[1]胡凯衡,张晓鹏,罗 鸿,等.丹巴县梅龙沟“6.17”泥石流灾害链调查[J].山地学报,2020,(6):945-951.[doi:10.16089/j.cnki.1008-2786.000570]
 HU Kaiheng*,ZHANG Xiaopeng,LUO Hong,et al.Investigation of the “6.17” Debris Flow Chain at the Meilong Catchment of Danba County, China[J].Mountain Research,2020,(6):945-951.[doi:10.16089/j.cnki.1008-2786.000570]
点击复制

丹巴县梅龙沟“6.17”泥石流灾害链调查
分享到:

《山地学报》[ISSN:1008-2186/CN:51-1516]

卷:
期数:
2020年第6期
页码:
945-951
栏目:
研究简报
出版日期:
2020-12-25

文章信息/Info

Title:
Investigation of the “6.17” Debris Flow Chain at the Meilong Catchment of Danba County, China
文章编号:
1008-2786-(2020)6-945-07
作者:
胡凯衡12张晓鹏123罗 鸿4刘斌涛1 陈华勇12
1.中国科学院山地灾害与地表过程重点实验室,成都 610041; 2.中国科学院、水利部成都山地灾害与环境研究所,成都 610041; 3.中国科学院大学,北京 100049; 4.四川省国土空间生态修复与地质灾害防治研究院,成都 610081
Author(s):
HU Kaiheng12* ZHANG Xiaopeng123 LUO Hong4 LIU Bintao12 CHEN Huayong12
1. Key Laboratory of Mountain Hazards and Earth Surface Process, Chinese Academy of Sciences, Chengdu 610041, China; 2. Institute of Mountain Hazards and Environment, Chinese Academy of Sciences & Ministry of Water Conservancy, Chengdu 610041, China; 3. University of Chinese Academy of Sciences, Beijing 100049, China; 4. Sichuan Institute of Land and Space Ecological Restoration and Geological Hazard Prevention, Chengdu 610081, China.
关键词:
泥石流 灾害链 堰塞湖 梅龙沟
Keywords:
debris flow multi-hazard chain dammed lake the Meilong catchment
分类号:
P642.23
DOI:
10.16089/j.cnki.1008-2786.000570
文献标志码:
A
摘要:
2020年6月17日,四川省甘孜州丹巴县半扇门乡梅龙沟暴发大规模泥石流灾害,形成暴雨-泥石流-滑坡-堰塞湖-洪涝灾害链。在前期短历时强降雨激发下,梅龙沟沟道径流沿途铲刮沟道松散堆积物,泥石流冲出量约2.4×105 m3,进入主河约1.3×105 m3,形成堰塞坝; 自然溃流后的泥石流坝残体挤压小金川河,迫使河水冲刷掏蚀对岸阿娘寨古滑坡坡脚,引发红梁木包包和烂水湾两处次级滑坡。古滑坡因之局部失稳复活,约6.6×106 m3坡体变形剧烈,坡体整体下挫,表面拉裂缝发育,强变形区边缘裂隙已经贯通,整体处于不稳定状态。分析表明,丹巴县梅龙沟灾害具有典型的灾害链生效应,严重危及上下游。现场监测表明,阿娘寨古滑坡整体滑动可能性大,如失稳后可能形成大规模堰塞湖,危险性极高,应提前防护应对。
Abstract:
On June 17, 2020, a rainstorm-triggering geohazard chain occurred near the Meilong catchment of Banshanmen town, Danba county, Sichuan province, China, which cascaded down consecutively in an order of debris flow, landslide, dammed lake and outburst flood. Upstream channel flow which produced by rainstorm of three hours strongly eroded sediment and loose material on the channel banks of the Meilong valley and transformed into sub-viscous debris flow. Total discharging volume in this debris flow event is up to 2.4×105 m3, and ca. 1.3×105 m3 of sediment rushed into the Xiaojinchuan river and blocked it temporarily. As a consequent of the river channel narrowing, the river flood scoured the foot of ancient landslide deposit of Aniangzhai on the opposite bank. The scouring induced two new landslides, the Hongliangmubaobao landslide and the Lanshuiwan landslides at the toe of the ancient landslide site. The two landslides eventually led to the revival of the Aniangzhai landslide. About 6.6×106 m3 of the ancient landslide deposits deformed strongly and fell integrally. Surface cracks developed on the severe deformation area have penetrated, and the ancient landslide is in an unstable state. The 6.17 Meilong disasters is a typical multi-hazard chain, which seriously and extensively endangered the upstream and downstream areas. On-site monitoring indicated that the overall sliding possibility of the ancient landslide is high, and a large-scale dammed lake may be formed if the Aniangzhai landslide fails. The risk of the ancient landslide's failure is extremely high, and effective countermeasures should be prepared in advance.

