利用灰岩断层面形貌特征识别罗云山山前断裂古地震信息

doi:10.3969/j.issn.0253-4967.2019.02.009

摘要/Abstract

摘要： 以山西地堑系罗云山山前断裂的基岩断层面为例，用陆基LiDAR扫描获取了断层面形貌学数据，采用各向同性变差函数法计算了断层面形貌的分维值。结果显示，断层面形貌在高度上具有显著的分带性，每个分带的特征分维值随断层面高度的增加呈阶跃式变化。分析认为这种形貌特征可能反映了断层面与多次地震相关的间歇式出露方式。分带高度指示了约3m和1m的2组同震倾滑位移量，各分带之间的分维值过渡带是断层面缓慢剥露的结果。与片麻岩区的断层面形貌学研究结果相比，灰岩断层面形貌学分维值随着暴露时间的增加而减小，2种岩性区的断层面分维值D与断层面高度H呈现类似镜像的关系，在气候构造条件大致相同的情况下，考虑为岩性差异的影响。

关键词: 古地震, 基岩断层面形貌, 各向同性变差函数法, 罗云山山前断裂

Abstract: The quantitative analysis of morphologic characteristics of bedrock fault surface is a useful approach to study faulting history and identify paleo-earthquake. It is an effective complement to trenching technique, specially to identifying paleo-earthquakes in a bedrock area where the trenching technique cannot be applied. This paper focuses on the Luoyunshan piedmont fault, which is an active normal fault extending along the eastern boundary of the Shanxi Graben, China. There are a lot of fault scarps along the fault zone, which supply plentiful samples to be selected to our research, that is, to study faulting history and identify paleo-earthquakes in bedrock area by the quantitative analysis of morphologic characteristics of fault surfaces. In this paper, we calculate the 2D fractal dimension of two bedrock fault surfaces on the Luoyunshan piedmont fault in the Shanxi Graben, China using the isotropic empirical variance function, which is a popular method in fractal geometry. Results indicate that the fractal dimension varies systematically with height above the base of the fault surface exposures, indicating segmentation of the fault surface morphology. The 2D fractal dimension on a fault surface shows a ‘stair-like’ vertical segmentation, which is consistent with the weathering band and suggests that those fault surfaces are outcropped due to periodic faulting earthquakes. However, compared to the results of gneiss obtained by the former researchers, the characteristic fractal value of limestone shows an opposite evolution trend. 1)The paleo-earthquake study of the bedrock fault surface can be used as a supplementary method to study the activity history of faults in specific geomorphological regions. It can be used to fill the gaps in the exploration of the paleo-earthquake method in the bedrock area, and then broaden the study of active faults in space and scope. The quantitative analysis of bedrock fault surface morphology is an effective method to study faulting history and identify paleo-earthquake. The quantitative feature analysis method of the bedrock fault surface is a cost-effective method for the study of paleo-earthquakes in the bedrock fault surface. The number of weathered bands and band height can be identified by the segment number and segment height of the characteristic fractal dimension, and then the paleoearthquake events and the co-seismic displacement can be determined; 2)The exposure of the fault surface of the Luoyunshan bedrock is affected and controlled by both fault activity and erosion. A strong fault activity(ruptured earthquake)forms a segment of fault surface which is equivalent to the vertical co-seismic displacement of the earthquake. After the segment is cropped out, it suffers from the same effect of weathering and erosion, and thus this segment has approximately the same fractal dimension. Multiple severe fault activities(ruptured earthquake)form multiple fault surface topography. The long-term erosion under weak hydrodynamic conditions at the base of the fault cliff between two adjacent fault activities(intermittent period)will form a gradual slow-connect region where the fractal dimension gradually changes with the height of the fault surface. Based on the segmentation of quantitative morphology of the two fault surfaces on the Luoyunshan piedmont fault, we identified four earthquake events. Two sets of co-seismic displacement of about 3m and 1m on the fault are obtained; 3)The relationship between the fault surface morphology parameters and the time is described as follows:The fractal dimension of the limestone area decreases with the increase of the exposure time, which reflects the gradual smoothing characteristics after exposed. The phenomenon is opposite to the evolution of the geological features of gneiss faults acquired by the predecessors on the Huoshan piedmont fault; 4)Lithology plays an important role in morphology evolution of fault surface and the two opposite evolution trends of the characteristic fractal value on limestone and gneiss show that the weathering mechanism of limestone is different from that of the gneiss.

