 冉勇康. 2004. 活动构造定量研究与应用［J］. 地学前缘, 11(4):383-392.
DENG Qi-dong, CHEN Li-chun, RAN Yong-kang. 2004. Quantitative studies and applications of active tectonics［J］. Earth Science Frontiers, 11(4):383-392(in Chinese).
丁国瑜. 1995. 阿尔金活断层的古地震与分段［J］. 第四纪研究, 15(2):97-106.
DING Guo-yu. 1995. Paleoearthquakes along the Altun active fault and its segmentation［J］. Quaternary Sciences, 15(2):97-106(in Chinese).
胡小飞. 2010. 祁连山北部侵蚀速率的时空分布与构造抬升变形研究［D］. 兰州:兰州大学.
HU Xiao-fei. 2010. Researches on temporal and spatial distributions of erosion rates and tectonic deformation in the northern Qilian Shan［D］. Lanzhou University, Lanzhou(in Chinese).
李海兵, van der Woerd J, 孙知明, 等. 2008. 阿尔金断裂带康西瓦段晚第四纪以来的左旋滑移速率及其大地震复发周期的探讨［J］. 第四纪研究, 28(2):197-213.
LI Hai-bing, van der Woerd J, SUN Zhi-ming, et al. 2008. Late Quaternary left-slip rate and large earthquake recurrence time along the Kangxiwar(Orkarakax)segment of the Altyn Tagh Fault, northern Tibet［J］. Quaternary Sciences, 28(2):197-213(in Chinese).
李涛, 陈杰. 2014. 利用河流阶地限定活动逆断层相关褶皱晚第四纪变形机制和速率:方法与认识［J］. 地震地质, 36(2):478-488. doi:10.3969/j.issn.0253-4967.2014.02.016.
LI Tao, CHEN Jie. 2014. Using deformed fluvial terraces to constrain growth mechanism and rates of thrust related fold:Methods and recognition［J］. Seismology and Geology, 36(2):478-488(in Chinese).
李有利, 司苏沛, 吕胜华, 等. 2012. 构造运动和气候变化对天山北麓奎屯河阶地发育的影响作用［J］. 第四纪研究, 32(5):880-890.
LI You-li, SI Su-pei, LÜ Sheng-hua, et al. 2012. Tectonic and climatic controls on the development of the Kuitun River terraces in the northern piedmont of Tianshan Mountains［J］. Quaternary Sciences, 32(5):880-890(in Chinese).
刘华国, 冉勇康, 李安, 等. 2011. 基于P5像对与GeoEye-1影像的近地表地层产状的提取［J］. 地震地质, 33(4):951-962. doi:10.3969/j.issn.0253-4967.2011.04.018.
LIU Hua-guo, RAN Yong-kang, LI An, et al. 2011. Attitude extraction of shallow stratum based on P5 stereo images and GeoEye-1 image［J］. Seismology and Geology, 33(4):951-962(in Chinese).
刘兴旺, 袁道阳, 潘保田, 等. 2013. 由黄河阶地变形反映的兰州盆地活动构造特征［J］. 兰州大学学报(自然科学版), 49(4):459-464.
LIU Xing-wang, YUAN Dao-yang, PAN Bao-tian, et al. 2013. Active tectonic features in Lanzhou Basin reflected by Yellow River terrace deformation［J］. Journal of Lanzhou University(Natural Sciences), 49(4):459-464(in Chinese).
吕红华, 李有利. 2010. 天山北麓活动背斜带的变形特征［J］. 第四纪研究, 30(5):1003-1011.
LÜ Hong-hua, LI You-li. 2010. Tectonic deformation of active fault related fold belts in the north piedmont of the central Tianshan Mountains, NW China［J］. Quaternary Sciences, 30(5):1003-1011(in Chinese).
任治坤, 张竹琪, 陈涛, 等. 2014. 侧向侵蚀相关的走滑断裂滑动速率计算新方法［J］. 地震地质, 36(4):1020-1028. doi:10.3969/j.issn.0253-4967.2014.04.007.
REN Zhi-kun, ZHANG Zhu-qi, CHEN Tao, et al. 2014. A new method for determining slip rates of strike-slip fault associated with lateral erosion of accumulated offset［J］. Seismology and Geology, 36(4):1020-1028(in Chinese).