参考文献/References:

[1] 刘翠容.泥石流堵塞大河判据及沿河线减灾对策[D].成都:西南交通大学,2014:1-30.[LIU Cuirong. Criteria of blocking large river by debris flow and disaster reduction countermeasures in highways along rivers[D]. Chengdu: Southwest Jiaotong University, 2014:1-30]
[2] 谢洪,钟敦伦,李泳,等.长江上游泥石流灾害的特征[J].长江流域资源与环境,2004,13(1):94-99. [XIE Hong, ZHONG Dunlun, LI Yong, et al. Features of debris flows in the upper reaches of the Changjiang river[J]. Resource and Environment in the Yangtze Basin, 2004, 13(1): 94-99]
[3] 张金山,沈兴菊,谢洪.泥石流堵河影响因素研究——以岷江上游为例[J]. 灾害学,2007,22(2):82-86. [ZHANG Jinshan, SHEN Xingju, XIE Hong. Study on factors affecting the river-blocking due to debris flow in the upper reaches of Minjiang river[J]. Journal of Catastrophology, 2007, 22(2): 82-86]
[4] 程尊兰,吴积善.西藏东南部培龙沟泥石流堵塞坝的形成机理[C]//第八届海峡两岸山地灾害与环境保育学术研讨会.乌鲁木齐,2011:39-45.[CHENG Zunlan, WU Jishan. Formation of dam from debris flow in the southeast Tibet[C]// Researches on Mountain Disaster and Environmental Protection across Taiwan Strait. Urumqi, 2011: 39-45]
[5] 童立强,涂杰楠,裴丽鑫,等.雅鲁藏布江加拉白垒峰色东普流域频繁发生碎屑流事件初步探讨[J].工程地质学报,2018,26(6):1552-1561. [TONG Liqiang, TU Jienan, PEI Lixin, et al. Preliminary discussion of the frequently debris flow events in Sedongpu basin at Gyalaperi peak, Yarlung Zangbo river[J]. Journal of Engineering Geology, 2018, 26(6): 1552-1561]
[6] HU Kaiheng, ZHANG Xiaopeng, YOU Yong, et al. Landslides and dammed lakes triggered by the 2017 Ms6.9 Milin earthquake in the Tsangpo gorge[J]. Landslides, 2019, 16(5), 993-1001.
[7] 史培军.五论灾害系统研究的理论与实践[J].自然灾害学报,2009, 18(5):1-9.[SHI Peijun. Theory and practice on disaster system research in a fifth time[J]. Journal of Natural Disaster, 2009, 18(5): 1-9]
[8] MENONI S. Chains of damages and failures in a metropolitan environment: some observations on the Kobe earthquake in 1995[J]. Journal of Hazardous Materials, 2001, 86(1/3): 101-119.
[9] CARPIGNANO A, GOLIA E, MAURO C D, et al. A methodological approach for the definition of multi-risk maps at regional level: first application[J]. Journal of Risk Research, 2009, 12(3/4):513-534.
[10] KAPPES M S, KEILER M, ELVERFELDT K V, et al. Challenges of analyzing multi-hazard risk: a review[J]. Natural Hazards, 2012, 64(2):1925-1958.
[11] HELBING D. Globally networked risks and how to respond[J]. Nature, 2013, 497(7447): 51-59.
