涪江流域河流地貌特征对虎牙断裂带活动性的响应

doi:10.3969/j.issn.0253-4967.2018.01.004

摘要/Abstract

摘要： 青藏高原东缘岷山东边界的虎牙断裂带强震频发，但因第四系保留有限，目前对于该断裂的活动性仍认识不清。而基岩山区河流地貌与活动构造关系研究发现，河流地貌特征能够很好地记录构造活动信息。虎牙断裂带横跨涪江流域，这为通过河流地貌研究虎牙断裂的活动特征提供了条件。文中选择涪江流域SRTM 30m精度数字高程模型（DEM）数据，利用GIS技术提取了涪江流域坡度（slope）、局部起伏度（local relief）、标准化陡峭指数（k_sn）、面积-高程积分值（HI）等地貌指数，并对跨虎牙断裂带小流域盆地的平均陡峭指数（k_s）和面积-高程积分值进行对比，结合野外调查、岩性、降水与现代侵蚀速率等特征，分析讨论了涪江流域地貌特征与虎牙断裂带活动特征的关系。研究表明：1）涪江流域基本处于稳态状况，区内仅有跨雪山断裂带的河道剖面显示明显的裂点，其余跨断裂河道剖面无明显裂点存在；2）虎牙断裂带两侧地貌指数差异明显，整体上表现为西高东低，这应与虎牙断裂的逆断活动有关；3）断裂两侧的小流域地貌指数差异分析表明，沿虎牙断裂带自北向南抬升作用逐渐增强，反映了虎牙断裂带北段以走滑为主，南段以逆断为主。该研究有助于提高对青藏高原东缘隆升变形机制的理解。

关键词: 地貌指数, 构造抬升, 走滑断裂, 虎牙断裂带, 涪江流域

Abstract: The Huya Fault, located in the steep topographic boundary of the Minshan Mountains in the eastern margin of the Tibetan plateau, has documented many major earthquakes such as the 1630(M=6 3/4), 1973 Huanglong(M_S=6.5) and the 1976 Songpan-Pingwu earthquake swarm(M_S=7.2, 6.7, 7.2). While its activity remains unclear because of lacking Quaternary sediments. In the past few decades, there have been significant advances in understanding the relationship between bedrock channel landscapes and active tectonics, indicating that the bedrock fluvial features can well record the tectonic activity. Many studies reveal that tectonism is the primary factor of landscape evolution in tectonically active regions, and the erosional landscapes can be used to reveal tectonic signals on timescales of 10³~10⁶ years. The Huya Fault crosses the Fujiang drainage basin, making it suitable for the study of bedrock rivers and tectonic uplift in the eastern margin of Minshan. In this study, we calculate the geomorphologic indeices(hillslope, local relief, normalized steepness indices and hypsometric integral) on the basis of the digital elevation model(DEM) SRTM-1. For better understanding the tectonic activity along this fault, we derive some small catchments on the two sides of the Huya fault to analyze the differences of average steepness indices and hypsometric integral. Combining with field observations, lithology, precipitation and modern erosion rates, this study suggests that tectonic activity is the controlling factor of geomorphology in the eastern margin of the Minshan Mountains. We use focal mechanism solutions, GPS data and geomorphic evidence to explore the relationship between the geomorphologic indices of the Fujiang drainage and activity characteristics of the Huya fault. Our results suggest that:(1) The Fujiang drainage basin is in a steady state. The characteristics of the knickpoints indicate that they are mainly controlled by the locally resistant substrate. (2) The suggested value of the geomorphologic index on the west side of the Huya fault is generally larger than on the east side, showing differential tectonic uplift rates across the fault. (3) The difference of the geomorphologic index of the small catchments on both sides of the Huya fault is gradually increasing from north to south along this fault, in accordance with that the north and south segments of the Huya fault are dominated by strike-and reverse-slip, respectively.

Key words: geomorphologic indices, tectonic uplift, strike-slip fault, Huya fault, Fujiang drainage

中图分类号:

P315.2

梁欧博, 任俊杰, 吕延武. 涪江流域河流地貌特征对虎牙断裂带活动性的响应[J]. 地震地质, 2018, 40(1): 42-56.