田晴映, 郑文俊, 张冬丽, 等. 2017. 构造活动和气候变化对河流阶地发育的影响:以祁连山北缘洪水坝河和马营河为例［J］. 地震地质, 39(6):1283-1296. doi:10.3969/j.issn.0253-4967.2017.06.013.
TIAN Qing-ying, ZHENG Wen-jun, ZHANG Dong-li, et al. 2017. Influence of tectonics and climate on the evolution of fluvial terraces:A case study of the Hongshuiba and Maying Rivers in the northern margin of the Qilian Mountains［J］. Seismology and Geology, 39(6):1283-1296(in Chinese).
徐锡伟, Tapponnier P, van der Woerd J, 等. 2003. 阿尔金断裂带晚第四纪左旋走滑速率及其构造运动转换模式讨论［J］. 中国科学(D辑), 33(10):967-974.
XU Xi-wei, Tapponnier P, van der Woerd J, et al. 2003. Late Quaternary sinistral slip rate along the Altyn Tagh Fault and its structural transformation model［J］. Science in China(Ser D), 33(10):967-974(in Chinese).
徐锡伟, 于贵华, 陈桂华, 等. 2007. 青藏高原北部大型走滑断裂带近地表地质变形带特征分析［J］. 地震地质, 29(2):201-217.
XU Xi-wei, YU Gui-hua, CHEN Gui-hua, et al. 2007. Near-surface character of permanent geologic deformation across the mega-strike-slip faults in the northern Tibetan plateau［J］. Seismology and Geology, 29(2):201-217(in Chinese).
杨景春, 李有利. 2012. 地貌学原理［M］. 第3版. 北京:北京大学出版社.
YANG Jing-chun, LI You-li. 2012. Principle of Geomorphology［M］. 3rd Edition. Peking University Press, Beijing(in Chinese).
张宁. 2016. 阿尔金断裂东端部的几何结构与运动特征［D］. 北京:中国地震局地质研究所.
ZHANG Ning. 2016. Geometry and kinematics of the eastern end of the Altyn Tagh Fault［D］. Institute of Geology, China Earthquake Administration, Beijing(in Chinese).
张培震, 李传友, 毛凤英. 2008. 河流阶地演化与走滑断裂滑动速率［J］. 地震地质, 30(1):44-57.
ZHANG Pei-zhen, LI Chuan-you, MAO Feng-ying. 2008. Strath terrace formation and strike-slip faulting［J］. Seismology and Geology, 30(1):44-57(in Chinese).
张天琪, 吕红华, 赵俊香, 等. 2014. 河流阶地演化与构造抬升速率:以天山北麓晚第四纪河流作用为例［J］. 第四纪研究, 34(2):281-291.
ZHANG Tian-qi, LÜ Hong-hua, ZHAO Jun-xiang, et al. 2014. Fluvial terrace formation and tectonic uplift rate:A case study of late Quaternary fluvial process in the north piedmont of the Tianshan, northwestern China［J］. Quaternary Sciences, 34(2):281-291(in Chinese).
郑文俊, 袁道阳, 张培震, 等. 2016. 青藏高原东北缘活动构造几何图像、运动转换与高原扩展［J］. 第四纪研究, 36(4):775-788.
ZHENG Wen-jun, YUAN Dao-yang, ZHANG Pei-zhen, et al. 2016. Tectonic geometry and kinematic dissipation of the active faults in the northeastern Tibetan plateau and their implications for understanding northeastward growth of the plateau［J］. Quaternary Sciences, 36(4):775-788(in Chinese).
郑文俊, 张培震, 袁道阳, 等. 2009. GPS观测及断裂晚第四纪滑动速率所反映的青藏高原北部变形［J］. 地球物理学报, 52(10):2491-2508.
ZHENG Wen-jun, ZHANG Pei-zhen, YUAN Dao-yang, et al. 2009. Deformation on the northern of the Tibetan plateau from GPS measurement and geologic rates of Late Quaternary along the major fault［J］. Chinese Journal of Geophysics, 52(10):2491-2508(in Chinese).
郑文涛, 杨景春, 段锋军. 2000. 武威盆地晚更新世河流阶地变形与新构造活动［J］. 地震地质, 22(3):318-328.
