同震地表破裂及活动断层迹线的几何形貌特征

doi:10.3969/j.issn.0253-4967.2017.06.012

摘要/Abstract

摘要： 天然断层面的几何形貌特征中隐含着大量与断层演化和破裂机制相关的信息，准确描述断层面的形貌特征对于认识断层的形成与发展，及其破裂过程具有重要意义。文中运用能谱密度分析方法，对全球52条同震地表破裂和300条活动断层的地表迹线数据进行分析和归纳，结果显示：1）它们的平均能谱密度曲线在频域上具有明显的3分段特征。在低频域，能谱密度曲线特征表征了km级以上尺度的构造块体边界的形貌特征；在中频域，则受到hm—km级尺度上的断层横向扩展、次级断裂的贯通以及地形因素的控制；在hm尺度上的拐点代表了重采样的有效长度，在hm级以下尺度的高频域，能谱曲线特征受到数据插值方法的控制；2）在km级以下尺度，同震地表破裂的能谱密度曲线显示3种破裂类型的断层迹线粗糙度之间存在明显差异：逆冲型 > 正断型 > 走滑型，这表明在该尺度范围内的破裂迹线几何形貌特征差异主要受破裂类型的控制；3）与同震地表破裂相比，活动断层迹线的能谱密度明显偏低。这表明随着破裂次数增加、断层活动历史增长，断层的粗糙度会逐渐减小，即粗糙度与成熟程度成反比。

关键词: 同震地表破裂, 活动断层, 能谱密度, 断层粗糙度

Abstract: Fault traces contain abundant information associated with the fracture process and mechanism, so an accurate and quantitative description of their geometric characteristics is of great significance to perceiving the generation and development of faults. We collected 52 co-seismic surface ruptures and 300 active fault traces from across the world to analyse their geometric characteristics by the method of power spectrum density. Our results show that (1)the average power spectrum density has a distinct three-segment charateristic in the frequency domain. In the low frequency domain it represents the geometric characteristics of the boundary of tectonic block. In the medium frequency domain, the power spectrum density reflects the processes of lateral growth and connection of secondary faults, and the turn point on the 100 meters scale represents the effective resampling length, below which the power spectrum density characteristics are meaningless. (2)In the middle and high frequency domains, the power spectrum density curves of co-seismic surface ruptures show that there are obvious differences in roughness among three fault types, i.e. reverse > normal > strike-slip, which indicates that the geometric characteristics of co-seismic surface ruptures are controlled by the fault types. (3)Compared with co-seismic surface ruptures, active fault traces have much lower power spectrum density, indicating the roughness of active fault traces becomes lower with increasing numbers of rupturing events and the lengths of active history, i.e., the fault roughness is inversly proportional to its maturity.

Key words: co-seismic surface ruptures, active faults, power spectrum density, fault roughness

中图分类号:

P315.2

郝海健, 何宏林, 魏占玉, 石峰. 同震地表破裂及活动断层迹线的几何形貌特征[J]. 地震地质, 2017, 39(6): 1267-1282.

HAO Hai-jian, HE Hong-lin, WEI Zhan-yu, SHI Feng. GEOMETRIC CHARACTERISTICS OF CO-SEISMIC SURFACE RUPTURES AND ACTIVE FAULTS[J]. SEISMOLOGY AND GEOLOGY, 2017, 39(6): 1267-1282.