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.

参考文献

陈长云, 任金卫, 孟国杰, 等. 2012. 巴颜喀拉块体北东缘主要断裂现今活动性分析［J］. 大地测量与地球动力学, 32(3):27-30. CHEN Chang-yun, REN Jin-wei, MENG Guo-jie, et al. 2012. Analysis of modern activity of major faults in northeast margin of Baryan-Har block［J］. Journal of Geodesy and Geodynamics, 32(3):27-30(in Chinese).
李勇, 曹叔尤, 周荣军, 等. 2005. 晚新生代岷江下蚀速率及其对青藏高原东缘山脉隆升机制和形成时限的定量约束［J］. 地质学报, 79(1):28-37. LI Yong, CAO Shu-you, ZHOU Rong-jun, et al. 2005. Late Cenozoic Minjiang incision rate and its constraint on the uplift of the eastern margin of the Tibetan plateau［J］. Acta Geologica Sinica, 79(1):28-37(in Chinese).
李勇, 周荣军, Densmore A L, 等. 2006. 青藏高原东缘大陆动力学过程与地质响应［M］. 北京:地质出版社. LI Yong, ZHOU Rong-jun, Densmore A L, et al. 2006. The Geology of the Eastern Margin of the Qinghai-Tebet Plateau［M］. Geological Publishing House, Beijing(in Chinese).
闵刚, 王绪本, 夏时斌, 等. 2017. 岷山隆起带与西秦岭构造带中段中上地壳电性结构特征［J］. 地球物理学报, 60(6):2397-2413. MIN Gang, WANG Xu-ben, XIA Shi-bin, et al. 2017. Electrical structure of middle and upper crust beneath the Minshan uplift zone and central section of the West Qinling orogenic zone［J］. Chinese Journal of Geophysics, 60(6):2397-2413(in Chinese).
南希, 李爱农, 景金城. 2017. 中国山地起伏度计算中地形自适应滑动窗口获取与验证［J］. 地理与地理信息科学, 33(4):34-39. NAN Xi, LI Ai-nong, JING Jin-cheng. 2017. Calculation and verification of topography adaptive slide windows for the relief amplitude solution in mountain areas of China［J］. Geography and Geo-Information Science, 33(4):34-39(in Chinese).
任俊杰, 徐锡伟, 张世民, 等. 2017. 东昆仑断裂带东端的构造转换与2017年九寨沟M_S7.0地震孕震机制［J］. 地球物理学报, 60(10):4027-4045. REN Jun-jie, XU Xi-wei, ZHANG Shi-min, et al. 2017. Tectonic transformation at the eastern termination of the Eastern Kunlun fault zone and seismogenic mechanism of the 8 August 2017 Jiuzhaigou M_S7.0 earthquake［J］. Chinese Journal of Geophysics, 60(10):4027-4045(in Chinese).
唐荣昌, 韩渭宾. 1993. 四川活动断裂与地震［M］. 北京:地震出版社. TANG Rong-chang, HAN Wei-bin. 1993. Active Fault and Earthquake of Sichuan［M］. Seismological Press, Beijing(in Chinese).
唐文清, 刘宇平, 陈智梁, 等. 2004. 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, 24(4):31-34. TANG Wen-qing, LIU Yu-ping, CHEN Zhi-liang, et al. 2004. The preliminary study of the tectonic activities along the boundary faults around the Minshan uplift, western Sichuan［J］. Sedimentary Geology and Tethyan Geology, 24(4):31-34(in Chinese).
王一舟, 张会平, 郑德文, 等. 2016. 基岩河道河流水力侵蚀模型及其应用:兼论青藏高原基岩河道研究的迫切性［J］. 第四纪研究, 36(4):884-897. WANG Yi-zhou, ZHANG Hui-ping, ZHENG De-wen, et al. 2016. Stream-power incision model and its implications:discussion on the urgency of studying bedrock channel across the Tibetan plateau［J］. Quaternary Sciences, 36(4):884-897(in Chinese).
谢富仁, 陈群策, 崔效锋, 等. 2007. 中国大陆地壳应力环境基础数据库［J］. 地球物理学进展, 22(1):131-136. XIE Fu-ren, CHEN Qun-ce, CUI Xiao-feng, et al. 2007. Fundamental database of crustal stress environment in continental China［J］. Progress in Geophysics, 22(1):131-136(in Chinese).
徐锡伟, 陈桂华, 王启欣, 等. 2017. 九寨沟地震发震断层属性及青藏高原东南缘现今应变状态讨论［J］. 地球物理学报, 60(10):4018-4026. XU Xi-wei, CHEN Gui-hua, WANG Qi-xin, et al. 2017. Discussion on seismogenic structure of Jiuzhaigou earthquake and its implication for current strain state in the southeastern Qinghai-Tibet Plateau［J］. Chinese Journal of Geophysics, 60(10):4018-4026(in Chinese).
杨农, 张岳桥, 孟辉, 等. 2003. 川西高原岷江上游河流阶地初步研究［J］. 地质力学学报, 9(4):363-370. YANG Nong, ZHANG Yue-qiao, MENG Hui, et al. 2003. Study of the Minjiang river terraces in the Western Sichuan Plateau［J］. Journal of Geomechanics, 9(4):363-370(in Chinese).
