利用构造地貌分析日月山断裂晚更新世以来的演化

doi:10.3969/j.issn.0253-4967.2019.05.001

地震地质 ›› 2019, Vol. 41 ›› Issue (5): 1077-1090.DOI: 10.3969/j.issn.0253-4967.2019.05.001

利用构造地貌分析日月山断裂晚更新世以来的演化

李智敏^1,2, 李文巧⁴, 殷翔¹, 黄帅堂³, 张军龙⁴

1. 青海省地震局, 西宁 810001;
2. 深圳防灾减灾技术研究院, 深圳 518003;
3. 新疆维吾尔自治区地震局, 乌鲁木齐 830011;
4. 中国地震局地震预测研究所, 地震预测重点实验室, 北京 100036

收稿日期:2019-05-13 修回日期:2019-07-24 出版日期:2019-10-20 发布日期:2019-12-07
通讯作者: 张军龙,男,1973年生,副研究员,主要从事新构造、地震地质方面的研究,E-mail:448092692@qq.com。
作者简介:李智敏,男,1977年生,2005年于中国地震局兰州地震研究所获构造地质专业硕士学位,副研究员,现主要从事活动构造及其次生灾害方面的研究工作,电话:0755-82616372,E-mail:minhero_168@126.com。
基金资助:
青海省科技计划项目（2017-ZJ-775）、中央级公益性科研院所基本科研业务专项（JB-18-03）和国家自然科学基金（41372215）共同资助。

ANALYSIS OF EVOLUTION OF THE RIYUESHAN FAULT SINCE LATE PLEISTOCENE USING STRUCTURAL GEOMORPHOLOGY

LI Zhi-min^1,2, LI Wen-qiao⁴, YIN Xiang¹, HUANG Shuai-tang³, ZHANG Jun-long⁴

1. Qinghai Earthquake Agency, Xining 810001, China;
2. Shenzhen Academy of Disaster Prevention and Reduction, Shenzhen 518003, China;
3. Earthquake Agency of Xinjiang Uygur Autonomous Region, Urumqi 830011, China;
4. Key Laboratory of Earthquake Predication, Institute of Earthquake Forecasting, China Earthquake Administration, Beijing 100036, China

Received:2019-05-13 Revised:2019-07-24 Online:2019-10-20 Published:2019-12-07

摘要/Abstract

摘要： 日月山断裂位于东昆仑断裂和祁连-海原断裂等主边界断裂控制的柴达木-祁连活动块体内部，属于二级构造。该断裂构造地貌发育，研究其活动特征可获得青藏高原东北缘向外扩展的信息。文中以晚更新世以来清晰的地貌变形为重点，通过RTK测量方法获得沿断层走向的垂直位移量，基于断层生长连接理论，分析了日月山断裂的演化，并讨论其反映的动力学背景，主要获得了以下3点认识：1）根据晚更新世以来洪积扇和阶地等地貌内长约200km的3期断层陡坎的发育特征，将日月山断裂分为5段，最重要的分段位于第三重叠区（CD-3）。2）日月山断层3期位移量分布形态反映了断层由多条次级破裂生长连接而成，处于断层生长连接的第二阶段。以CD-3为界，NW侧的断层持续生长连接；东南侧的断层活动时间相对较短，活动强度相对较弱。3）断层位移量分布曲线极值指示了应变集中和应力积累的位置。以CD-3重叠区为界，NW侧应力和应变主要集中在中部及断层重叠区，东南侧应力长期积累的范围则相对分散。应力状态可能与区域构造应力挤压作用下块体内部的顺时针旋转有关。

关键词: 青藏高原, 日月山断裂, 晚更新世, 几何分段, 断层生长

Abstract: 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.

Key words: Qinghai-Tibet Plateau, Riyueshan Fault, Late Pleistocene, geometric segmentation, fault growth

中图分类号:

P315.2

李智敏, 李文巧, 殷翔, 黄帅堂, 张军龙. 利用构造地貌分析日月山断裂晚更新世以来的演化[J]. 地震地质, 2019, 41(5): 1077-1090.

LI Zhi-min, LI Wen-qiao, YIN Xiang, HUANG Shuai-tang, ZHANG Jun-long. ANALYSIS OF EVOLUTION OF THE RIYUESHAN FAULT SINCE LATE PLEISTOCENE USING STRUCTURAL GEOMORPHOLOGY[J]. SEISMOLOGY AND GEOLOGY, 2019, 41(5): 1077-1090.