参考文献

邓起东, 陈桂华, 朱艾斓. 2011. 关于2008年汶川M_S8.0地震震源断裂破裂机制几个问题的讨论［J］. 中国科学(D辑), 41(11):1559-1576.DENG Qi-dong, CHEN Gua-hua, ZHU Ai-lan. 2011. Discussion of rupture mechanisms on the seismogenic fault of the 2008 M_S8.0 Wenchuan earthquake［J］. Science in China(Ser D), 54(9):1360-1377.
皇甫岗. 1988. 断层泥的厚度、粒度与断层错距的关系［J］. 四川地震, (1):52-58.HUANGFU Gang. 1988. The Correlation between thickness, granularity of fault gouge and fault offset［J］. Sichuan Earthquake Research, (1):52-58(in Chinese).
周枝华, 杜守继. 2005. 岩石节理表面几何特性的三维统计分析［J］. 岩土力学, 26(8):1227-1232.ZHOU Zhi-hua, DU Shou-ji. 2005. 3D statistic analysis of geometrical properties of a rock joint［J］. Rock and Soil Mechanics, 26(8):1227-1232(in Chinese).
Aki K. 1984. Asperities, barriers, characteristic earthquakes and strong motion prediction［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 89(B7):5867-5872.
Akyüz H S, Hartleb R, Barka A, et al. 2002. Surface rupture and slip distribution of the 12 November 1999 Düzce earthquake(M7.1), north Anatolian Fault, Bolu, Turkey［J］. Bulletin of the Seismological Society of America, 92(1):61-66.
Allen C R, Engen G R, Hanks T C, et al. 1971. Main shock and larger aftershocks of the San Fernando earthquake, February 9 through March 1, 1971. Washington:USGS Prof. Paper, 733:17-20.
Allen C R, Grantz A, Brune J N, et al. 1968. The Borrego Mountain, California, earthquake of 9 April 1968:A preliminary report［J］. Bulletin of the Seismological Society of America, 58(3):1183-1186.
Barka A. 1996. Slip distribution along the North Anatolian Fault associated with the large earthquakes of the period 1939 to 1967［J］. Bulletin of the Seismological Society of America, 86(5):1238-1254.
Beanland S, Berryman K R, Blick G H. 1989. Geological investigations of the 1987 Edgecumbe earthquake, New Zealand［J］. New Zealand journal of geology and geophysics, 32(1):73-91.
Berberian M, Jackson J A, Fielding E, et al. 2001. The 1998 March 14 Fandoqa earthquake(M_W6.6)in Kerman Province, southeast Iran:re-rupture of the 1981 Sirch earthquake fault, triggering of slip on adjacent thrusts and the active tectonics of the Gowk fault zone［J］. Geophysical Journal International, 146(2):371-398.
Berberian M, Jackson J A, Ghorashi M, et al. 1984. Field and teleseismic observations of the 1981 Golbaf-Sirch earthquakes in SE Iran［J］. Geophysical Journal International, 77(3):809-838.
Berberian M, Jackson J A, Qorashi M, et al. 1999. The 1997 May 10 Zirkuh(Qa'enat)earthquake(M_W7.2):faulting along the Sistan suture zone of eastern Iran［J］. Geophysical Journal International, 136(3):671-694.
Berry M V, Hannay J H. 1978. Topography of random surfaces［J］. Nature, 273(5663):573-573.
Brodsky E E, Kanamori H. 2001. Elastohydrodynamic lubrication of faults［J］. Journal of Geophysical Research:Solid Earth, 106(B8):16357-16374.
Brown S R. 1987. A note on the description of surface roughness using fractal dimension［J］. Geophysical Research Letters, 14(11):1095-1098.
Brown S R. 1995. Simple mathematical model of a rough fracture［J］. Journal of Geophysical Research:Solid Earth, 100(B4):5941-5952.
Brown S R, Scholz C H. 1985. Broad bandwidth study of the topography of natural rock surfaces［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 90(B14):12575-12582.
Candela T, Renard F, Bouchon M, et al. 2009. Characterization of fault roughness at various scales:implications of three-dimensional high resolution topography measurements［J］. Pure and Applied Geophysics, 166(10-11):1817-1851.
Candela T, Renard F, Klinger Y, et al. 2012. Roughness of fault surfaces over nine decades of length scales［J］. Journal of Geophysical Research:Solid Earth, 117(B8):B08409.
Caskey S J, Wesnousky S G. 1997. Static stress changes and earthquake triggering during the 1954 Fairview Peak and Dixie Valley earthquakes, Central Nevada［J］. Bulletin of the Seismological Society of America, 87(3):521-527.
Chen G L, Spetzler H. 1993. Topographic characteristics of laboratory induced shear fractures［J］. Pure and Applied Geophysics, 140(1):123-135.