张会平, 杨农, 张岳桥, 等. 2006. 岷江水系流域地貌特征及其构造指示意义［J］. 第四纪研究, 26(1):126-135. ZHANG Hui-ping, YANG Nong, ZHANG Yue-qiao, et al. 2006. Geomorphology of the Minjiang drainage system(Sichuan, China)and its structural implications［J］. Quaternary Sciences, 26(1):126-135(in Chinese).
赵小麟, 邓起东, 陈社发. 1994. 岷山隆起的构造地貌学研究［J］. 地震地质, 16(4):429-439. ZHAO Xiao-lin, DENG Qi-dong, CHEN She-fa. 1994. Tectonics geomorphology of the Minshan uplift in Western Sichuan, southwestern China［J］. Seismology and Geology, 16(4):429-439(in Chinese).
周荣军, 李勇, Densmore A L, 等. 2006. 青藏高原东缘活动构造［J］. 矿物岩石, 26(2):40-51. ZHOU Rong-jun, LI Yong, Densmore A L, et al. 2006. Active tectonics of the eastern margin of the Tibet Plateau［J］. Journal of Mineralogy and Petrology, 26(2):40-51(in Chinese).
周荣军, 蒲晓虹, 何玉林, 等. 2000. 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, 22(3):285-294. doi:10.3969/j.issn.0253-4967.2000.03.009. ZHOU Rong-jun, PU Xiao-hong, HE Yu-lin, et al. 2000. Recent activity of Minjiang fault zone, uplift of Minshan block and their relationship with seismicity of Sichuan［J］. Seismology and Geology, 22(3):285-294(in Chinese).
Ahnert F. 1970. Functional relationships between denudation, relief, and uplift in large, mid-latitude drainage basins［J］. American Journal of Science, 268(3):243-263.
Burchfiel B C, Chen Z L, Yupinc L, et al. 1995. Tectonics of the Longmen shan and adjacent regions, Central China［J］. International Geology Review, 37(8):661-735.
Chen S F, Wilson C J L, Deng Q D, et al. 1994. Active faulting and block movement associated with large earthquakes in the Min Shan and Longmen Mountains, northeastern Tibetan plateau［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 99(B12):24025-24038.
Chen Y W, Shyu J B H, Chang C P. 2015. Neotectonic characteristics along the eastern flank of the Central Range in the active Taiwan orogen inferred from fluvial channel morphology［J］. Tectonics, 34(10):2249-2270.
Davis W M. 1899. The geographical cycle［J］. The Geographical Journal, 14(5):481-504.
Flint J J. 1974. Stream gradient as a function of order, magnitude, and discharge［J］. Water Resources Research, 10(5):969-973.
Hack J T. 1973. Stream-profile analysis and stream-gradient index［J］. Journal of Research of the U.S. Geological Survey, 1(4):421-429.
Kirby E, Whipple K X. 2001. Quantifying differential rock-uplift rates via stream profile analysis［J］. Geology, 29(5):415-418.
Kirby E, Whipple K X. 2012. Expression of active tectonics in erosional landscapes［J］. Journal of Structural Geology, 44:54-75.
Kirby E, Whipple K X, Burchfiel B C, et al. 2000. Neotectonics of the Min Shan, China:implications for mechanisms driving Quaternary deformation along the eastern margin of the Tibetan plateau［J］. Geological Society of America Bulletin, 112(3):375-393.
Liu-Zeng J, Wen L, Oskin M, et al. 2011. Focused modern denudation of the Longmen Shan margin, eastern Tibetan plateau［J］. Geochemistry Geophysics Geosystems, 12(11):Q11007.
Montgomery D R, Foufoula-Georgiou E. 1993. Channel network source representation using digital elevation models［J］. Water Resources Research, 29(12):3925-3934.
New M, Lister D, Hulme M, et al. 2002. A high-resolution data set of surface climate over global land areas［J］. Climate Research, 21:1-25.
Ouimet W B, Whipple K X, Granger D E. 2009. Beyond threshold hillslopes:channel adjustment to base-level fall in tectonically active mountain ranges［J］. Geology, 37(7):579-582.