参考文献

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).
邓起东, 闻学泽. 2008. 活动构造研究:历史、进展与建议［J］. 地震地质, 30(1):1-30.
DENG Qi-dong, WEN Xue-ze. 2008. A review on the research of active tectonics:History, progress and suggestions［J］. Seismology and Geology, 30(1):1-30(in Chinese).
邓起东, 张培震, 冉勇康, 等. 2002. 中国活动构造基本特征［J］. 中国科学(D辑), 32(12):1020-1030.
DENG Qi-dong, ZHANG Pei-zhen, RAN Yong-kang, et al. 2002. Basic characteristic of active tectonics of China［J］. Science in China(Ser D), 32(12):1020-1030(in Chinese).
付碧宏, 张松林, 谢小平, 等. 2006. 阿尔金断裂系西段——康西瓦断裂的晚第四纪构造地貌特征研究［J］. 第四纪研究, 26(2):228-235.
FU Bi-hong, ZHANG Song-lin, XIE Xiao-ping, et al. 2006. Late Quaternary tectono-geomorphic features along the Kangxiwar Fault, Altyn Tagh fault system, northern Tibet［J］. Quaternary Sciences, 26(2):228-235(in Chinese).
国家地震局地质研究所, 国家地震局兰州地震研究所. 1993. 祁连山-河西走廊活动断裂系［M］. 北京:地震出版社.
Institute of Geology, SSB, Lanzhou Institute of Seismology, SSB. 1993. The Qilian Mountains-Hexi Corridor Active Fault System［M］. Seismological Press, Beijing(in Chinese).
李建军, 张军龙, 郭玉涛. 2016. 晚更新世以来若尔盖盆地的地层划分及构造-气候意义［J］. 地震地质, 38(4):950-963. doi:10.3969/j.issn.0253-4967.2016.04.012.
LI Jian-jun, ZHANG Jun-long, GUO Yu-tao. 2016. Chronostratigraphic classification of Zoige Basin since Late Pleistocene and its tectonic-climate significance［J］. Seismology and Geology, 38(4):950-963(in Chinese).
李智敏, 苏鹏, 黄帅堂, 等. 2018. 日月山断裂德州段晚更新世以来的活动速率研究［J］. 地震地质, 40(3):656-671. doi:10.3969/j.issn.0253-4967.2018.03.011.
LI Zhi-min, SU Peng, HUANG Shuai-tang, et al. 2018. Slip rates of the Riyue Mt. Fault at Dezhou segment since late Pleistocene［J］. Seismology and Geology, 40(3):656-671(in Chinese).
李智敏, 李文巧, 田勤俭, 等. 2013. 青藏高原东北缘热水-日月山断裂带热水段古地震初步研究［J］. 地球物理学进展, 28(4):1766-1771.
LI Zhi-min, LI Wen-qiao, TIAN Qin-jian, et al. 2013. A preliminary study on paleo-earthquake of the Reshui segment in Reshui-Riyue Mt. fault zone, Qinghai Province［J］. Progress in Geophysics, 28(4):1766-1771(in Chinese).
冉勇康, 邓起东. 1998. 海原断裂的古地震及特征地震破裂的分级性讨论［J］. 第四纪研究, 18(3):271-278.
RAN Yong-kang, DENG Qi-dong. 1998. Paleoearthquakes along Haiyuan Fault and discussion of grading on rupture of large earthquakes［J］. Quaternary Sciences, 18(3):271-278(in Chinese).
施雅风, 贾玉连, 于革, 等. 2002. 40~30ka BP青藏高原及邻区高温大降水事件的特征、影响及原因探讨［J］. 湖泊科学, 14(1):1-11.
SHI Ya-feng, JIA Yu-lian, YU Ge, et al. 2002. Features, impacts and causes of the high temperature and large precipitation event in the Tibetan plateau and its adjacent area during 40~30ka BP［J］. Journal of Lake Sciences, 14(1):1-11(in Chinese).
田勤俭, 丁国瑜. 2006. 青藏高原北部第四纪早期断裂活动的新生性变化初步研究［J］. 第四纪研究, 26(1):32-39.
TIAN Qin-jian, DING Guo-yu. 2006. Preliminary analysis on an early Quaternary new fault trace in north of Tibetan plateau［J］. Quaternary Sciences, 26(1):32-39(in Chinese).
田勤俭, 申旭辉, 丁国瑜, 等. 2000. 海原断裂带内第三纪老龙湾拉分盆地的地质特征［J］. 地震地质, 22(3):329-336.
TIAN Qin-jian, SHEN Xu-hui, DING Guo-yu, et al. 2000. Discovery and preliminary study of the Lanlongwan Tertiary pull-apart basin in the Haiyuan fault zone［J］. Seismology and Geology, 22(3):329-336(in Chinese).
王燕, 赵志中, 乔彦松, 等. 2006. 川北若尔盖高原红原泥炭剖面孢粉记录的晚冰期以来古气候古环境的演变［J］. 地质通报, 25(7):827-832.
WANG Yan, ZHAO Zhi-zhong, QIAO Yan-song, et al. 2006. Paleoclimatic and paleoenvironmental evolution since the late glacial epoch as recorded by sporopollen from the Hongyuan peat section on the Zoige Plateau, northern Sichuan, China［J］. Geological Bulletin of China, 25(7):827-832(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).
于学峰, 周卫健, Franzen L G, 等. 2006. 青藏高原东部全新世冬夏季风变化的高分辨率泥炭记录［J］. 中国科学(D辑), 36(2):182-187.
