西秦岭临潭-宕昌断裂第四纪最新活动特征

doi:10.3969/j.issn.0253-4967.2021.01.005

地震地质 ›› 2021, Vol. 43 ›› Issue (1): 72-91.DOI: 10.3969/j.issn.0253-4967.2021.01.005

西秦岭临潭-宕昌断裂第四纪最新活动特征

张波^1),2), 田勤俭³⁾, 王爱国²⁾, 李文巧^3),*, 徐岳仁³⁾, 高泽民¹⁾

1)甘肃兰州地球物理国家野外科学观测研究站, 兰州 730000;
2)中国地震局地质研究所, 北京 100029;
3)中国地震局地震预测研究所, 北京 100036

收稿日期:2020-01-09 修回日期:2020-03-02 出版日期:2021-02-20 发布日期:2021-05-06
通讯作者: *李文巧, 男, 1978年生, 博士, 副研究员, 主要从事活动构造和地震工程研究, E-mail:lwq3278@163.com。
作者简介:张波, 男, 1986年生, 2020年于中国地震局地质研究所获构造地质学博士学位, 副研究员, 主要研究方向为新生代构造与活动构造, 电话: 13919015394, E-mail: kjwxn999@163.com。
基金资助:
中国地震局地震预测研究所基本科研业务专项(2018IESLZ02, 2017IES010101); 中国地震局地震科技星火计划项目(XH19045Y); 国家自然科学基金(41602225, 41802208)共同资助

STUDIES ON NEW ACTIVITY OF LINTAN-DANGCHANG FAULT, WEST QINLING

ZHANG Bo^1),2), TIAN Qin-jian³⁾, WANG Ai-guo²⁾, LI Wen-qiao³⁾, XU Yue-ren³⁾, GAO Ze-min¹⁾

1)Lanzhou National Observatory of Geophysics, Lanzhou 730000, China;
2)Institute of Geology, China Earthquake Administration, Beijing 100029, China;
3)Institute of Earthquake Forecasting, China Earthquake Administration, Beijing 100036, China

Received:2020-01-09 Revised:2020-03-02 Online:2021-02-20 Published:2021-05-06

摘要/Abstract

摘要： 临潭-宕昌断裂是西秦岭造山带内一条重要的分支断裂, 其最新活动特征是分析西秦岭构造变形的重要依据。临潭-宕昌断裂的新构造活动强烈, 中强地震频繁, 但目前对于断裂的新活动特征研究程度较低, 未见有其全新世活动地质地貌证据的报道。文中基于遥感解译、宏观地貌分析研究断裂的长期活动表现和分段性; 同时通过地质地貌考察、无人机摄影测量、差分GPS和放射性碳测年等方法定量研究断裂的新活动特征; 最后基于研究结果探讨了断裂及附近区域的地震危险性和区域构造变形。结果表明: 根据断层迹线收敛程度和宏观地貌差异, 可将临潭-宕昌断裂分为西、中、东3段; 断裂的运动性质以左旋走滑为主, 兼具逆冲分量, 左旋走滑使洮河及其支流、冲沟和山脊等发生同步左旋拐弯, 最大左旋位移可达3km, 逆冲分量使新近纪盆地边缘和内部形成300~500m的垂向位移; 断裂的最新活动时代为全新世, 限定了1次2090~7745aBP(置信度为2σ)的全新世古地震事件; 全新世早期以来, 临潭-宕昌断裂东段主干断裂的左旋走滑速率为0.86~1.65mm/a, 垂直滑动速率为0.05~0.10mm/a。临潭-宕昌断裂分配了约2mm/a的左旋走滑分量, 是东昆仑-西秦岭阶区变形分配的关键断裂之一。