Key words: paleo-earthquake, morphology of bedrock fault surface, isotropic empirical variogram, Luoyunshan piedmont fault

中图分类号:

P931.2

邹俊杰, 何宏林, 石峰, 魏占玉, 苏鹏, 闫小兵. 利用灰岩断层面形貌特征识别罗云山山前断裂古地震信息[J]. 地震地质, 2019, 41(2): 400-418.

ZOU Jun-jie, HE Hong-lin, SHI Feng, WEI Zhan-yu, SU Peng, YAN Xiao-bing. IDENTIFICATION OF PALEO-EARTHQUAKES OF LUOYUNSHAN PIEDMONT FAULT BY QUANTITATIVE MORPHOLOGY OF LIMESTONE FAULT SURFACES[J]. SEISMOLOGY AND GEOLOGY, 2019, 41(2): 400-418.

参考文献

艾南山, 李后强. 1993. 从曼德布罗特景观到分形地貌学［J］. 地理学与国土研究 9(1):13-17.
AI Nan-shan, LI Hou-qiang. 1993. From the Mandelbrot landscape to the fractal geomorphology ［J］. Geography and Territorial Research, 9(1):13-17(in Chinese).
曹忠权, 吴裕文. 1986. 罗云山断裂带第四纪活动特征［J］. 地震, (6):35-40.
CAO Zhong-quan, WU Yu-wen. 1986. Features of Quaternary movement of the Luoyunshan fault zone ［J］. Earthquake, (6):35-40(in Chinese).
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, 苏宗正, 王挺梅, 等. 1993. 临汾盆地晚第四纪沉积与新构造运动［M］//马宗晋主编. 山西临汾地震研究与系统减灾. 北京:地震出版社:111-129.
DENG Qi-dong, SU Zong-zheng, WANG Ting-mei, et al. 1993. Late Quaternary Deposition and Neotectonic Movement of Linfen Basin［M］//MA Zong-jin(ed).Linfen Earthquake Research and Systematic Disaster Reduction in Shanxi. Seismological Press, Beijing:111-129(in Chinese).
邓起东, 王克鲁, 汪一鹏, 等. 1973. 山西隆起区断陷地震带地质条件及地震发展趋势概述［J］. 地质科学, (1):37-47.
DENG Qi-dong, WANG Ke-lu, WANG Yi-peng, et al. 1973. A review of seismo-geological conditions and seismic activity tendency in Shanxi faulted depression of Shanxi uplift zone［J］. Chinese Journal of Geology, (1):37-47(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).
国家地震局地震地质大队, 北京大学地质地理系. 1979. 临汾盆地活动构造体系与地震［A］//中国地质科学院地质力学研究所编. 地质力学论丛(5). 北京:科学出版社:140-150.
Seismo-geological Brigade, State Seismological Bureau, Geology and Geography Department, Peking University. 1979. Active tectonic system and earthquake in Linfen Basin［A］//Institute of Geomechanics, Chinese Academy of Geological Sciences. Collected Papers and Notes on Geomechanics, No. 5. Science Press, Beijing:140-150(in Chinese).
国家地震局 "鄂尔多斯周缘活动断裂系"课题组. 1988. 鄂尔多斯周缘活动断裂系［M］. 北京:地震出版社.
The Research Group on Active Fault System around Ordos Massif, State Seismological Bureau. 1988. Active Fault System around Ordos Massif［M］. Seismological Press, Beijing(in Chinese).
何宏林, 魏占玉, 毕丽思, 等. 2015. 利用基岩断层面形貌定量特征识别古地震:以霍山山前断裂为例［J］. 地震地质, 37(2):61-73. doi:10.3969/j.issn.0253-4967.2015.02.005.
HE Hong-lin, WEI Zhan-yu, BI Li-si, et al. 2015. Identify paleo-earthquake using quantitative morphology of bedrock fault surface:A case study on the Huoshan piedmont fault［J］. Seismology and Geology, 37(2):61-73(in Chinese).
刘光勋. 1985. 汾渭地堑系边缘挤压构造带及其地质意义［A］//构造地质论丛(4). 北京:地震出版社.
LIU Guang-xun. 1985. Compressional tectonic zones on the Linfen-Weihe graben margin and its geological significance［A］//Collected Papers and Notes on Tectonics, No4. Seismological Press, Beijing(in Chinese).
龙毅, 周侗, 汤国安, 等. 2007. 典型黄土地貌类型区的地形复杂度分形研究［J］. 山地学报, 25(4):385-395.
LONG Yi, ZHOU Tong, TANG Guo-an, et al. 2007. Research on terrain complexity of several typical regions of loess landform based on fractal method［J］. Journal of Mountain Science, 25(4):385-395(in Chinese).
罗明. 2016. 岩石暴露面光释光测年初探［D］. 北京:中国地震局地质研究所.
LUO Ming. 2016. Optical stimulated luminescence dating of rock surfaces［D］. Institute of Geology, China Earthquake Administration, Beijing(in Chinese).
冉勇康, 邓起东. 1999. 古地震学研究的历史、现状和发展趋势［J］. 科学通报, 44(1):12-20.
RAN Yong-kang, DENG Qi-dong. 1999. History, present situation and trend of paleo-seismology［J］. Chinese Science Bulletin, 44(1):12-20(in Chinese).