Chester F M, Chester J S. 2000. Stress and deformation along wavy frictional faults［J］. Journal of Geophysical Research:Solid Earth, 105(B10):23421-23430.
Choi J H, JIN Kwang-min, Enkhbayar D, et al. 2012. Rupture propagation inferred from damage patterns, slip distribution, and segmentation of the 1957 M_W8.1 Gobi-Altay earthquake rupture along the Bogd fault, Mongolia［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 117(B12):B12401.
Clark D, McPherson A, Allen T, et al. 2013. Coseismic Surface Deformation Caused by the 23 March 2012 M_W5.4 Ernabella(Pukatja)Earthquake, Central Australia:Implications for Fault Scaling Relations in Cratonic Settings［J］. Bulletin of the Seismological Society of America, 104(1):24-39.
Crone A J, Machette M N. 1984. Surface faulting accompanying the Borah Peak earthquake, central Idaho［J］. Geology, 12(11):664-667.
Deng Q D, Chen S F, Song F M, et al. 1986. Variations in the geometry and amount of slip on the Haiyuan(Nanxihaushan)fault zone, China and the surface rupture of the 1920 Haiyuan earthquake[M]//Das S, Boatwright J, Scholz C H, eds. Earthquake Source Mechanics. Geophysical Monograph, Washington, DC:169-182.
Deng Q D, Zhang P Z. 1984. Research on the geometry of shear fracture zones［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 89(B7):5699-5710.
DePolo C M, Clark D G, Slemmons D B, et al. 1991. Historical surface faulting in the Basin and Range Province, western North America:implications for fault segmentation［J］. Journal of Structural Geology, 13(2):123-136.
Dieterich J H, Smith D E. 2009. Nonplanar faults:mechanics of slip and off-fault damage［J］. Pure and Applied Geophysics, 166(10-11):1799-1815.
Eberhart P D, Haeussler P J, Freymueller J T, et al. 2003. The 2002 Denali Fault earthquake, Alaska:A large magnitude, slip-partitioned event［J］. Science, 300(5622):1113-1118.
Florensov N A, Solonenko V P. 1963. The Gobi-Altai Earthquake(Gobi-Altaiskoe Zemletryasenie)[M]. Moscow:Akademie Nauk USSR. Translated by Rosental E, U.S. Department of Commerce, Washington D C, 1965.
Gold R D, Reitman N G, Briggs R W, et al. 2015. On-and off-fault deformation associated with the September 2013 M_W7.7 Balochistan earthquake:Implications for geologic slip rate measurements［J］. Tectonophysics, 660:65-78.
Hough S E. 2004. Revisiting the 23 February 1892 Laguna Salada earthquake［J］. Bulletin of the Seismological Society of America, 94(4):1571-1578.
Kaneda H, Nakata T, Tsutsumi H, et al. 2008. Surface rupture of the 2005 kashmir, Pakistan, earthquake and its active tectonic implications［J］. Bulletin of the Seismological Society of America, 98(2):521-557.
King G, Nábělek J. 1985. Role of fault bends in the initiation and termination of earthquake rupture［J］. Science, 228(4702):984-987.
Klinger Y. 2005. High-Resolution Satellite Imagery Mapping of the Surface Rupture and Slip Distribution of the M_W7.8, 14 November 2001 Kokoxili Earthquake, Kunlun Fault, Northern Tibet, China［J］. Bulletin of the Seismological Society of America, 95(5):1970-1987.
Klinger Y, Michel R, King G C P. 2006. Evidence for an earthquake barrier model from M_W7.8 Kokoxili(Tibet)earthquake slip-distribution［J］. Earth and Planetary Science Letters, 242(3-4):354-364.
Klinkenberg B, Goodchild M F. 1992. The fractal properties of topography:A comparison of methods［J］. Earth Surface Processes and Landforms, 17(3):217-234.
Kurushin R A, Olziybat M, Enhtuvshin B, et al. 1997. The Surface Rupture of the 1957 Gobi-Altay, Mongolia, Earthquake[M]. Geological Society of America, Washington, DC.
Langridge R M, Stenner H D, Fumal T E, et al. 2002. Geometry, slip distribution, and kinematics of surface rupture on the Sakarya fault segment during the 17 August 1999 Izmit, Turkey, earthquake［J］. Bulletin of the Seismological Society of America, 92(1):107-125.
Lay T, Kanamori H, Ruff L. 1982. The asperity model and the nature of large subduction zone earthquakes［J］. Earthquake Prediction Research, 1:3-71.