关键词: 临潭-宕昌断裂, 全新世活动, 滑动速率, 岷县-漳县M_S6.6地震, 西秦岭

Abstract: Located in the intervening zone between Tibetan plateau and surrounding blocks, the Lintan-Dangchang Fault(LDF)is characterized by north-protruding arc-shape, complex structures and intense fault activity. Quantitative studies on its new activity play a key role in searching the seismogenic mechanism, building regional tectonic model and understanding the tectonic interaction between Tibetan plateau and surrounding blocks. The LDF has strong neotectonic activities, and moderate-strong earthquakes occur frequently(three M6~7 earthquakes occurred in the past 500 years, including the July 22nd, 2013, Minxian-Zhangxian M_S6.6 earthquake), but the new activity of the fault is poorly known, the geological and geomorphological evidence of the Holocene activity has not been reported yet. Based on remote sensing interpretation and macro-landform analysis, this paper studies the long-term performance of LDF. Based on the study of fault activity, unmanned aircraft vehicle photogrammetry and differential GPS, radiocarbon dating, etc., the latest activity of LDF is quantitatively studied. Then the research results, historical strong earthquakes and small earthquake distribution are comprehensively analyzed for studying the seismogenic mechanism and constructing regional tectonic models. The results are as follows: Firstly, the fault geometry is complex and there are many branch faults. According to the convergence degree of the fault trace and the fault-controlled macroscopic topography, the LDF is divided into three segments: the west, the middle and the east. The west segment contains two fault branches(the south and the north)and the south Hezuo Fault. The south branch of the west segment mainly dominates the Jicang Neogene Basin, and the south Hezuo Fault controls the south boundary of Hezuo Basin. The middle segment has more convergent and stable trace, consisting of the main fault and south Hezuo Fault, and these faults separate the main planation surface of the Tibetan plateau and Lintan Basin surface geologically and geomorphologically. The fault traces in the east segment are sparsely distributed, and the terrain is characterized by hundreds of meters of uplifts. The branch faults include the main fault, Hetuo Fault, Muzhailing Fault and Bolinkou Fault, each controlling differential topography. Secondly, the motion property of the LDF is mainly left-lateral strike-slip, with a relative smaller portion of vertical slip. The left-lateral strike-slip offset the Taohe River and its tributaries, gullies and ridges synchronously, and the maximum left-lateral displacement of the tributary of Taohe River can reach 3km. Meanwhile, the pull-apart basins and push-up ridges associated with the left-lateral fault slip are also developed in the fault zone. The performance of vertical slip includes tilting of the main planation surface, vertical offsets of the boundary and interior of Neogene basin and hundred meter-scale differential topography. The vertical offset of the Neogene is 300~500m. Thirdly, one fault profile was newly discovered in Gongqia Village, revealing a complete sequence of pre-earthquake-coseismic-postseismic deposition, and this event was constrained by the radiocarbon ages of pre-earthquake and post-earthquake deposition. The event was constrained to be 2090~7745aBP(confidence 2σ), which for the first time confirmed the Holocene activity of the fault. Fourthly, a gully with two terraces at least on the west side of Zhuangzi Village in the east segment of the main fault retains a typical faulted landform. The T2/T1 terrace riser of the gully has a left-handed dislocation of 6.3~11.8m, and the scarp height on terrace T2 is 0.4~0.7m, the radiocarbon age of the terrace T2 is7170~7310aBP, so the derived left-lateral strike-slip rate since the early Holocene in the east segment of the main fault is 0.86~1.65mm/a, and the vertical slip rate is 0.05~0.10mm/a. The derived slip rates are in line with the regional tectonic model proposed by the predecessors, so the LDF plays an important role in the internal deformation of the West Qinling. The clockwise rotation of the middle to east segments of the LDF acts as an obstacle to the left-lateral strike-slip motion, which inevitably leads to the redistribution and rapid release of stress, so earthquakes in the middle-east segment of the LDF are unusually frequent.

Key words: Lintan-Dangchang Fault, Holocene activity, slip rate, Minxian-Zhangxian M_S6.6 earthquake, West Qinling

中图分类号:

P315.2

张波, 田勤俭, 王爱国, 李文巧, 徐岳仁, 高泽民. 西秦岭临潭-宕昌断裂第四纪最新活动特征[J]. 地震地质, 2021, 43(1): 72-91.

ZHANG Bo, TIAN Qin-jian, WANG Ai-guo, LI Wen-qiao, XU Yue-ren, GAO Ze-min. STUDIES ON NEW ACTIVITY OF LINTAN-DANGCHANG FAULT, WEST QINLING[J]. SEISMOLOGY AND GEOLOGY, 2021, 43(1): 72-91.