石峰, 何宏林, Alexander L D, 等. 2016. 二维分形参数与构造活动关系研究:以滇西南块体为例［J］. 地震地质, 38(4):862-873. doi:10.3969/j.issn.0253-4967.2016.04.005.
SHI Feng, HE Hong-lin, Alexander L D, et al. 2016. Research on the relationship between fractal factors and tectonic activity:A case study of southeastern Yunnan block［J］. Seismology and Geology, 38(4):862-873(in Chinese).
孙昌斌, 谢新生, 许建红. 2011. 罗云山山前断裂带阶地调查研究及其构造［J］. 中国地震, 27(2):126-135.
SUN Chang-bin, XIE Xin-sheng, XU Jian-hong. 2011. Research on terraces investigation of Luoyunshan fault zone and its tectonic implication［J］. Earthquake Research in China, 27(2):126-135(in Chinese).
孙昌斌, 谢新生, 许建红. 2013. 罗云山山前断裂中段土门-贾朱村晚第四纪断错地貌特征［J］. 中国地震, 29(3):347-357.
SUN Chang-bin, XIE Xin-sheng, Xu Jian-hong. 2013. Late Quaternary faulted landforms characteristics on the Tumen-Jiazhu village segment of the Luoyunshan piedmont fault［J］. Earthquake Research in China, 29(3):347-357(in Chinese).
王乃樑, 杨景春, 夏正楷, 等. 1996. 山西地堑系新生代沉积与构造地貌［M］. 北京:科学出版社. 1-392.
WANG Nai-liang, YANG Jing-chun, XIA Zheng-kai, et al. 1996. Cenozoic Sedimentary and Tectonic Geomorphology in Shanxi Graben System［M］. Science Press, Beijing:1-392(in Chinese).
魏占玉. 2010. 断层面高精度形貌学定量研究［D］. 北京:中国地震局地质研究所.
WEI Zhan-yu. 2010. A quantitative study of the topography of fault surfaces with high accuracy［D］. Institute of Geology, China Earthquake Administration, Beijing(in Chinese).
谢焱石, 谭凯旋, 陈广浩. 2004, 地表的分形测量及其大地构造学意义［J］. 大地构造与成矿学, 28(1):74-80.
XIE Yan-shi, TAN Kai-xuan, CHEN Guang-hao. 2004. Fractal measure of the earth's surface and its significance to geo-tectonics［J］. Geotectonica et Metallogenia, 28(1):74-80(in Chinese).
许建红, 谢新生, 孙昌斌. 2011. 山西罗云山山前断裂带中段龙祠-峪口全新世活动证据［J］. 地震地质, 33(4):119-128. doi:10.3969/j.issn.0253-4967.2011.04.010.
XU Jian-hong, XIE Xin-sheng, SUN Chang-bin. 2011. The Holocene active evidence on the Longci-Yukou segment of Luoyunshan frontal fault zone, Shanxi［J］. Seismology and Geology, 33(4):119-128(in Chinese).
Benedetti L, Finkel R, Armijo R, et al. 2000. Earthquake time-slip histories determined from in situ ³⁶Cl cosmogenic dating of limestone fault scarps the Sparta normal fault(Greece)［C］. Eos, Trans, AGU, 81(Suppl48), Fall Meeting, Abstract:T71E-10.
Benedetti L, Manighetti I, GaudemerY, et al. 2013. Earthquake synchrony and clustering on Fucino faults(Central Italy)as revealed from in situ 36Cl exposure dating［J］. Journal of Geophysical Research:Solid Earth, 118:4948-4974.
Bi L, He H, Wei Z, et al. 2012. Fractal properties of landforms in the Ordos Block and surrounding areas, China［J］. Geomorphology, 175-176:151-162.
Brown S R. 1995. Simple mathematical model of a rough fracture［J］. Journal of Geophysical Research:Solid Earth, 100(B4):59415952.
Candela T, Renard F, Bouchon M, et al. 2009. Characterization of fault roughness at various scales:Implication of three-dimensional high resolution topography measurements［J］. Pure and Applied Geophysics, 166(10-11):1817-1851.
Carr J R, Benzer W B. 1991. On the practice of estimating fractal dimension［J］. Mathematical Geology, 23(7):945-958.
Chao P C. 1995. Landform simulation and the fractal properties of topography on Taiwan［D］. National Cheng Kung University, Tainan.
Davies S. 1999. Fractal analysis of surface roughness by using spatial data［J］. Journal of the Royal Statistical Society, 61(Part 1):3-37.