ZHENG Wen-tao, YANG Jing-chun, DUAN Feng-jun. 2000. A atudy on the relation between deformation of river terraces and neotectonic activity for the Wuwei Basin［J］. Seismology and Geology, 22(3):318-328(in Chinese).
Allen C R. 1962. Circum-Pacific faulting in the Philippines-Taiwan region［J］. Journal of Geophysical Research, 67(12):4795-4812.
Allen C R, Gillespie A R, Han Y, et al. 1984. Red River and associated faults, Yunnan Province, China:Quaternary geology, slip rates, and seismic hazard［J］. Geological Society of America Bulletin, 95(6):686-700.
Anderson J G. 1979. Estimating the seismicity from geological structure for seismic-risk studies［J］. Bulletin of the Seismological Society of America, 69(1):135-158.
Antoine P, Lautridou J P, Laurent M. 2000. Long-term fluvial archives in NW France:Response of the Seine and Somme rivers to tectonic movements, climatic variations and sea-level changes［J］. Geomorphology, 33(3-4):183-207.
Bi H, Zheng W, Ge W, et al. 2018. Constraining the distribution of vertical slip on the South Heli Shan Fault(northeastern Tibet)from high-resolution topographic data［J］. Journal of Geophysical Research:Solid Earth, 123(3):2484-2501.
Burbank D W, Leland J, Fielding E, et al. 1996. Bedrock incision, rock uplift and threshold hillslopes in the northwestern Himalayas［J］. Nature, 379(6565):505-510.
Burnett A W, Schumm S A. 1983. Alluvial-river response to neotectonic deformation in Louisiana and Mississippi［J］. Science, 222(4619):49-50.
Chappell J. 1983. A revised sea-level record for the last 300, 000 years from Papua New Guinea［J］. Search, 14(3):99-101.
Costa J E, Baker V R. 1982. Surficial geology:Building with the earth［J］. American Scientist, (1):80-81.
Cowgill E. 2007. Impact of riser reconstructions on estimation of secular variation in rates of strike-slip faulting:Revisiting the Cherchen River site along the Altyn Tagh Fault, NW China［J］. Earth and Planetary Science Letters, 254(3-4):239-255.
England P, Houseman G. 1986. Finite strain calculations of continental deformation:2. Comparison with the India-Asia collision zone［J］. Journal of Geophysical Research:Solid Earth, 91(B3):3664-3676.
England P, Molnar P. 1990. Surface uplift, uplift of rocks, and exhumation of rocks［J］. Geology, 18(12):1173-1177.
England P, Molnar P. 1997. Active deformation of Asia:From kinematics to dynamics［J］. Science, 278(5338):647-650.
Frankel K L, Dolan J F, Finkel R C, et al. 2007. Spatial variations in slip rate along the Death Valley-Fish Lake Valley fault system determined from LiDAR topographic data and cosmogenic ¹⁰Be geochronology［J］. Geophysical Research Letters, 34(18):219-230.
Gold R D, Cowgill E, Arrowsmith J R, et al. 2009. Riser diachroneity, lateral erosion, and uncertainty in rates of strike-slip faulting:A case study from Tuzidun along the Altyn Tagh Fault, NW China［J］. Journal of Geophysical Research:Solid Earth, 114(B4):B04401.
Hetzel R. 2013. Active faulting, mountain growth, and erosion at the margins of the Tibetan plateau constrained by in situ-produced cosmogenic nuclides［J］. Tectonophysics, 582(1):1-24.
Hetzel R, Niedermann S, Tao M, et al. 2002. Low slip rates and long-term preservation of geomorphic features in Central Asia［J］. Nature, 417(6887):428-432.
Hu X, Pan B, Kirby E, et al. 2015. Rates and kinematics of active shortening along the eastern Qilian Shan, China, inferred from deformed fluvial terraces［J］. Tectonics, 34(12):2478-2493.
Huang W. 1993. Morphologic patterns of stream channels on the active Yishi Fault, southern Shandong Province, eastern China:Implications for repeated great earthquakes in the Holocene［J］. Tectonophysics, 219(4):283-304.
Klinger Y, Etchebes M, Tapponnier P, et al. 2011. Characteristic slip for five great earthquakes along the Fuyun Fault in China［J］. Nature Geoscience, 4(6):389-392.
Lensen G J. 1968. Analysis of progressive fault displacement during downcutting at the branch river terraces, South Island, New Zealand［J］. Geological Society of America Bulletin, 79(5):545-555.