参考文献

[1] 艾明. 2018. 高精度摄影测量方法在活动构造定量参数获取中的应用: 以茶卡盆地两侧断裂为例 [D]. 北京: 中国地震局地质研究所.
AI Ming.2018. Application of high-precision photogrammetry method in obtaining quantitative parameters of active tectonics: A case study of the faults on the two sides of the Caka Basin [D]. Institute of Geology, China Earthquake Administration, Beijing(in Chinese).
[2] 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).
[3] 顾功叙. 1983. 中国地震目录 [Z]. 北京: 科学出版社.
GU Gong-xu. 1983. Catalogue of Chinese Earthquake [Z]. Science Press, Beijing(in Chinese).
[4] 国家地震局震害防御司. 1995. 中国历史强震目录 [Z]. 北京: 地震出版社.
Department of Earthquake Disaster Prevention, State Seismological Bureau. 1995. Catalogue of Chinese Historical Strong Earthquakes [Z]. Seismological Press, Beijing(in Chinese).
[5] 何文贵, 郑文俊, 王爱国, 等. 2013. 临潭-宕昌断裂新活动特征与岷县漳县M_S6.6地震关系研究[J]. 地震工程学报, 35(4): 751—760.
HE Wen-gui, ZHENG Wen-jun, WANG Ai-guo, et al. 2013. New activities of Lintan-Dangchang Fault and its relations to Minxian-Zhangxian M_S6.6 earthquake[J]. China Earthquake Engineering Journal, 35(4): 751—760(in Chinese).
[6] 何文贵, 周志宇, 马尔曼, 等. 2006. 岷县-卓尼5.0级地震的基本特征和地质背景研究[J]. 地震研究, 29(4): 373—378.
HE Wen-gui, ZHOU Zhi-yu, MA Er-man, et al. 2006. Basic features and geological background of the Minxian-Zhuoni M5.0 earthquake on Sep.7, 2004[J]. Journal of Seismological Research, 29(4): 373—378(in Chinese).
[7] 李翠芹, 沈旭章. 2013. 岷县漳县M_S6.6地震震源区地壳速度结构特征初步研究[J]. 地震工程学报, 35(3): 448—454.
LI Cui-qin, SHEN Xu-zhang.2013. Characteristics of crustal structures in source area of the Minxian-Zhangxian M_S 6.6 earthquake[J]. China Earthquake Engineering Journal, 35(3): 448—454(in Chinese).
[8] 李光涛, 苏刚, 程理, 等. 2019. 临潭-宕昌断裂带遥感解译及其晚第四纪活动特征研究[J]. 防灾科技学院学报, 21(2): 21—28.
LI Guang-tao, SU Gang, CHENG Li, et al. 2019. Remote sensing interpretation of Lintan-Dangchang fault zone and its late Quaternary activity characteristics[J]. Journal of Institute of Disaster Prevention, 21(2): 21—28(in Chinese).
[9] 李晓峰, 裴惠娟, 徐辉, 等. 2013. 2013年7月22日岷县漳县6.6级地震震源机制解[J]. 地震工程学报, 35(3): 459—462.
LI Xiao-feng, PEI Hui-juan, XU Hui, et al. 2013. Focal mechanism of the Minxian-Zhangxian M_S6.6 earthquake[J]. China Earthquake Engineering Journal, 35(3): 459—462(in Chinese).
[10] 刘君, 杜学彬, 范莹莹, 等. 2013. 甘肃岷县漳县M_S6.6地震前的地电阻率变化[J]. 地震工程学报, 35(4): 819—826.
LIU Jun, DU Xue-bin, FAN Ying-ying, et al. 2013. The geo-electrical resistivity anomaly before the Minxian-Zhangxian M_S6.6 earthquake in Gansu[J]. China Earthquake Engineering Journal, 35(4): 819—826(in Chinese).
[11] 潘保田, 高红山, 李吉均. 2002. 关于夷平面的科学问题: 兼论青藏高原夷平面[J]. 地理科学, 22(5): 520—526.
PAN Bao-tian, GAO Hong-shan, LI Ji-jun.2002. On problems of planation surface: A discussion on the planation surface in Qinghai-Xizang Plateau[J]. Scientia Geographica Sinica, 22(5): 520—526(in Chinese).
[12] 荣代潞, 李亚荣. 2013. 2013年7月22日岷县漳县6.6级地震前地震相关长度增长现象[J]. 地震工程学报, 35(3): 455—458.
RONG Dai-lu, LI Ya-rong.2013. Analysis of the growth phenomenon of seismic correlation length prior to Minxian-Zhangxian earthquake[J]. China Earthquake Engineering Journal, 35(3): 455—458(in Chinese).