Perron J T, Royden L. 2013. An integral approach to bedrock river profile analysis［J］. Earth Surface Processes and Landforms, 38(6):570-576.
Pike R J, Wilson S E. 1971. Elevation-relief ratio, hypsometric integral, and geomorphic area-altitude analysis［J］. Geological Society of America Bulletin, 82(4):1079-1084.
Ren J J, Xu X W, Yeats R S, et al. 2013. Millennial slip rates of the Tazang fault, the eastern termination of Kunlun Fault:implications for strain partitioning in eastern Tibet［J］. Tectonophysics, 68:1180-1200.
Ren Z K, Zhang Z Q, Dai F C, et al. 2014. Topographic changes due to the 2008 M_W7.9 Wenchuan earthquake as revealed by the differential DEM method［J］. Geomorphology, 217:122-130.
Royden L, Perron J T. 2013. Solutions of the stream power equation and application to the evolution of river longitudinal profiles［J］. Journal of Geophysical Research:Earth Surface, 118(2):497-518.
Scherler D, Bookhagen B, Strecker M R. 2014. Tectonic control on ¹⁰Be-derived erosion rates in the Garhwal Himalaya, India［J］. Journal of Geophysical Research:Earth Surface, 119(2):83-105.
Schmidt K M, Montgomery D R. 1995. Limits to relief［J］. Science, 270(5236):617-620.
Schwanghart W, Kuhn N J. 2010. TopoToolbox:A set of Matlab functions for topographic analysis［J］. Environmental Modelling & Software, 25(6):770-781.
Snyder N P, Whipple K X, Tucker G E, et al. 2000. Landscape response to tectonic forcing:digital elevation model analysis of stream profiles in the Mendocino triple junction region, northern California［J］. Geological Society of America Bulletin, 112(8):1250-1263.
Snyder N P, Whipple K X, Tucker G E, et al. 2003. Importance of a stochastic distribution of floods and erosion thresholds in the bedrock river incision problem［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 108(B2):2117. doi:10.1029/2001JB001655.
Stock J, Dietrich W E. 2003. Valley incision by debris flows:evidence of a topographic signature［J］. Water Resources Research, 39(4):1089. doi:10.1029/2001WR001057.
Strahler A N. 1952. Hypsometric(area-altitude)analysis of erosional topography［J］. Geological Society of America Bulletin, 63(11):1117-1142.
Strahler A N. 1957. Quantitative analysis of watershed geomorphology［J］. Eos, Transactions American Geophysical Union, 38(6):913-920.
Tan X B, Xu X W, Lee Y H, et al. 2017. Late Cenozoic thrusting of major faults along the central segment of Longmen Shan, eastern Tibet:evidence from low-temperature thermochronology［J］. Tectonophysics, 712-713:145-155. doi:10.1016/j.tecto.2017.05.016.
Tinkler K J, Wohl E E. 1998. Rivers Over Rock:Fluvial Processes in Bedrock Channels［M］. American Geophysical Union, Washington.
Whipple K X, Kirby E, Brocklehurst S H. 1999a. Geomorphic limits to climate-induced increases in topographic relief［J］. Nature, 401(6748):39-43.
Whipple K X, Tucker G E. 1999b. Dynamics of the stream-power river incision model:implications for height limits of mountain ranges, landscape response timescales, and research needs［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 104(B8):17661-17674.
Wobus C, Whipple K X, Kirby E, et al. 2006. Tectonics from topography:procedures, promise, and pitfalls［C］//Willett S D, Hovius N, Brandon M T, et al. Tectonics, Climate, and Landscape Evolution:Geological Society of America Special Papers 398:55-74.
Zhang H P, Zhang P Z, Kirby E, et al. 2011. Along-strike topographic variation of the Longmen Shan and its significance for landscape evolution along the Eastern Tibetan plateau［J］. Journal of Asian Earth Sciences, 40(4):855-864.

