Magnitude-frequency relationship of debris flows in the Jiangjia Gully, China 被引量：3

Magnitude-frequency relationship of debris flows in the Jiangjia Gully, China

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摘要 The magnitude-frequency(MF) relationship of debris flows is the basis for engineering designs and risk quantification. However, because of the lack of debris flow monitoring data, research progress in this area has been relatively slow. The MF relationship of debris flows in Jiangjia Gully, Yunnan Province was evaluated based on a regression analysis of 178 debris flow events that occurred from 1987-2004. The magnitude-cumulative frequency(MCF) relationship of the debris flows in the Jiangjia Gully is consistent with the linear logarithmic transformation function. Moreover, observed data for debris flows in Hunshui Gully of Yunnan Province and Huoshao Gully, Liuwan Gully, and Niwan Gully of Gansu Province were used to verify the function. The results showed that the MCF relationship of highfrequency debris flows is consistent with the power law equation, although the regression coefficients in the equation are considerably different. Further analysis showed a strong correlation between the differences in the constants and the drainage area and daily maximum precipitation. The magnitude-frequency(MF) relationship of debris flows is the basis for engineering designs and risk quantification. However, because of the lack of debris flow monitoring data, research progress in this area has been relatively slow. The MF relationship of debris flows in Jiangjia Gully, Yunnan Province was evaluated based on a regression analysis of 178 debris flow events that occurred from 1987-2004. The magnitude-cumulative frequency(MCF) relationship of the debris flows in the Jiangjia Gully is consistent with the linear logarithmic transformation function. Moreover, observed data for debris flows in Hunshui Gully of Yunnan Province and Huoshao Gully, Liuwan Gully, and Niwan Gully of Gansu Province were used to verify the function. The results showed that the MCF relationship of highfrequency debris flows is consistent with the power law equation, although the regression coefficients in the equation are considerably different. Further analysis showed a strong correlation between the differences in the constants and the drainage area and daily maximum precipitation.

作者 GAO Yan-chao CHEN Ning-sheng HU Gui-sheng DENG Ming-feng

机构地区 Key Laboratory of Mountain Hazards and Land Surface Process Chengdu Center University of Chinese Academy of Sciences

出处《Journal of Mountain Science》 SCIE CSCD 2019年第6期1289-1299,共11页 山地科学学报（英文）

基金 supported by The National Key Research and Development Program of China (Grant No. 2018YFC1505406) the National Natural Science Foundation of China (Grant Nos. 41502337, 41671112, 41661134012, 41501012) the China Geological Survey (Grant Nos. DD20160274, DD20190640)

关键词 DEBRIS flow MAGNITUDE CUMULATIVE FREQUENCY Drainage area Precipitation Jiangjia GULLY Debris flow Magnitude Cumulative frequency Drainage area Precipitation Jiangjia Gully

分类号 P642.23 [天文地球—工程地质学]

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参考文献4

1CHEN Ning-sheng,ZHU Yun-hua,HUANG Qi,IQBAL Javed,DENG Ming-feng,HE Na.Mechanisms involved in triggering debris flows,within a cohesive gravel soil mass on a slope:a case in SW China[J].Journal of Mountain Science,2017,14(4):611-620. 被引量：6
2LI Wei-yue,LIU Chun,HONG Yang,ZHANG Xin-hua,WAN Zhan-ming,Manabendra SAHARIA,SUN Wei-wei,YAO Dong-jing,CHEN Wen,CHEN Sheng,YANG Xiu-qin,YUE Jing.A public Cloud-based China's Landslide Inventory Database(Cs LID): development, zone, and spatiotemporal analysis for significant historical events, 1949-2011[J].Journal of Mountain Science,2016,13(7):1275-1285. 被引量：4
3倪化勇,郑万模,唐业旗,徐如阁,王德伟,陈绪钰,宋志.汶川震区文家沟泥石流成灾机理与特征[J].工程地质学报,2011,19(2):262-270. 被引量：37
4余斌,杨永红,苏永超,黄文杰,王高峰.甘肃省舟曲8.7特大泥石流调查研究[J].工程地质学报,2010,18(4):437-444. 被引量：122