Lee J J, Bruhn R L. 1996. Structural anisotropy of normal fault surfaces［J］. Journal of Structural Geology, 18(8):1043-1059.
Lee Y H, Hsieh M L, Lu S D, et al. 2003. Slip vectors of the surface rupture of the 1999 Chi-Chi earthquake, western Taiwan［J］. Journal of Structural Geology, 25(11):1917-1931.
Lin A, Ouchi T, Chen A, et al. 2001. Co-seismic displacements, folding and shortening structures along the Chelungpu surface rupture zone occurred during the 1999 Chi-Chi(Taiwan)earthquake［J］. Tectonophysics, 330(3-4):225-244.
Lin A M, Rao G, Jia D, et al. 2011. Co-seismic strike-slip surface rupture and displacement produced by the 2010 M_W6.9 Yushu earthquake, China, and implications for Tibetan tectonics［J］. Journal of Geodynamics, 52(3-4):249-259.
Machette M N, Crone A J, Bowman J R. 1993. Geologic Investigations of the 1986 Marryat Creek, Australia, Earthquake:Implications for Paleoseismicity in Stable Continental Regions. Washington:USGS Bulletin, 2032-B:8-10.
McGill S F, Rubin C M. 1999. Surficial slip distribution on the central Emerson fault during the June 28, 1992, Landers earthquake, California［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 104(B3):4811-4833.
Okubo P G, Aki K. 1987. Fractal geometry in the San Andreas fault system［J］. Journal of Geophysical Research:Solid Earth, 92(B1):345-355.
Peltzer G, Crampé F, King G. 1999. Evidence of nonlinear elasticity of the crust from the M_W7.6 Manyi(Tibet)earthquake［J］. Science, 286(5438):272-276.
Perron J T, Kirchner J W, Dietrich W E. 2008. Spectral signatures of characteristic spatial scales and nonfractal structure in landscapes［J］. Journal of Geophysical Research:Earth Surface, 113(F4):F04003.
Power W L, Tullis T E. 1991. Euclidean and fractal models for the description of rock surface roughness:J Geophys Res V96, NB1, Jan 1991, P415-424［J］. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, 28(6):A344.
Power W L, Tullis T E, Weeks J D. 1988. Roughness and wear during brittle faulting［J］. Journal of Geophysical Research:Solid Earth, 93(B12):15268-15278.
Quigley M, Van Dissen R, Litchfield N, et al. 2012. Surface rupture during the 2010 M_W7.1 Darfield(Canterbury)earthquake:Implications for fault rupture dynamics and seismic-hazard analysis［J］. Geology, 40(1):55-58.
Ren Z K. 2013. Geometry and deformation features of the most recent co-seismic surface ruptures along the Xiaojiang Fault and its tectonic implications for the Tibetan plateau［J］. Journal of Asian Earth Sciences, 77:21-30.
Rymer M J, Ellsworth W L. 1990. The Coalinga, California, earthquake of May 2, 1983. Washington:USGS Prof. Paper, 1478:299.
Sagy A, Brodsky E E, Axen G J. 2007. Evolution of fault-surface roughness with slip［J］. Geology, 35(3):283.
Sagy A, Tesei T, Collettini C. 2017. Fault-surface geometry controlled by faulting mechanisms:Experimental observations in limestone faults［J］. Geology, 45(9):851-854.
Sayles R S, Thomas T R. 1978. Surface topography as a nonstationary random process［J］. Nature, 271(5644):431-434.
Schmittbuhl J, Gentier S, Roux Stéphane. 1993. Field measurements of the roughness of fault surfaces［J］. Geophysical Research Letters, 20(8):639-641.
Scholz C H. 1985. The Black Mountain asperity:Seismic hazard of the southern San Francisco Peninsula, California［J］. Geophysical Research Letters, 12(10):717-719.
Scholz C H. 1987. Wear and gouge formation in brittle faulting［J］. Geology, 15(6):493-495.
Scholz C H. 1988. The brittle-plastic transition and the depth of seismic faulting［J］. Geologische Rundschau, 77(1):319-328.
Scholz C H. 2002. The Mechanics of Earthquakes and Faulting[M]. Cambridge University Press, Cambridge.
Scholz C H, Aviles C A. 1986. The fractal geometry of faults and faulting[M]//Das S, Boatwright J, Scholz C H, eds. Earthquake Source Mechanics. Weily, Washington D.C:147-155.
Sharp R V, Budding K E, Boatwright J, et al. 1989. Surface faulting along the Superstition Hills fault zone and nearby faults associated with the earthquakes of 24 November 1987［J］. Bulletin of the Seismological Society of America, 79(2):252-281.