Li C, Zhang P Z, Yin J, et al. 2009. Late Quaternary left-lateral slip rate of the Haiyuan Fault, northeastern margin of the Tibetan plateau［J］. Tectonics, 28:TC5010.
Maddy D, Bridgland D R, Green C P. 2000. Crustal uplift in southern England:Evidence from the river terrace records［J］. Geomorphology, 33(3):167-181.
Maruyama T, Lin A. 2000. Tectonic history of the Rokko active fault zone(southwest Japan)as inferred from cumulative offsets of stream channels and basement rocks［J］. Tectonophysics, 323(3-4):197-216.
Maruyama T, Lin A. 2002. Active strike-slip faulting history inferred from offsets of topographic features and basement rocks:A case study of the Arima Takatsuki tectonic line, southwest Japan［J］. Tectonophysics, 344(1):81-101.
Mériaux A S, Ryerson F J, Tapponnier P, et al. 2004. Rapid slip along the central Altyn Tagh Fault:Morphochronologic evidence from Cherchen He and Sulamu Tagh［J］. Journal of Geophysical Research:Solid Earth, 109(B6):B06401.
Molnar P. 1978. Earthquake recurrence intervals and plate tectonics［J］. Bulletin of the Seismological Society of America, 69(1):115-133.
Molnar P, Tapponnier P. 1975. Cenozoic tectonics of Asia:Effects of a continental collision:Features of recent continental tectonics in Asia can be interpreted as results of the India-Eurasia collision［J］. Science, 189(4201):419-426.
Pan B, Burbank D, Wang Y, et al. 2003. A 900 k.y. record of strath terrace formation during glacial-interglacial transitions in northwest China［J］. Geology, 31(11):957-960.
Pan B, Gao H, Wu G, et al. 2007. Dating of erosion surface and terraces in the eastern Qilian Shan, northwest China［J］. Earth Surface Processes and Landforms, 32(1):143-154.
Pan B, Hu X, Gao H, et al. 2013. Late Quaternary river incision rates and rock uplift pattern of the eastern Qilian Shan Mountain, China［J］. Geomorphology, 184(430):84-97.
Pan B, Su H, Hu Z, et al. 2009. Evaluating the role of climate and tectonics during non-steady incision of the Yellow River:Evidence from a 1.24Ma terrace record near Lanzhou, China［J］. Quaternary Science Reviews, 28(27):3281-3290.
Peltzer G, Tapponnier P. 1988. Formation and evolution of strike-slip faults, rifts, and basins during the India-Asia collision:An experimental approach［J］. Journal of Geophysical Research:Solid Earth, 93(B12):15085-15117.
Peng Y J, Lu Y J, Xu J, et al. 2012. Seismic risk zoning in Bohai and its inspiration to engineering earthquake resistance［J］. Progress in Geophysics, 27(1):18-28.
Replumaz A, Lacassin R, Tapponnier P, et al. 2001. Large river offsets and Plio-Quaternary dextral slip rate on the Red River Fault(Yunnan, China)［J］. Journal of Geophysical Research:Solid Earth, 106(B1):819-836.
Rockwell T K, Keller E A, Dembroff G R. 1988. Quaternary rate of folding of the Ventura Avenue anticline, western Transverse Ranges, southern California［J］. Geological Society of America Bulletin, 100(6):850-858.
Sieh K E, Jahns R H. 1984. Holocene activity of the San Andreas Fault at Wallace Creek, California［J］. Geological Society of America Bulletin, 95(8):883-896.
Tapponnier P, Xu Z Q, Roger F, et al. 2001. Oblique stepwise rise and growth of the Tibet plateau［J］. Science, 294(5547):1671-1677.
van der Woerd J, Tapponnier P, Ryerson F, et al. 2002. Uniform postglacial slip-rate along the central 600km of the Kunlun Fault(Tibet), from ²⁶Al, ¹⁰Be, and ¹⁴C dating of riser offsets, and climatic origin of the regional morphology［J］. Geophysical Journal of the Royal Astronomical Society, 148(3):356-388.
Weldon R J, Sieh K E. 1985. Holocene rate of slip and tentative recurrence interval for large earthquakes on the San Andreas Fault, Cajon Pass, southern California［J］. Geological Society of America Bulletin, 96(6):793-812.
