青藏高原东南缘地貌边界性质的界定及其对高原东南缘扩展模式的启示

doi:10.3969/j.issn.0253-4967.2019.02.003

摘要/Abstract

摘要： 青藏高原东南部的地貌结构是高原隆升深部动力过程与高原扩展的重要指标之一，存在受下地壳流驱动的渐变模型和受宽约50~200km的雅砻-玉龙断裂系控制的陡变模型2种不同认识。文中基于30m分辨率的SRTM数据进行数字高程分析，利用高程和水系参数对研究区地貌加以提取和分析，结合野外地貌和构造调研的结果以及前人的相关研究，对高原东南缘川滇地块中部构造地貌细结构进行了详细的解析。研究认为，青藏高原东南边界具有明显的台阶式构造地貌结构，不同台阶梯度带受不同时期发育的NE-SW向断裂控制。其中一级边界位于木里-玉龙断裂，控制了平均海拔4 200m的高原面的东南边界，是渐新世-中新世早期构造抬升的结果；二级边界受中新世中期逆冲活动的金河-箐河断裂控制，其构成丽江-盐源一带海拔中等（约3 000m）、相对低起伏区域的东南边界。高原东南边界的台阶式构造地貌结构反映了高原向SE的前展式逆冲扩展。这种扩展模式并不支持下地壳管道流连续变形模型。

关键词: 青藏高原东南缘, 川滇地块, 台阶式构造地貌, 木里-玉龙断裂, 金河-箐河断裂

Abstract: The geomorphologic structure in the southeastern Tibetan Plateau is one of the important indexes for the expansion and deep dynamic process of Tibet. There are two different understandings for the geomorphologic structure in the southeastern Tibetan Plateau, i.e. gradual change and abrupt change. The gradient model suggests a gradual topographic reduction towards southeast which is an important evidence for the lower crust channel flow. The abrupt model considers that the southeast boundary of the plateau shows an abrupt change of topography in a zone of 50~200km wide which is controlled by the Yarlung-Yulong fault system. Here, we describe the morphotectonic feature in detail of the Sichuan-Yunnan block on the southeast edge of the plateau through the digital elevation model(DEM)analysis, further review the structural controls on the geomorphologic structure by combining the tectono-thermochronology analysis, and evaluate the southeastward spreading mode of the plateau.
The topographic arithmetic progression ranking by using the DEM of the Sichuan-Yunnan block reveals three geomorphologic steps gradually lowering from the northwest to southeast. The switching of hypsometric integral(HI)value and the anomaly of SL/K value(where SL is stream length-gradient index and K is altitude of the profile)of river systems all occur on the edge of terraces. The high terrace is located on the north of Muli-Yulong with average elevation~4 200m; the secondary level of terrace extends to the Yanyuan-Lijiang area with average elevation~3 000m; and the third level is the region between the Jinhe-Qinghe and Anninghe with average elevation~1 800m.
Structure investigation reveals that all the topographic boundaries between different terraces are consistent with regional major faults. The Muli thrust fault and Yulong thrust fault control the southeast edge of the high terrace, the Jinhe-Qinghe thrust fault separates the second and third level of terrace. The coincidence between topography boundaries and faults suggests that the formation of the stepped geomorphology on the southeast edge of the plateau were induced by the fault activities, reflecting the fault-controlled southeastward stepped-expanding mode of the plateau.
The fission-track(FT)dating of the granites at the hanging wall of the Yuling-Muli Fault reveals fast uplift during~27~22Ma BP, reflecting the major thrusting along the Yulong-Muli Fault, which is consistent with the early-stage activity (~30~25Ma BP) of the Longmenshan Fault. Therefore, the high terrace was formed during the Oligocene to early Miocene with the thrusting of the Yulong-Muli Fault. Tectono-thermochronology analysis also reveals the major thrusting of the Jinhe-Qinghe Fault occurred during~18~11Ma BP, indicating the middle terrace was formed in the middle Miocene, which also could correspond to the middle Miocene(~15~10Ma BP) activity of the Longmenshan Fault.
Therefore, the thrusting faults controlled stepped terrace geomorphologic structure and the stepwise expanding mode under combined movements of large-scale thrusts and strike-slip faults at the southeast edge of Tibetan Plateau during the late Cenozoic do not support the lower crust channel flow model.