[13] 谭毅培, 曹井泉, 陈继峰, 等. 2015. 2013年甘肃岷县漳县M_S6.6地震余震序列时域衰减特征分析[J]. 地球物理学报, 58(9): 3222—3231.
TAN Yi-pei, CAO Jing-quan, CHEN Ji-feng, et al. 2015. Temporal decay characteristics of the aftershock sequence of the 2013 Minxian-Zhangxian, Gansu, M_S6.6 earthquake[J]. Chinese Journal of Geophysics, 58(9): 3222—3231(in Chinese).
[14] 王兰民, 吴志坚. 2013. 岷县漳县6.6级地震震害特征及其启示[J]. 地震工程学报, 35(3): 401—412.
WANG Lan-min, WU Zhi-jian.2013. Earthquake damage characteristics of the Minxian-Zhangxian M_S6.6 earthquake and its lessons[J]. China Earthquake Engineering Journal, 35(3): 401—412(in Chinese).
[15] 王林, 田勤俭, 李文巧, 等. 2019. 2017年西藏米林M_S6.9地震发震构造初探[J]. 地球物理学报, 62(7): 2549—2566.
WANG Lin, TIAN Qin-jian, LI Wen-qiao, et al. 2019. Preliminary investigation of the seismogenic structure of the 2017 M_S6.9 Milin earthquake in Tibet[J]. Chinese Journal of Geophysics, 62(7): 2549—2566(in Chinese).
[16] 许冲, 徐锡伟, 郑文俊, 等. 2013. 2013年甘肃岷县漳县6.6级地震触发滑坡及其构造分析[J]. 地震地质, 35(3): 616—626. doi: 10.3969/j.issn.0253-4967.2013.03.015.
XU Chong, XU Xi-wei, ZHENG Wen-jun, et al. 2013. Landslides triggered by the 2013 Minxian-Zhangxian, Gansu Province M_S6.6 earthquake and its tectonic analyses[J]. Seismology and Geology, 35(3): 616—626(in Chinese).
[17] 袁道阳, 石玉成, 刘百篪. 1999. 青藏高原东北缘地区晚第四纪水系沉积物年代标尺的初步研究[J]. 地震地质, 21(1): 1—8.
YUAN Dao-yang, SHI Yu-cheng, LIU Bai-chi.1999. Study on the time scale of late Quaternary hydrogenic sediments along the northeastern margin of Qinghai-Xizang Plateau[J]. Seismology and Geology, 21(1): 1—8(in Chinese).
[18] 袁道阳, 张培震, 刘百篪, 等. 2004. 青藏高原东北缘晚第四纪活动构造的几何图像与构造转换[J]. 地质学报, 78(2): 270—278.
YUAN Dao-yang, ZHANG Pei-zhen, LIU Bai-chi, et al. 2004. Geometrical imagery and tectonic transformation of late Quaternary active tectonics in northeastern margin of Qinghai-Xizang Plateau[J]. Acta Geologica Sinica, 78(2): 270—278(in Chinese).
[19] 张培震, 郑德文, 尹功明, 等. 2006. 有关青藏高原东北缘晚新生代扩展与隆升的讨论[J]. 第四纪研究, 26(1): 5—13.
ZHANG Pei-zhen, ZHENG De-wen, YIN Gong-ming, et al. 2006. Discussion on late Cenozoic growth and rise of northeastern margin of the Tibetan plateau[J]. Quaternary Sciences, 26(1): 5—13(in Chinese).
[20] 张元生, 冯红武, 陈继峰, 等. 2013. 基于地震学资料探讨2013年岷县漳县6.6级地震发震构造[J]. 地震工程学报, 35(3): 419—424.
ZHANG Yuan-sheng, FENG Hong-wu, CHEN Ji-feng, et al. 2003. Study on seismogenic structure of 2013 Minxian-Zhangxian M_S6.6 earthquake with seismological data[J]. China Earthquake Engineering Journal, 35(3): 419—424(in Chinese).
[21] 赵凌强, 詹艳, 陈小斌, 等. 2015a. 西秦岭造山带(中段)及其两侧地块深部电性结构特征[J]. 地球物理学报, 58(7): 2460—2472.
ZHAO Ling-qiang, ZHAN Yan, CHEN Xiao-bin, et al. 2015a. Deep electrical structure of the central West Qinling orogenic belt and blocks on its either side[J]. Chinese Journal of Geophysics, 58(7): 2460—2472(in Chinese).
[22] 赵凌强, 詹艳, 赵国泽, 等. 2015b. 基于深部电性结构特征的2013年甘肃岷县漳县M_S6.6地震孕震环境探讨[J]. 地震地质, 37(2): 541—554. doi: 10.3969/j.issn.0253-4967.2015.02.016.
