四川绵竹清平乡“8·13”走马岭特大泥石流灾害特征
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摘要
2010年8月13日四川省绵竹市清平乡普降暴雨导致走马岭沟暴发泥石流,主沟及支沟内的大量松散堆积物一起冲出,导致绵远河改道。为了探讨强震区泥石流灾害的形成原因及成灾机理,利用野外现场调查资料和航空图像解译成果对马岭泥石流的流域特征,特别是地震条件下的泥石流物源特征,进行了分析。结果表明走马岭特大泥石流受降雨影响显著,流速为7.19m/s,最大洪峰流量为866.35m3/s,一次泥石流过流总量为121.64×104 m3,显示了强震区泥石流暴发的特点。认为震后绵远河区域进入了泥石流的高发期,降雨是强震区诱发泥石流的主要动力因素,泥石流暴发主要受前期累积雨量和当次激发雨量共同作用。
On August 13,2010,the rainstorms in Qingping town of Mianzhu City caused a catastrophic debris flow which resulted in a large amount of loose materials removing out the catchment.The debris flow deposits caused the Mianyuan River to change its original channel.In order to explore the formation and mechanism of the debris flow in seismic regions,based on field surveys and aerial image interpretation,this paper analyses the watershed characteristics,and especially the characteristics of sediment supply for the debris flow occurrence in the Zoumaling basin.The results show that the rainfall is a significant factor of the Zoumaling debris flow.The velocity is 7.19 m/s,the maximum peak discharge is 866.35 m3/s,and a mud-rock flow volume amounts to 121.64×104 m3.The debris flow in the Zoumaling basin typically shows that debris flow activities will be more frequent in a long period,that rainfall is the main dynamic factor of debris flows in seismic regions and that debris flow is mainly affected by the joint action of the cumulative rainfall and a rainfall at that time.
On August 13,2010,the rainstorms in Qingping town of Mianzhu City caused a catastrophic debris flow which resulted in a large amount of loose materials removing out the catchment.The debris flow deposits caused the Mianyuan River to change its original channel.In order to explore the formation and mechanism of the debris flow in seismic regions,based on field surveys and aerial image interpretation,this paper analyses the watershed characteristics,and especially the characteristics of sediment supply for the debris flow occurrence in the Zoumaling basin.The results show that the rainfall is a significant factor of the Zoumaling debris flow.The velocity is 7.19 m/s,the maximum peak discharge is 866.35 m3/s,and a mud-rock flow volume amounts to 121.64×104 m3.The debris flow in the Zoumaling basin typically shows that debris flow activities will be more frequent in a long period,that rainfall is the main dynamic factor of debris flows in seismic regions and that debris flow is mainly affected by the joint action of the cumulative rainfall and a rainfall at that time.
引文
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[2]常鸣,唐川,李为乐,等.汶川地震区绵远河流域泥石流形成区的崩塌滑坡特征[J].山地学报,2012,30(5):561-569.
[3]陈晓利,祁生文,叶洪.基于GIS的地震滑坡危险性的模糊综合评价研究[J].北京大学学报:自然科学版,2008,44(3):434-438.
[4]Conoscenti C,DI Maggio C,Rotiglinao E.GIS anal-ysis to assess landslide susceptibility in a fluvial basinof NW Sicily(Italy)[J].Geomorphology,2008,94:325-339.
[5]许强.四川省8.13特大泥石流灾害特点、成因与启示[J].工程地质学报,2010,18(5):610-621.
[6]Caine N.The rainfall intensity-duration control ofshallow landslides and debris flows[J].Geogr Ann,1980,A62:23-27.
[7]Jibson R W.Debris flow in southern Porto Rico[J].Geological Society of America Special Paper,1989,236:29-55.
[8]余斌.不同容重的泥石流淤积厚度计算方法研究[J].防灾减灾工程学报,2010,23(2):78-92.
[9]余斌.黏性泥石流的平均运动速度研究[J].地球科学进展,2008,23(5):524-532.
[10]Tang C,Zhu J,Chang M,et al.An empirical-statistical model for predicting debris flow runoutzones in the Wenchuan earthquake area[J].Quater-nary International,2011,9-10.
[11]Matteo Berti,Alessandro Simoni.Prediction of deb-ris flow inundation areas using empirical mobilityrelationships[J].Geomorphology,2007,90:144-161.
[12]唐川,朱静.GIS支持下的地震诱发滑坡危险区预测研究[J].地震研究,2001,24(1):73-81.
[13]齐信,唐川,铁永波,等.基于GIS技术的汶川地震诱发地质灾害危险性评价———以四川省北川县为例[J].成都理工大学学报:自然科学版,2010,37(2):160-161.
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