Key words: southeastern Tibet, Chuandian block, stepped geomorphological structure, Muli-Yulong Fault, Jinhe-Jinghe thrust fault

中图分类号:

P931.2

吴贵灵, 祝成宇, 王国灿, 张攀. 青藏高原东南缘地貌边界性质的界定及其对高原东南缘扩展模式的启示[J]. 地震地质, 2019, 41(2): 281-299.

WU Gui-ling, ZHU Cheng-yu, WANG Guo-can, ZHANG Pan. DEMARCATION OF THE GEOMORPHOLOGICAL BOUNDARIES OF SOUTHEASTERN TIBET: IMPLICATIONS FOR EXPANSION MECHANISMS OF THE PLATEAU EDGE[J]. SEISMOLOGY AND GEOLOGY, 2019, 41(2): 281-299.

参考文献

范莉苹, 吴建平, 房立华. 2015. 青藏高原东南缘远震P波层析成像研究［J］. CT理论与应用研究, 24(2):209-223.
FAN Li-ping, WU Jian-ping, FANG Li-hua. 2015. Teleseimic P wave tomography in the southeast margin of the Tibetan Plateau［J］. Computerized Tomography Theory and Applications, 24(2):209-223(in Chinese).
姜文亮, 张景发. 2011. 川滇地区重力场与深部结构特征［J］. 地球物理学进展, 26(6):1915-1924.
JIANG Wen-liang, ZHANG Jing-fa. 2011. Deep structures of Sichuan-Yunnan region derived from gravity data［J］. Progress in Geophysics, 26(6):1915-1924(in Chinese).
刘静, 曾令森, 丁林, 等. 2009. 青藏高原东南缘构造地貌、活动构造和下地壳流动假说［J］. 地质科学, 44(4):1227-1255.
LIU-ZENG Jing, ZENG Ling-seng, DING Lin, et al. 2009. Tectonic geomorphology, active tectonics and lower crustal channel flow hypothesis of southeastern Tibetan Plateau［J］. Chinese Journal of Geology, 44(4):1227-1255(in Chinese).
潘桂棠, 肖庆辉, 陆松年, 等. 2009. 中国大地构造单元划分［J］. 中国地质, 36(1):1-28.
PAN Gui-tang, XIAO Qing-hui, LU Song-nian, et al. 2009. Subdivision of tectonic units in China［J］. Geology in China, 36(1):1-28(in Chinese).
王立全. 2013. 青藏高原及邻区地质图及说明书［CM］. 北京:地质出版社.
WANG Li-quan. 2013. Geological Maps and Descriptions of Tibetan Plateau and Its Vicinity［CM］. Geological Publishing House, Beijing(in Chinese).
向宏发, 徐锡伟, 虢顺民, 等. 2002. 丽江-小金河断裂第四纪以来的左旋逆推运动及其构造地质意义:陆内活动地块横向构造的屏蔽作用［J］. 地震地质, 24(2):188-198.
XIANG Hong-fa, XU Xi-wei, GUO Shun-min, et al. 2002. Sinistral thrusting along the Lijiang-Xiaojinhe Fault since Quaternary and its geologic-tectonic significance:Shielding effect of transverse structure of intracontinental active block［J］. Seismology and Geology, 24(2):188-198(in Chinese).
徐锡伟, 程国良, 于贵华, 等. 2003. 川滇菱形块体顺时针转动的构造学与古地磁学证据［J］. 地震地质, 25(1):61-70.
XU Xi-wei, CHENG Guo-liang, YU Gui-hua, et al. 2003. Tectonic and paleomagnetic evidence for the clockwise rotation of the Sichuan-Yunnan rhombic block［J］. Seismology and Geology, 25(1):61-70(in Chinese).
许志琴, 李化启, 侯立炜, 等. 2007. 青藏高原东缘龙门-锦屏造山带的崛起:大型拆离断层和挤出机制［J］. 地质通报, 26(10):1262-1276.
XU Zhi-qin, LI Hua-qi, HOU Li-wei, et al. 2007. Uplift of the Longmen-Jinping orogenic belt along the eastern margin of the Qinghai-Tibet Plateau:Large-scale detachment faulting and extrusion mechanism［J］. Geological Bulletin of China, 26(10):1262-1276(in Chinese).
余明烈. 1990. 川西木里推覆构造的厘定［J］. 中国区域地质, (1):46-50, 61.
YU Ming-lie. 1990. Study of the nappe structure in Muli western Sichuan［J］. Regional Geology of China, (1):46-59, 61(in Chinese).
俞维贤, 王彬, 谢英情, 等. 2004. 玉龙雪山周缘主要断裂的断层泥中石英碎砾表面SEM特征与丽江地震［J］. 地震研究, 27(1):81-87.
YU Wei-xian, WANG Bin, XIE Ying-qing, et al. 2004. Discussion on the Lijiang earthquake and the SEM characteristics of surfaces of quartz gravels in the gouge of main faults around the Yulong snow mountain［J］. Journal of Seismological Research, 27(1):81-87(in Chinese).
张会平, 杨农, 刘少峰, 等. 2006. 数字高程模型(DEM)在构造地貌研究中的应用新进展［J］. 地质通报, 25(6):660-669.
ZHANG Hui-ping, YANG Nong, LIU Shao-feng, et al. 2006. Recent progress in the DEM-based tectonogeomorphic study［J］. Geological Bulletin of China, 25(6):660-669(in Chinese).
Arne D, Worley B, Wilson C, et al. 1997. Differential exhumation in response to episodic thrusting along the eastern margin of the Tibetan Plateau［J］. Tectonophysics, 280(3-4):239-256.