Giaccio B, Galadini F, Sposato A, et al. 2002. Image processing and roughness analysis of exposed bedrock fault planes as a tool for paleoseismological analysis:Results from the Campo Felice Fault(central Apennines, Italy)［J］. Geomorphology, 49(3):281-301.
He H L, Wei Z Y, Densmore A. 2016. Quantitative morphology of bedrock fault surfaces and identification of paleo-earthquakes［J］. Tectonophysics, 693:22-31.
Klinkenberg B. 1992. Fractals and morphometric measures:Is there a relationship?［J］. Geomorphology, 5(6):5-20.
Klinkenberg B, Goodchild M F. 1992. The fractal properties of topography:A comparison of methods［J］. Earth Surface Processes and Landform, 17(3):217-234.
Mayer L. 1984. Dating Quaternary fault scarps formed in alluvium using morphologic parameters［J］. Quaternary Research. 22(3):300-313.
Mitchell S G, Matmon A, Bierman P R, et al. 2001. Displacement history of a limestone normal fault scarp, northen Israel, from cosmogenic ³⁶Cl［J］. Journal of Geophysical Research:Solid Earth, 106(B3):4247-4264.
Ohnaka M. 2003. A constitutive scaling law and a unified comprehension for frictional slip failure, shear fracture of intact rock, and earthquake rupture［J］. Journal of Geophysical Research:Solid Earth, 108(B2):2080. doi:10.1029/2000JB000123.
Palumbo L, Benedetti L, Bourlès D, et al. 2004. Slip history of the Magnola Fault(Apennines, central Italy) from ³⁶Cl surface exposure dating:Evidence for strong earthquakes over the Holocene［J］. Earth and Planetary Science Letters, 225(1-2):163-176.
Pentland A P. 1984. Fractal-based description of natural scenes［J］. IEEE Transaction on Pattern Analysis and Machine Intelligence, 6(6):666-674.
Power W L, Tullis T E. 1991. Euclidean and fractal models for the description of rock surface-roughness［J］. Journal of Geophysical Research, 96(B1):415-424.
Power W L, Tullis T E, Brown S R, et al. 1987. Roughness of natural fault surfaces［J］. Geophysical Research Letters, 14(1):29-32.
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.
Renard F, Voisin C, Marsan D, et al. 2006. High resolution 3D laser scanner measurements of a strike-slip fault quantify its morphological anisotropy at all scales［J］. Geophysical Research Letters, 33(4):L04305. doi:10.1029/2005GL025038.
Sagy A, Brodsky E E, Axen G J. 2007. Evolution of fault-surface roughness with slip［J］. Geology, 35:283-286.
Stewart I. 1996. A rough guide to limestone fault scarps［J］. Journal of Structural Geology, 18(10):1259-1264.
Schlagenhauf A, Gaudemer Y, Benedetti L, et al. 2010. Using in situ Chlorine-36 cosmonuclide to recover past earthquake histories on limestone normal fault scarps:A reappraisal of methodology and interpretations［J］. Geophysical Journal International, 182:36-72.
Sung Q C, Chen Y C. 2004. Self-affinity dimensions of topography and its implicationsin morph-tectonics: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, 94(4):655-672.
Wallace R E. 1984. Fault scarps formed during the earthquake of October 2, 1915, Pleasant Valley, Nevada and some tectonic implications［J］. US Geological Survey Professional Paper, 1274-A.
Wei Z Y, He H L, Shi F, et al. 2010. Topographic characteristics of rupture surface associated with the 12 May 2008 Wenchuan earthquake［J］. Bulletin of the Seismological Society of America, 100(5B):2669-2680. doi:10.1785/0120090260.
Xu T B, Moore I D, Gallant J C. 1993. Fractals, fractal dimensions and landscapes:A review［J］. Geomorphology, 8(4):245-262.
Zreda M, Noll J S. 1998. Ages of prehistoric earthquakes revealed by cosmogenic Chlorine-36 in a bedrock fault scarp at Hebgen Lake［J］. Science, 282(5391):1097.