Sharp R V, Rymer M J, Lienkaemper J J. 1986. Surface displacement on the Imperial and Superstition Hills faults triggered by the Westmorland, California, earthquake of 26 April 1981［J］. Bulletin of the Seismological Society of America, 76(4):949-965.
Sibson R H. 1985. Stopping of earthquake ruptures at dilational fault jogs［J］. Nature, 316(6025):248-251.
Sieh K E. 1984. Slip Along the San Andreas Fault Associated with the Great 1857 Earthquake［J］. Bulletin of the Seismological Society of America, 68(5):1421-1448.
Smith S W, Wyss M. 1968. Displacement on the San Andreas Fault subsequent to the 1966 Parkfield earthquake［J］. Bulletin of the Seismological Society of America, 58(6):1955-1973.
Sung Q C, Chen Y C. 2004. Self-affinity dimensions of topography and its implications in morphotectonics:An example from Taiwan［J］. Geomorphology, 62(3-4):181-198.
Sung Q C, Chen Y C, Chao P C. 1998. Spatial variation of fractal parameters and its geological implications［J］. Terrestrial, Atmospheric and Oceanic Sciences, 9(4):655-672.
Tchalenko J S, Berberian M. 1975. Dasht-e Bay-az fault, Iran:earthquake and earlier related structures in bed rock［J］. GSA Bulletin, 86(5):703-709.
Treiman J A, Kendrick K J, Bryant William A, et al. 2002. Primary surface rupture associated with the M_W7.1 16 October 1999 hector mine earthquake, san bernardino county, california［J］. Bulletin of the Seismological Society of America, 92(4):1171-1191.
Tullis T E, Weeks J D. 1986. Constitutive behavior and stability of frictional sliding of granite[M]//Tullis T E, ed. Friction and Faulting. Birkhäuser, Basel:Springer. 383-414.
Tun S T, Wang Y, Khaing S N, et al. 2014. Surface ruptures of the M_W6. 8 March 2011 Tarlay earthquake, eastern Myanmar［J］. Bulletin of the Seismological Society of America, 104(6):2915-2932.
Wallace R E, Bonilla M G, Villalobos H A. 1984. Faulting related to the 1915 earthquakes in Pleasant Valley, Nevada. Washington:USGS Prof. Paper, 1274-A, B:57.
Wei S J, Fielding J, Leprince S, et al. 2011. Superficial simplicity of the 2010 El Mayor-Cucapah earthquake of Baja California in Mexico［J］. Nature Geoscience, 4(9):615-618.
Wei Z Y, He H L, Shi F. 2013. Weathering history of an exposed bedrock fault surface interpreted from its topography［J］. Journal of Structural Geology, 56:31-44.
Xu R, Li L X, Zhang L Q, et al. 2014. Influence of pressure and surface roughness on the heat transfer efficiency during water spray quenching of 6082 aluminum alloy［J］. Journal of Materials Processing Technology, 214(12):2877-2883.
Xu X W, Wen X Z, Yu G H, et al. 2009. Coseismic reverse-and oblique-slip surface faulting generated by the 2008 M_W7.9 Wenchuan earthquake, China［J］. Geology, 37(6):515-518.
Xu X W, Yu G H, Klinger Y, et al. 2006. Reevaluation of surface rupture parameters and faulting segmentation of the 2001 Kunlunshan earthquake(M_W7.8), northern Tibetan plateau, China［J］. Journal of Geophysical Research:Solid Earth(1978-2012), 111(B5):B05316.
Yielding G, Jackson J A, King G C P, et al. 1981. Relations between surface deformation, fault geometry, seismicity, and rupture characteristics during the El Asnam(Algeria)earthquake of 10 October 1980［J］. Earth and Planetary Science Letters, 56:287-304.
Yomogida K, Nakata T. 1994. Large slip velocity of the surface rupture associated with the 1990 Luzon earthquake［J］. Geophysical Research Letters, 21(17):1799-1802.
Zhang P Z, Mao F Y, Slemmons D B. 1999. Rupture terminations and size of segment boundaries from historical earthquake ruptures in the Basin and Range Province［J］. Tectonophysics, 308(1-2):37-52.

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[13]	闫兵, 贾东. 沿走滑活动断层的基岩河道系统位错——以青藏高原东部为例[J]. 地震地质, 2017, 39(6): 1127-1142.
[14]	邵延秀, 张波, 邹小波, 王爱国, 张帆宇, 袁道阳, 刘兴旺, 何文贵. 采用无人机载LiDAR进行快速地质调查实践[J]. 地震地质, 2017, 39(6): 1185-1197.
[15]	徐锡伟, 郭婷婷, 刘少卓, 于贵华, 陈桂华, 吴熙彦. 活动断层避让相关问题的讨论[J]. 地震地质, 2016, 38(3): 477-502.