Cao S, Liu J, Leiss B, et al. 2011a. Oligo-Miocene shearing along the Ailao Shan-Red River shear zone:Constraints from structural analysis and zircon U/Pb geochronology of magmatic rocks in the Diancang Shan massif, SE Tibet, China［J］. Gondwana Research, 19(4):975-993.
Cao S, Neubauer F, Liu J, et al. 2011b. Exhumation of the Diancang Shan metamorphic complex along the Ailao Shan-Red River belt, southwestern Yunnan, China:Evidence from ⁴⁰Ar/³⁹Ar thermochronology［J］. Journal of Asian Earth Sciences, 42(3):525-550.
Cao K, Wang G, Leloup P H. et al. 2019. Oligocene-Early Miocenetopographic relief generation of southeastern Tibet triggered by thrusting［J］. Tectonics, 38:374-391.
Clark M K, House M A, Royden L H, et al. 2005. Late Cenozoic uplift of southeastern Tibet［J］. Geology, 33(6):525-528.
Clark M K, Royden L H. 2000. Topographic ooze:Building the eastern margin of Tibet by lower crustal flow［J］. Geology, 28(8):703-706.
Clark M K, Royden L H, Whipple K X, et al. 2006. Use of a regional, relict landscape to measure vertical deformation of the eastern Tibetan Plateau［J］. Journal of Geophysical Research:Earth Surface, 111(F3):F03002.
Clift P D, Sun Z. 2006. The sedimentary and tectonic evolution of the Yinggehai-Song Hong Basin and the southern Hainan margin, South China Sea:Implications for Tibetan uplift and monsoon intensification［J］. Journal of Geophysical Research Solid Earth, 111(B6):B06405.
Godard V, Pik R, Lavé J, et al. 2009. Late Cenozoic evolution of the central Longmen Shan, eastern Tibet:Insight from (U-Th)/He thermochronometry［J］. Tectonics, 28:TC5009.
Hack J T. 1973. Stream-profile analysis and stream-gradient index［J］. Journal of Research of the US Geological Survey, 1(4):421-429.
Hoke G D, Liu-Zeng J, Hren M T, et al. 2014. Stable isotopes reveal high southeast Tibetan Plateau margin since the Paleogene［J］. Earth and Planetary Science Letters, 394:270-278.
Hoke G D. 2018. Geochronology transforms our view of how Tibet's southeast margin evolved［J］. Geology, 46(1):95-96.
Keller E A, Pinter N. 1996. Active tectonics:Earthquakes, uplift, and landscape［J］. Prentice Hall:338.
Kirby E, Reiners P W, Krol M A, et al. 2002. Late Cenozoic evolution of the eastern margin of the Tibetan Plateau:Inferences from ⁴⁰Ar/³⁹Ar and(U-Th)/He thermochronology［J］. Tectonics, 21(1):1-1-1-20.
Lacassin R, Schärer U, Leloup P H E, et al. 1996. Tertiary deformation and metamorphism SE of Tibet:The folded Tiger-leap dècollemen of NW Yunnan, China［J］. Tectonics, 15(2):605-622.
Leloup P H, Arnaud N, Lacassin R, et al. 2001. New constraints on the structure, thermochronology, and timing of the Ailao Shan-Red River shear zone, SE Asia［J］. Journal of Geophysical Research, 106(B4):6683-6732.
Li D, Liao H, Ding Z, et al. 2018. Joint inversion of the 3D P wave velocity structure of the crust and upper mantle under the southeastern margin of the Tibetan Plateau using regional earthquake and teleseismic data［J］. Acta Geologica Sinica, 92(1):16-33.
Li S, Currie B S, Rowley D B, et al. 2015. Cenozoic paleoaltimetry of the SE margin of the Tibetan Plateau:Constraints on the tectonic evolution of the region［J］. Earth and Planetary Science Letters, 432:415-424.
Liu A. 2008. Advances in Digital Terrain Analysis:DEM-based Analysis of Local Relief［M］. Springer Berlin Heidelberg:177-192.
Liu-Zeng J, Tapponnier P, Gaudemer Y, et al. 2008. Quantifying landscape differences across the Tibetan Plateau:Implications for topographic relief evolution［J］. Journal of Geophysical Research, 113(F4):F04018.