[1]	刘庆, 刘韶, 张世民. 大凉山断裂带中段越西断裂晚第四纪古地震[J]. 地震地质, 2023, 45(2): 321-337.
[2]	李安, 万波, 王晓先, 计昊旻, 索锐. 金州断裂盖州北鞍山段古地震破裂的新证据[J]. 地震地质, 2023, 45(1): 111-126.
[3]	郑海刚, 姚大全, 赵朋, 杨源源, 黄金水. 郯庐断裂带赤山段全新世新活动的特征[J]. 地震地质, 2023, 45(1): 127-138.
[4]	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.
[5]	石文芳, 徐伟, 尹金辉, 郑勇刚. 秦岭北缘古地震基岩崩塌和滑坡施密特锤暴露年龄[J]. 地震地质, 2022, 44(6): 1384-1402.
[6]	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.
[7]	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.
[8]	冯嘉辉, 陈立春, 王虎, 刘姣, 韩明明, 李彦宝, 高帅坡, 卢丽莉. 大凉山断裂带北段石棉断裂的古地震[J]. 地震地质, 2021, 43(1): 53-71.
[9]	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.
[10]	张玲, 杨晓平, 李胜强, 黄伟亮, 杨海波. 秋里塔格褶皱带东段探槽的古地震事件[J]. 地震地质, 2020, 42(5): 1039-1057.
[11]	黄帅堂, 胡伟华, 杨攀新, 李帅, 伊力亚尔. 东天山唐巴勒-塔斯墩断裂带晚第四纪活动特征[J]. 地震地质, 2020, 42(5): 1058-1071.
[12]	王莅斌, 尹功明, 袁仁茂, 王盈, 苏刚. 金沙江中游永胜昔格达层软沉积变形构造[J]. 地震地质, 2020, 42(5): 1072-1090.
[13]	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.
[14]	覃金堂, 陈杰, 李涛. 阿尔金断裂带中段现代沉积物样品钾长石红外激发后红外释光的残留信号——对年轻古地震事件测年的指示意义[J]. 地震地质, 2020, 42(4): 981-992.
[15]	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.