ZHAO Ling-qiang, ZHAN Yan, ZHAO Guo-ze, et al. 2015b. The seismogenic environment of the 2013 Minxian-Zhangxian M_S6.6 earthquake based on the deep electrical structure[J]. Seismology and Geology, 37(2): 541—554(in Chinese).
[23] 郑文俊, 雷中生, 袁道阳, 等. 2007a. 1573年甘肃岷县地震史料考证与发震构造探讨[J]. 中国地震, 23(1): 75—83.
ZHENG Wen-jun, LEI Zhong-sheng, YUAN Dao-yang, et al. 2007a. Textual research on the historical data of the 1573AD Minxian earthquake in Gansu Province and discussion on its seismogenic structure[J]. Earthquake Research in China, 23(1): 75—83(in Chinese).
[24] 郑文俊, 雷中生, 袁道阳, 等. 2007b. 1837年甘肃岷县北6级地震考证与发震构造分析[J]. 地震, 27(1): 120—130.
ZHENG Wen-jun, LEI Zhong-sheng, YUAN Dao-yang, et al. 2007b. Structural research on the 1837 northern Minxian M6 earthquake in Gansu Province and its causative structure[J]. Earthquake, 27(1): 120—130(in Chinese).
[25] 郑文俊, 刘小凤, 赵广堃, 等. 2005. 2003年11月13日甘肃岷县M_S5.2地震基本特征[J]. 西北地震学报, 27(1): 61—65.
ZHENG Wen-jun, LIU Xiao-feng, ZHAO Guang-kun, et al. 2005. Principal features of Minxian M_S5.2 earthquake in Gansu Province[J]. Northwestern Seismological Journal, 27(1): 61—65(in Chinese).
[26] 郑文俊, 闵伟, 何文贵, 等. 2013a. 2013年甘肃岷县漳县6.6级地震震害分布特征及发震构造分析[J]. 地震地质, 35(3): 604—615. doi: 10.3969/j.issn.0253-4967.2013.03.014.
ZHENG Wen-jun, MIN Wei, HE Wen-gui, et al. 2013a. Distribution of the related disaster and the causative tectonic of the Minxian-Zhangxian M_S6.6 earthquake on July 22, 2013, Gansu, China[J]. Seismology and Geology, 35(3): 604—615(in Chinese).
[27] 郑文俊, 袁道阳, 何文贵, 等. 2013b. 甘肃东南地区构造活动与2013年岷县-漳县M_S6.6地震孕震机制[J]. 地球物理学报, 56(12): 4058—4071.
ZHENG Wen-jun, YUAN Dao-yang, HE Wen-gui, et al. 2013b. Geometric pattern and active tectonics in southeastern Gansu Province: Discussion on seismogenic mechanism of the Minxian-Zhangxian M_S6.6 earthquake on July 22, 2013[J]. Chinese Journal of Geophysics, 56(12): 4058—4071(in Chinese).
[28] 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): 1—14.
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): 1—14(in Chinese).
[29] 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.
[30] Johnson K, Nissen E, Saripalli S, et al. 2014. Rapid mapping of ultrafine fault zone topography with structure from motion[J]. Geosphere, 10(5): 969—986.
[31] Ramsey C B.2017. Methods for summarizing radiocarbon datasets[J]. Radiocarbon, 59(6): 1809—1833.
[32] Reimer P J, Bard E, Bayliss A, et al. 2013. IntCal13 and Marine13 radiocarbon age calibration curves 0~50000 years cal BP[J]. Radiocarbon, 55(4): 1869—1887.
[33] Westoby M J, Brasington J, Glasser N F, et al. 2012. ‘Structure-from-Motion’ photogrammetry: A low-cost, effective tool for geoscience applications[J]. Geomorphology, 179:300—314.
[34] XU C, XU X, Shyu J B H, et al. 2014. Landslides triggered by the 22 July 2013 Minxian-Zhangxian, China, M_W5.9 earthquake: Inventory compiling and spatial distribution analysis[J]. Journal of Asian Earth Sciences, 92:125—142.
[35] Zielke O, Arrowsmith J R.2012. LaDiCaoz and LiDARimager: MATLAB GUIs for LiDAR data handling and lateral displacement measurement[J]. Geosphere, 8(1): 206—221.