Whipple K X, Hancock G S, Anderson R S. 2000. River incision into bedrock:Mechanics and relative efficacy of plucking, abrasion, and cavitation［J］. Geological Society of America Bulletin, 112(3):490-503.
Wittlinger G, Tapponnier P, Poupinet G, et al. 1998. Tomographic evidence for localized lithospheric shear along the Altyn Tagh Fault［J］. Science, 282(5386):74-76.
Yan B, Lin A. 2015. Systematic deflection and offset of the Yangtze River drainage system along the strike-slip Ganzi-Yushu-Xianshuihe fault zone, Tibetan plateau［J］. Journal of Geodynamics, 87:13-25.
Zhang P Z, Molnar P, Xu X. 2007. Late Quaternary and present-day rates of slip along the Altyn Tagh Fault, northern margin of the Tibetan plateau［J］. Tectonics, 26:TC5010.
Zhang P Z, Shen Z, Wang M, et al. 2004. Continuous deformation of the Tibetan plateau from global positioning system data［J］. Geology, 32(9):809-812.
Zhang Y Q, Vergely P, Mercier J. 1995. Active faulting in and along the Qinling Range(China)inferred from SPOT imagery analysis and extrusion tectonics of South China［J］. Tectonophysics, 243(1):69-95.
Zheng W J, Zhang H P, Zhang P Z, et al. 2013a. Late Quaternary slip rates of the thrust faults in western Hexi Corridor(northern Qilian Shan, China)and their implications for northeastward growth of the Tibetan plateau［J］. Geosphere, 9(2):342-354.
Zheng W J, Zhang P Z, He W G, et al. 2013b. Transformation of displacement between strike-slip and crustal shortening in the northern margin of the Tibetan plateau:Evidence from decadal GPS measurements and late Quaternary slip rates on faults［J］. Tectonophysics, 584(1):267-280.
Zheng W, Zhang P, Ge W, et al. 2013c. 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.

[1]	YE Yu-hui, WU Lei, WANG Yi-ping, LOU Qian-qian, CHEN Li-qi, GAO Shi-bao, LIN Xiu-bin, CHENG Xiao-gan, CHEN Han-lin. LATE QUATERNARY ACTIVE TECTONICS OF THE NORTH ALTYN FAULT [J]. SEISMOLOGY AND GEOLOGY, 2022, 44(2): 297-312.
[2]	SHAO Yan-xiu, LIU-ZENG Jing, GAO Yun-peng, WANG Wen-xin, YAO Wen-qian, HAN Long-fei, LIU Zhi-jun, ZOU Xiao-bo, WANG Yan, LI Yun-shuai, LIU Lu. COSEISMIC DISPLACEMENT MEASUREMENT AND DISTRIBUTED DEFORMATION CHARACTERIZATION: A CASE OF 2021 M_W7.4 MADOI EARTHQUAKE [J]. SEISMOLOGY AND GEOLOGY, 2022, 44(2): 506-523.
[3]	MIAO Shu-qing, HU Zong-kai, ZHANG Ling, YANG Hai-bo, YANG Xiao-ping. GEOMORPHIC ANALYSIS OF STRIKE-SLIP FAULTING AT THE TOP OF ALLUVIAL FAN: A CASE STUDY AT AHEBIEDOU RIVER ON THE EASTERN MARGIN OF TACHENG BASIN, XINJIANG, CHINA [J]. SEISMOLOGY AND GEOLOGY, 2021, 43(3): 488-503.
[4]	LEI Sheng-xue, RAN Yong-kang, LI Yan-bao, LI Hai-ou, GAO Ye, GUO Wei. A POSSIBLE MECHANISM FOR REVERSE CROSS-BASIN FAULT IN GANYANCHI ASYMMETRIC PULL-APART BASIN ALONG THE HAIYUAN FAULT [J]. SEISMOLOGY AND GEOLOGY, 2021, 43(1): 36-52.
[5]	YAO Sheng-hai, GAI Hai-long, YIN Xiang, LIU Wei, ZHANG Jia-qing, YUAN Jian-xin. TECTONIC GEOMORPHOLOGY AND QUATERNARY SLIP RATE OF THE XITIESHAN SECTION OF THE NORTHERN MARGIN FAULT OF QAIDAM BASIN [J]. SEISMOLOGY AND GEOLOGY, 2020, 42(6): 1385-1400.