[12] 刘爱华,吴超. 基于复杂网络的灾害链风险评估方法的研究[J]. 系统工程理论与实践,2015,35(2):466-472.[LIU Aihua, WU Chao. Research on risk assessment method of disaster chain based on complex network[J]. Systems Engineering —Theory & Practice, 2015, 35(2): 466-472]
[13] 王静爱, 雷永登,周洪建,等.中国东南沿海台风灾害链区域规律与适应对策研究[J].北京师范大学学报:社会科学版,2012,1(2):130-138. [WANG Jing'ai, LEI Yongdeng, ZHOU Hongjian, et al. Regional features and adaptation countermeasures of typhoon disaster chains in southeast coastal regions of China[J]. Journal of Beijing Normal University(Social Science), 2012, 1(2): 130-138]
[14] 王静爱.区域灾害系统与台风灾害链风险防范模式[M]. 北京:中国环境科学出版社,2013:1-50.[WANG Jing'ai. Regional disaster system and typhoon disaster chain risk prevention model. Beijing: China Environmental Science Press, 2013:1-50]
[15] KAPPES M S, GLADE T.(2013)Landslides in a multi-hazard context[C]//MARGOTTINI C., CANUTI P., SASSA K.(eds)Landslide Science and Practice. Berlin, Heidelberg: Springer,2013:83-90.
[16] LIU Wei, HE Siming. Dynamic simulation of a mountain disaster chain: landslides, barrier lakes, and outburst floods [J]. Natural hazards, 2018, 90(2):757-775.
[17] HU Kaiheng, ZHANG Xiaopeng, TANG Jinbo, et al. 9 Milin earthquake in the Tsangpo gorge[C]// Debris Flows: Disasters, Risk, Forecast, Protection, Proceedings of the 5th International Conference, Tbilisi, Georgia, 1-5 October. Tbilisi, 2018: 97-104.
[18] HU Xudong, HU Kaiheng, TANG Jinbo, et al. Assessment of debris-flow potential dangers in the Jiuzhaigou Valley following the August 8, 2017, Jiuzhaigou earthquake, western China [J]. Engineering Geology, 2019, 256, 57-66.
[19] FAN Xuanmei, SCARINGI G, KORUP O, et al. Earthquake-induced chains of geologic hazards: patterns, mechanisms, and impacts[J]. Reviews of Geophysics, 2019, 57(2): 421-503.
[20] 李明辉,郑万模,陈启国.丹巴县地质灾害发育特征及成因探讨[J].自然灾害学报,2008,17(1):49-53. [LI Minghui, ZHENG Wanmo, CHEN Qiguo. Development characteristic of geological hazard in Danba county and its cause discussion[J]. Journal of Natural Disasters, 2008, 17(1): 49-53]
[21] COSTA J E, SCHUSTER R L. The formation and failure of natural dams[J]. Geological Society of America Bulletin, 1988, 100(7):1054-1068.
[22] FAN Xuanmei, DUFRESNE A, SUBRAMANIAN S S, et al. The formation and impact of landslide dams-State of the art[J]. Earth-Science Reviews, 2020, 203: 103116.
[23] PENNA I M, DERRON M H, VOLPI M, et al. Analysis of past and future dam formation and failure in the Santa Cruz River(San Juan province, Argentina)[J]. Geomorphology, 2013, 186: 28-38.