西秦岭临潭-宕昌断裂第四纪最新活动特征

STUDIES ON NEW ACTIVITY OF LINTAN-DANGCHANG FAULT, WEST QINLING

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	杨晨艺, 李晓妮, 冯希杰, 黄引弟, 裴跟弟. 秦岭北缘断裂带的重要分支——桃川-户县断层的浅部结构与第四纪活动性[J]. 地震地质, 2023, 45(2): 464-483.
[2]	杨源源, 李鹏飞, 路硕, 疏鹏, 潘浩波, 方良好, 郑海刚, 赵朋, 郑颖平, 姚大全. 郯庐断裂带中段F₅断裂淮河-女山湖段的古地震与垂直滑动速率[J]. 地震地质, 2022, 44(6): 1365-1383.
[3]	张秀丽, 熊建国, 张培震, 刘晴日, 姚勇, 钟岳志, 张会平, 李有利. 中更新世晚期以来中条山北麓断层滑动速率研究[J]. 地震地质, 2022, 44(6): 1403-1420.
[4]	邵延秀, 刘静, 高云鹏, 王文鑫, 姚文倩, 韩龙飞, 刘志军, 邹小波, 王焱, 李云帅, 刘璐. 同震地表破裂的位移测量与弥散变形分析——以2021年青海玛多M_W7.4地震为例[J]. 地震地质, 2022, 44(2): 506-523.
[5]	张驰, 李智敏, 任治坤, 刘金瑞, 张志亮, 武登云. 日月山断裂南段晚第四纪活动特征[J]. 地震地质, 2022, 44(1): 1-19.
[6]	张波, 王爱国, 田勤俭, 葛伟鹏, 贾伟, 姚赟胜, 袁道阳. 基于ALOS-PALSAR DEM的山体阴影图识别断裂线性——以西秦岭地区为例[J]. 地震地质, 2022, 44(1): 130-149.
[7]	闫小兵, 周永胜, 李自红, 扈桂让, 任瑞国, 郝雪景. 山西浮山断裂的晚第四纪活动与位移速率[J]. 地震地质, 2022, 44(1): 35-45.
[8]	万永魁, 沈小七, 刘瑞丰, 刘峡, 郑智江, 李媛, 张扬, 王雷. 川滇地区活动块体边界断裂现今运动和应力分布[J]. 地震地质, 2021, 43(6): 1614-1637.
[9]	李正芳, 李彦宝, 周本刚, 朱国军, 刘保金, 吴健. 北京平原大兴凸起东缘断裂全新世活动的新认识[J]. 地震地质, 2021, 43(6): 1671-1681.
[10]	常祖峰, 常昊, 李鉴林, 毛泽斌, 臧阳. 维西-乔后断裂全新世活动与古地震[J]. 地震地质, 2021, 43(4): 881-898.
[11]	刘瑞春, 张锦, 郭文峰, 陈慧, 郑亚迪, 成诚. 鄂尔多斯块体东南缘现今的变形特征与构造模式探讨[J]. 地震地质, 2021, 43(3): 540-558.
[12]	朱爽, 梁洪宝, 魏文薪, 李经纬. 天山地震带主要活动断层现今的滑动速率及其地震矩亏损[J]. 地震地质, 2021, 43(1): 249-261.
[13]	陈健龙, 张冬丽, 周宇. 利用Envisat ASAR数据探讨渭河盆地断层现今的滑动速率[J]. 地震地质, 2020, 42(2): 333-345.
[14]	罗全星, 李传友, 任光雪, 李新男, 马字发, 董金元. 阳高-天镇断裂晚第四纪活动特征及滑动速率[J]. 地震地质, 2020, 42(2): 399-413.
[15]	田镇, 杨志强, 王师迪. 喜马拉雅东构造结主要断裂的地震矩亏损与危险性评估[J]. 地震地质, 2020, 42(1): 33-49.