YU Xue-feng, ZHOU Wei-jian, Franzen L G, et al. 2006. Holocene high resolution peat record of changes in a winter summer monsoon in the eastern plateau［J］. Science in China(Ser D), 36(2):182-187(in Chinese).
袁道阳, 刘百篪, 吕太乙, 等. 1997. 北祁连山东段活动断裂带古地震特征［J］. 华南地震, 17(2):24-31.
YUAN Dao-yang, LIU Bai-chi, LÜ Tai-yi, et al. 1997. Palaeoearthquake features along the eastern segment of north Qilianshan active fault zone［J］. South China Journal of Seismology, 17(2):24-31(in Chinese).
袁道阳, 刘小龙, 张培震, 等. 2003a. 青海热水-日月山断裂带古地震的初步研究［J］. 西北地震学报, 25(2):136-142.
YUAN Dao-yang, LIU Xiao-long, ZHANG Pei-zhen, et al. 2003a. A preliminary study on palaeo-earthquake events of the Reshui-Riyue Mt. active fault zone in Qinghai Province［J］. Northwestern Seismological Journal, 25(2):136-142(in Chinese).
袁道阳, 刘小龙, 张培震, 等. 2003b. 青海热水-日月山断裂带的新活动特征［J］. 地震地质, 25(1):155-165.
YUAN Dao-yang, LIU Xiao-long, ZHANG Pei-zhen, et al. 2003b. Characteristics of the modern activity of the Reshui-Riyueshan fault zone in Qinghai Province［J］. Seismology and Geology, 25(1):155-165(in Chinese).
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).
张培震, 邓起东, 张竹琪, 等. 2013. 中国大陆的活动断裂、地震灾害及其动力过程［J］. 中国科学(D辑), 43(10):1607-1620.
ZHANG Pei-zhen, DENG Qi-dong, ZHANG Zhu-qi, et al. 2013. Active faults, earthquake disasters and their dynamic processes in the mainland of China［J］. Science in China(Ser D), 43(10):1607-1620(in Chinese).
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).
郑文俊. 2009. 河西走廊及其邻区活动构造图像及构造变形模式［D］. 北京:中国地震局地质研究所.
ZHENG Wen-jun. 2009. Geometric pattern and active tectonics of the Hexi Corridor and its adjacent regions［D］. Institute of Geology, China Earthquake Administration, Beijing(in Chinese).
郑文俊, 袁道阳, 何文贵. 2004. 祁连山东段天桥沟-黄羊川断裂古地震活动习性研究［J］. 地震地质, 26(4):645-657.
ZHENG Wen-jun, YUAN Dao-yang, HE Wen-gui. 2004. Characteristics of palaeo-earthquake activity along the active Tianqiaogou-Huangyangchuan Fault on the eastern section of the Qilianshan Mountains［J］. Seismology and Geology, 26(4):645-657(in Chinese).
郑文俊, 张培震, 葛伟鹏, 等. 2012. 河西走廊北部合黎山南缘断裂晚第四纪滑动速率及其对青藏高原向北东扩展的响应［J］. 国际地震动态, (6):30.
ZHENG Wen-jun, ZHANG Pei-zhen, GE Wei-peng, et al. 2012. Late Quaternary slip rates of the southern margin thrust fault of Heli Shan at the northern Hexi Corridor and their implications for northeastward growth of the Tibetan plateau［J］. Recent Developments in World Seismology, (6):30(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).
Yuan D Y, Champagnac J D, GE W P, et al. 2011. Late Quaternary right-lateral slip rates of faults adjacent to the lake Qinghai, northeastern margin of the Tibetan plateau［J］. Geological Society of America Bulletin, 123(9-10):2016-2030.
Fossen H, Rotevatn A. 2016. Fault linkage and relay structures in extensional settings:A review［J］. Earth-Science Reviews, 154:14-28.
Kim Y S, Sanderson D J. 2005. The relationship between displacement and length of faults:A review［J］. Earth-Science Reviews, 68:317-334.
Peacock D C P, Sanderson D J. 1991. Displacements, segment linkage and relay ramps in normal fault zones［J］. Journal of Structural Geology, 13:721-733.
Peacock D C P, Nixon C W, Rotevatn A, et al. 2017. Interacting faults［J］. Journal of Structural Geology, 97:1-22. doi:10.1016/j.jsg.2017.02.008.
Tvedt A B M, Rotevatn A, Jackson A L, et al. 2013. Growth of normal faults in multilayer sequences:A 3D seismic case study from the Egersund Basin, Norwegian North Sea［J］. Journal of Structural Geology, 55:1-20. doi:10.1016/j.jsg.2013.08.002.