Liu-Zeng J, Zhang J, McPhillips D, et al. 2018. Multiple episodes of fast exhumation since Cretaceous in southeast Tibet, revealed by low-temperature thermochronology［J］. Earth and Planetary Science Letters, 490:62-76.
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):1079-1083.
Roger F, Calassou S, Lancelot J, et al. 1995. Miocene emplacement and deformation of the Konga Shan granite(Xianshui He fault zone, west Sichuan, China):Geodynamic implications［J］. Earth and Planetary Science Letters, 130(1-4):201-216.
Seeber L, Gornitz V. 1983. River profiles along the Himalayan arc as indicators of active tectonics［J］. Tectonophysics, 92(4):335-337.
Shen X, Tian Y, Li D, et al. 2016. Oligocene-Early Miocene river incision near the first bend of the Yangze River:Insights from apatite (U-Th-Sm)/He thermochronology［J］. Tectonophysics, 687:223-231.
Strahler A N. 1952. Hypsometric(area-altitude)analysis of erosional topography［J］. Bulletin of the Geological Society of America, 63(11):1117-1142.
Tan X B, Lee Y H, Chen W Y, et al. 2014. Exhumation history and faulting activity of the southern segment of the Longmen Shan, eastern Tibet［J］. Journal of Asian Earth Sciences, 81(4):91-104.
Tang M, Jing L Z, Hoke G D, et al. 2017. Paleoelevation reconstruction of the Paleocene-Eocene Gonjo Basin, SE-central Tibet［J］. Tectonophysics, 712-713:170-181.
Tapponnier P, Peltzer G, Dain A Y L, et al. 1982. Propagating extrusion tectonics in Asia:New insights from simple experiments with plasticine［J］. Geology, 10(12):611-616.
Tapponnier P, Xu Z, Roger F, et al. 2001. Oblique stepwise rise and growth of the Tibet Plateau［J］. Science, 294(5547):1671-1677.
Thatcher W. 2007. Microplate model for the present-day deformation of Tibet［J］. Journal of Geophysical Research:Solid Earth, 112(B1):B01401.
Tian Y, Kohn B P, Gleadow A J W, et al. 2014. A thermochronological perspective on the morphotectonic evolution of the southeastern Tibetan Plateau［J］. Journal of Geophysical Research:Solid Earth, 119(1):676-698.
Wang E, Kirby E, Furlong K P, et al. 2012. Two-phase growth of high topography in eastern Tibet during the Cenozoic［J］. Nature Geoscience, 5(9):640-645.
Wang H, TianY T, Liang M J. 2017. Late Cenozoic exhumation history of the Luoji Shan in the southeastern Tibetan Plateau:Insights from apatite fission-track thermochronology［J］. Journal of Geological Society, 174(5):883-891.
Wang S, Jiang G, Xu T, et al. 2012. The Jinhe-Qinghe Fault:An inactive branch of the Xianshuihe-Xiaojiang fault zone, eastern Tibet［J］. Tectonophysics, 544-545(2):93-102.
Xu G, Kamp P J J. 2000. Tectonics and denudation adjacent to the Xianshuihe Fault, eastern Tibetan Plateau:Constraints from fission track thermochronology［J］. Journal of Geophysical Research:Solid Earth, 105(B8):19231-19251.
Yang R, Willett S D, Goren L. 2015. In situ low-relief landscape formation as a result of river network disruption［J］. Nature, 520(7548):526-529.
Zhang H, Oskin M E, Jing L Z, et al. 2016. Pulsed exhumation of interior eastern Tibet:Implications for relief generation mechanisms and the origin of high-elevation planation surfaces［J］. Earth and Planetary Science Letters, 449:176-185.
Zhang Y, Chen W, Yang N. 2004. ⁴⁰Ar/³⁹Ar dating of shear deformation of the Xianshuihe fault zone in west Sichuan and its tectonic significance［J］. Science in China(Ser D), 47(9):794-803.
Zhang Y Z, Replumaz A, Leloup P H, et al. 2017. Cooling history of the Gongga batholith:Implications for the Xianshuihe Fault and Miocene kinematics of SE Tibet［J］. Earth and Planetary Science Letters, 465:1-15.