二级参考文献48

1CHEN Ningsheng, CUI Peng, LIU Zhonggang & WEI Fangqiang Institute of Mountain Hazards and Environment, Chinese Academy of Sciences and Ministry of Water Resources, Chengdu 610041, China.Calculation of the debris flow concentration based on clay content[J].Science China(Technological Sciences),2003,46(z1):163-174. 被引量：5
2陈宁生,崔鹏,王晓颖,第宝锋.地震作用下泥石流源区砾石土体强度的衰减实验[J].岩石力学与工程学报,2004,23(16):2743-2747. 被引量：26
3中华人民共和国国土资源部.泥石流灾害防治工程勘查规范(报批稿)[M].2006:2.
4章书成,Oldrich Hungr,Olav Slaymaker.泥石流中巨石冲击力计算.泥石流观测与研究,杜榕桓主编.科学出版社[M].1996,67-72.
5谭万沛.泥石流及其灾害的极大值.灾害学,1987,2(3):79-83.
6Tang C,Zhu J,Li W L. Rainfall triggered debris flows after Wenchuan earthquake. Bull Eng Geol Environ, 2009,68: 187- 194.
7Chau K, Sze Y, Ftmg M, et al. (2004) Landslide hazard analysis for Hong Kong using landslide inventory and GIS. Computers & C-eosciences 3o: 49-443. DOI: xoAo16/j.cageo.2003.o8.o13.
8Che VB, Kervyn M, Suh C, et al. (2012) Landslide susceptibility assessment in Limbe (SW Cameroon): A field calibrated seed cell and information value method. Catena 92: 83-98. DOI: 10"1016/! :catella-2.011211.o 14.
9Coe JA, Michael JA, Crovelli RA, et al. (2004) Probabilistic assessment of precipitation-triggered landslides using historical records of landslide occurrence, Seattle, Washington. Environmental & Engineering Geoscience :0: 103-:22. DOI: 10.21:3/:0.2.103.
10Cruden DM (1991) A simple definition of a landslide. Bulletin of Engineering Geo10gy and the Environment 43: 27-9. DOI: 10.1007/BF0259o167.

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2张楠,徐永强.四川宁南县白鹤滩6·28泥石流特征分析[J].中国地质灾害与防治学报,2013,24(4):66-70. 被引量：4
3张金山,崔鹏.泥石流预警及其实施方法[J].水利学报,2012,43(S2):174-180. 被引量：10
4苏洁,周成,陈生水,何建村,何宁,吴艳,张桂荣.石笼拱柔性拦截坝新技术及其数值模拟[J].岩土工程学报,2015,37(2):269-275. 被引量：14
5马东涛.舟曲“8.8”特大泥石流灾害治理之我见[J].山地学报,2010,28(5):635-640. 被引量：15
6张旺锋,张风霖.从舟曲泥石流反思城市地质灾害防治[J].甘肃科技,2011,27(10):53-56. 被引量：8
7朱思军,赵宗勇,高菊英,吴钰梁.马路沟泥石流危险度评价及防治方案[J].三峡大学学报（自然科学版）,2011,33(3):29-33.
8尹洪江,王志兵,胡明鉴.降雨强度对松散堆积土斜坡破坏的模型试验研究[J].土工基础,2011,25(3):74-76. 被引量：12
9张茂省,黎志恒,孙萍萍,赵成,胡向德,曾庆铭.舟曲三眼峪“8.8”特大泥石流灾害特征与风险减缓对策[J].西北地质,2011,44(3):10-20. 被引量：14
10李瑞冬,王根龙,赵成,胡向德,朱立峰,曾庆铭.三眼峪特大泥石流形成的物源条件分析[J].西北地质,2011,44(3):21-29. 被引量：4

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4陈晓清,崔鹏,韦方强.良好植被区泥石流防治初探[J].山地学报,2006,24(3):333-339. 被引量：47
5杨小平,师长兴,李炳元,朱秉启.从地球系统科学角度浅析中国地貌若干问题研究的新进展[J].第四纪研究,2008,28(4):521-534. 被引量：21
6周小进,杨帆.中国南方大陆加里东晚期构造—古地理演化[J].石油实验地质,2009,31(2):128-135. 被引量：18
7JIAO Zhen WANG Daojie XIE Hong ZHANG Jinshan GUO Linghui.Experimental Analysis of Shear Strength of Undisturbed Soil in Leucaena Forest in Jiangjia Ravine,Yunnan,China[J].Journal of Mountain Science,2010,7(4):386-395. 被引量：5
8殷跃平.三峡库区重大地质灾害及防治研究进展[J].矿产勘查,2004(8):20-26. 被引量：3
9赵筱青,和春兰,易琦.大面积桉树引种区土壤水分及水源涵养性能研究[J].水土保持学报,2012,26(3):205-210. 被引量：31
10安慧,李国旗.放牧对荒漠草原植物生物量及土壤养分的影响[J].植物营养与肥料学报,2013,19(3):705-712. 被引量：52

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