[1]	赵朋, 李军辉, 陶月潮, 疏鹏, 方震. 郯庐断裂带女山湖北侧探槽的新活动现象及讨论[J]. 地震地质, 2023, 45(2): 338-354.
[2]	于书媛, 黄显良, 郑海刚, 李玲利, 骆佳骥, 丁娟, 范晓冉. 2022年门源M_W6.7地震的同震破裂模型及应力研究[J]. 地震地质, 2023, 45(1): 286-303.
[3]	吴中海, 白玛多吉, 叶强, 韩帅, 史亚然, 尼玛次仁, 高扬. 西藏阿里阿鲁错地堑系的第四纪活动性、最新同震地表破裂及其地震地质意义[J]. 地震地质, 2023, 45(1): 67-91.
[4]	宋婷, 沈旭章, 梅秀苹, 焦煜媛, 李敏娟, 苏小芸, 季婉婧. 利用接收函数频率特征研究青藏高原东北缘地区的莫霍面性质[J]. 地震地质, 2022, 44(5): 1290-1312.
[5]	李宗旭, 贺日政, 冀战波, 李娱兰, 牛潇. 2009年7月24日西藏尼玛M_S5.6地震的震源机制及其构造意义[J]. 地震地质, 2022, 44(4): 992-1010.
[6]	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.
[7]	盖海龙, 李智敏, 姚生海, 李鑫. 2022年青海门源M_S6.9地震地表破裂特征的初步调查研究[J]. 地震地质, 2022, 44(1): 238-255.
[8]	何翔, 杜星星, 刘健, 李艺豪, 李群. 武威盆地第四纪沉积过程及其构造意义[J]. 地震地质, 2022, 44(1): 76-97.
[9]	刘兴旺, 袁道阳, 姚赟胜, 邹小波. 三危山断裂敦煌段古地震活动特征[J]. 地震地质, 2021, 43(6): 1398-1411.
[10]	臧阳, 俞言祥, 孟令媛, 韩颜颜. 青藏高原东北缘地震波衰减特征及地震震源参数研究[J]. 地震地质, 2021, 43(6): 1638-1656.
[11]	方东, 胡敏章, 郝洪涛. 青藏高原东南缘重力场多尺度分析及其构造含义[J]. 地震地质, 2021, 43(5): 1208-1232.
[12]	唐茂云, 刘静, 李翠平, 王伟, 张金玉, 许强. 青藏高原东南缘的新生代盆地古高度重建研究与进展[J]. 地震地质, 2021, 43(3): 576-599.
[13]	哈广浩, 任治坤, 刘金瑞, 李智敏, 李正芳, 闵伟, 周本刚. 青海都兰地区夏日哈活动断裂带的发现及其构造意义[J]. 地震地质, 2021, 43(3): 614-629.
[14]	李智敏, 李文巧, 李涛, 徐岳仁, 苏鹏, 郭鹏, 孙浩越, 哈广浩, 陈桂华, 袁兆德, 李忠武, 李鑫, 杨理臣, 马震, 姚生海, 熊仁伟, 张彦博, 盖海龙, 殷翔, 徐玮阳, 董金元. 2021年5月22日青海玛多M_S7.4地震的发震构造和地表破裂初步调查[J]. 地震地质, 2021, 43(3): 722-737.
[15]	马骏, 周本刚, 王明明, 安力科. 鲜水河断裂带折多塘断裂西北段全新世活动的地质地貌依据[J]. 地震地质, 2020, 42(5): 1021-1038.

利用构造地貌分析日月山断裂晚更新世以来的演化

ANALYSIS OF EVOLUTION OF THE RIYUESHAN FAULT SINCE LATE PLEISTOCENE USING STRUCTURAL GEOMORPHOLOGY

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