[1]	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.
[2]	姚生海, 盖海龙, 殷翔, 刘炜, 张加庆, 袁建新. 柴达木盆地北缘断裂(锡铁山段)的构造地貌特征与晚第四纪活动速率[J]. 地震地质, 2020, 42(6): 1385-1400.
[3]	胡宗凯, 杨晓平, 杨海波, 吴国栋, 李军, 周本刚. 北天山博罗可努-阿齐克库都克断裂精河段的古地震事件[J]. 地震地质, 2020, 42(4): 773-790.
[4]	唐清, 郑文俊, 石霖, 张冬丽, 黄荣. 基于高精度LiDAR数据的断裂活动习性精细定量——以香山-天景山断裂景泰小红山段为例[J]. 地震地质, 2020, 42(2): 366-381.
[5]	邵延秀, 袁道阳, 刘静, Jerome Van der Woerd, 李志刚, 吴磊, 刘方斌. 阿尔金断裂中段南月牙山古地震地表破裂带及其构造意义[J]. 地震地质, 2020, 42(2): 435-454.
[6]	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.
[7]	哈广浩, 吴中海, 马凤山, 曾庆利, 张路青, 盖海龙. 藏北改则县别若则错活动断裂的发现及其地质意义[J]. 地震地质, 2019, 41(2): 436-446.
[8]	李康, 王躲, 邵庆丰, 徐锡伟. 青藏高原中部NE向其香错断裂全新世左旋走滑速率及其构造意义[J]. 地震地质, 2018, 40(6): 1204-1215.
[9]	黄伟亮, 杨晓平, 李胜强, 杨海波. 天山内部走滑断裂晚第四纪活动特征研究——以开都河断裂为例[J]. 地震地质, 2018, 40(5): 1040-1058.
[10]	杨蓉. 几种地形演化的数值模拟模型简述[J]. 地震地质, 2017, 39(6): 1173-1184.
[11]	吴富峣, 冉勇康, 李安, 徐良鑫, 曹筠. 东天山东段碱泉子-巴里坤断裂系晚第四纪左旋走滑的地质证据[J]. 地震地质, 2016, 38(3): 617-630.
[12]	邓起东, 朱艾斓, 高翔. 再议走滑断裂与地震孕育和发生条件[J]. 地震地质, 2014, 36(3): 562-573.
[13]	刘玉刚, 陈涛, 闵伟, 周本刚. 苍山-尼山断裂西段第四纪晚期活动性[J]. 地震地质, 2013, 35(4): 754-764.
[14]	冉勇康, 王虎, 李彦宝, 陈立春. 中国大陆古地震研究的关键技术与案例解析(1)——走滑活动断裂的探槽地点、布设与事件识别标志[J]. 地震地质, 2012, (2): 197-210.
[15]	郑荣章, 徐锡伟, 马文涛, 李建平. 阿尔金断裂带西段莫勒切河河口阶地的构造及气候意义[J]. 地震地质, 2011, 33(2): 323-334.