[6]	QIN Jin-tang, CHEN Jie, LI Tao. RESIDUAL POST-IR IRSL SIGNALS OF POTASSIUM FELDSPAR FROM MODERN SAG POND DEPOSITS OF CENTRAL ALTYN TAGH FAULT: IMPLICATION FOR DATING YOUNG PALEOSEISMIC EVENTS [J]. SEISMOLOGY AND GEOLOGY, 2020, 42(4): 981-992.
[7]	KANG Wen-jun, XU Xi-wei, YU Gui-hua, LUO Jia-hong. COMPARISON STUDY OF TWO KINDS OF CODES TO MEASURE FAULT-OFFSETS BASED ON MATLAB: A CASE STUDY ON EASTERN ALTYN TAGH FAULT [J]. SEISMOLOGY AND GEOLOGY, 2020, 42(3): 732-747.
[8]	TANG Qing, ZHENG Wen-jun, SHI Lin, ZHANG Dong-li, HUANG Rong. QUANTITATIVE STUDY OF FAULT ACTIVITY BASED ON HIGH-PRECISION AIRBORNE LiDAR DATA: A CASE OF XIAOHONGSHAN FAULT IN XIANGSHAN-TIANJINGSHAN FAULT ZONE [J]. SEISMOLOGY AND GEOLOGY, 2020, 42(2): 366-381.
[9]	SHAO Yan-xiu, YUAN Dao-yang, LIU-ZENG Jing, Jerome Van der Woerd, LI Zhi-gang, WU Lei, LIU Fang-bin. THE PALEOSEISMIC SURFACE RUPTURE AT SOUTH OF CENTRAL ALTYN TAGH FAULT AND ITS TECTONIC IMPLICATION [J]. SEISMOLOGY AND GEOLOGY, 2020, 42(2): 435-454.
[10]	LI Bing-shuai, YAN Mao-du, ZHANG Wei-lin, YANG Yong-peng, ZHANG Da-wen, CHEN Yi, GUAN Chong. THE MECHANISMS OF ARCUATE STRUCTURES ON THE SOUTH SIDE OF THE ALTYN TAGH FAULT AND THEIR TECTONIC IMPLICATIONS [J]. SEISMOLOGY AND GEOLOGY, 2019, 41(2): 300-319.
[11]	HA Guang-hao, WU Zhong-hai, MA Feng-shan, ZENG Qing-li, ZHANG Lu-qing, GAI Hai-long. FIRST REPORT OF BERO ZECO ACTIVE FAULT IN GÊRZÊ, NORTHERN TIBET [J]. SEISMOLOGY AND GEOLOGY, 2019, 41(2): 436-446.
[12]	HUANG Wei-liang, YANG Xiao-ping, LI Sheng-qiang, YANG Hai-bo. THE LATE QUATERNARY ACTIVITY CHARACTERISTICS OF THE STRIKE-SLIP FAULTS IN THE TIANSHAN OROGENIC BELT: A CASE STUDY OF THE KAIDUHE FAULT [J]. SEISMOLOGY AND GEOLOGY, 2018, 40(5): 1040-1058.
[13]	LIANG Ou-bo, REN Jun-jie, LÜ Yan-wu. THE RESPONSE OF FLUVIAL GEOMORPHOLOGIC CHARACTERISTICS OF THE FUJIANG DRAINGE BASIN TO ACTIVITY OF THE HUYA FAULT ZONE [J]. SEISMOLOGY AND GEOLOGY, 2018, 40(1): 42-56.
[14]	YAN Bing, JIA Dong. SYSTEMATIC OFFSET OF BEDROCK CHANNELS ALONG ACTIVE STRIKE-SLIP FAULTS ON THE EASTERN TIBETAN PLATEAU [J]. SEISMOLOGY AND GEOLOGY, 2017, 39(6): 1127-1142.
[15]	MIN Wei, LIU Yu-gang, CHEN Tao, SHU Peng, YU Zhong-yuan. THE QUANTATIVE STUDY ON ACTIVITY OF DENGDENGSHAN-CHIJIACIWO FAULTS SINCE LATE QUATERNARY [J]. SEISMOLOGY AND GEOLOGY, 2016, 38(3): 503-522.