[1]	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.
[2]	吴桂桔, 于炳飞, 郝洪涛, 胡敏章, 谈洪波. 漾濞震区及周缘深部构造特征与发震构造[J]. 地震地质, 2021, 43(4): 739-756.
[3]	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.
[4]	李君, 王勤彩, 崔子健, 张佩, 周琳, 周辉. 川滇菱形块体东边界及邻区震源机制解与构造应力场空间分布特征[J]. 地震地质, 2019, 41(6): 1395-1412.
[5]	商咏梅, 杨彧, 杨晓松. 岩石圈主要各向异性矿物的CPO特征及其对岩石圈动力学研究的启示[J]. 地震地质, 2019, 41(3): 704-725.
[6]	陈兆辉, 孟小红, 张双喜, 刘金钊, 王同庆, 张品, 韦少港. 青藏高原东南缘多尺度重力场变化特征及孕震机理分析[J]. 地震地质, 2019, 41(3): 690-703.
[7]	王辉, 曹建玲, 徐化超. 中小地震震源机制解在青藏高原东南缘地区断层稳定性分析中的初步应用[J]. 地震地质, 2019, 41(3): 633-648.
[8]	王虎, 冉勇康, 陈立春, 梁明剑, 高帅坡, 李彦宝, 徐良鑫. 安宁河断裂带南段滑动速率估计[J]. 地震地质, 2018, 40(5): 967-979.
[9]	李永华, 徐小明, 张恩会, 高家乙. 青藏高原东南缘地壳结构及云南鲁甸、景谷地震深部孕震环境[J]. 地震地质, 2014, 36(4): 1204-1216.
[10]	王虎, 冉勇康, 李彦宝, 陈立春. 川西地区安宁河断层古地震行为及其与则木河断层的比较[J]. 地震地质, 2014, 36(3): 706-717.
[11]	王刚, 王二七. 挤压造山带中的伸展构造及其成因——以滇中地区晚新生代构造为例[J]. 地震地质, 2005, 27(2): 188-199.
[12]	程万正, 刁桂苓, 吕弋培, 张永久, 李桂芳, 陈天长. 川滇地块的震源力学机制、运动速率和活动方式[J]. 地震地质, 2003, 25(1): 71-87.