相似文献/References:

[1]蒋志林,朱静,常鸣,等.汶川地震区红椿沟泥石流形成物源量动态演化特征[J].山地学报,2014,(01):81.
 JIANG Zhilin,ZHU Jing,CHANG Ming,et al.Dynamic Evolution Characteristics of Hongchun Gully Source Area of Debris Flow in Wenchuan Earthquake Region[J].Mountain Research,2014,(6):81.
[2]常鸣,唐川,蒋志林,等.强震区都江堰市龙池镇泥石流物源的遥感动态演变[J].山地学报,2014,(01):89.
 CHANG Ming,TANG Chuan,JIANG Zhilin,et al.Dynamic Evolution Process of Sediment Supply for Debris Flow Occurrence in Longchi of Dujiangyan,Wenchuan Earthquake Area[J].Mountain Research,2014,(6):89.
[3]王 钧,欧国强,杨 顺,等.地貌信息熵在地震后泥石流危险性评价中的应用[J].山地学报,2013,(01):83.
 WANG Jun,OU Guoqiang,YANG Shun,et al.Applicability of Geomorphic Information Entropy in the Postearthquake Debris Flow Risk Assessment[J].Mountain Research,2013,(6):83.
[4]王东坡,何思明,葛胜锦,等.“9?07”彝良地震诱发次生山地灾害调查及减灾建议[J].山地学报,2013,(01):101.
 WANG Dongpo,HE Siming,GE Shengjin,et al.Mountain Hazards Induced by the Earthquake of Sep 07,2012 in Yiliang and the Suggestions of Disaster Reduction[J].Mountain Research,2013,(6):101.
[5]喻 武,万 丹,汪书丽,等.藏东南泥石流沉积区植物群落结构和物种多样性特征[J].山地学报,2013,(01):120.
 YU Wu,WAN Dan,WANG Shuli,et al.Community Structure and Species Diversity of Debris Flow Deposition Area in Southeast of Tibet,China[J].Mountain Research,2013,(6):120.
[6]崔鹏,陈晓清,张建强,等.“4·20”芦山7.0级地震次生山地灾害活动特征与趋势[J].山地学报,2013,(03):257.
 CUI Peng,CHEN Xiaoqing,ZHANG Jianqiang,et al.Activities and Tendency of Mountain Hazards Induced by the Ms7.0 Lushan Earthquake,April 20,2013[J].Mountain Research,2013,(6):257.
[7]邹强,崔鹏,杨伟,等.G318川藏公路段泥石流危险性评价[J].山地学报,2013,(03):342.
 ZOU Qiang,CUI Peng,YANG Wei.Hazard Assessment of Debris Flows along G318 Sichuan-Tibet Highway[J].Mountain Research,2013,(6):342.
[8]王根龙,张茂省,于国强,等.舟曲2010年“8·8”特大泥石流灾害致灾因素[J].山地学报,2013,(03):349.
 WANG Genlong,ZHANG Maosheng,YU Guoqiang,et al.Factor Analysis for Catastrophic Debris Flows on August 8,2010 in Zhouqu City of Gansu,China[J].Mountain Research,2013,(6):349.
[9]陈源井,余斌,朱渊,等.地震后泥石流临界雨量变化特征——以汶川地震区小岗剑沟为例[J].山地学报,2013,(03):356.
 CHEN Yuanjing,YU Bin,ZHU Yuan,et al.Characteristics of Critical Rainfall of Debris Flow after Earthquake——A Case Study of the Xiaogangjian Gully[J].Mountain Research,2013,(6):356.
[10]游勇,柳金峰,陈兴长,等.芦山“4·20”地震后宝兴县城打水沟泥石流发育趋势及防治方案[J].山地学报,2013,(04):495.
 YOU Yong,LIU Jinfeng,CHEN Xingzhang.The Potential Tendency and Mitigation Measures of Dashui Gully in Baoxing Coutny after Lushan“4?20”Earthquake of Schuan[J].Mountain Research,2013,(6):495.

备注/Memo

备注/Memo:
收稿日期(Received date):2020-07-02; 改回日期(Accepted date): 2020-07-15
基金项目(Foundation item):中国国家铁路集团有限公司科技研究开发计划课题(K2019G006); 国家自然科学基金项目(41790434,91747207)。[Project of Science and Technology Research and Development Program of China National Railway Group(K2019G006); National Natural Science Foundation of China(41790434, 91747207)]
作者简介(Biography):胡凯衡(1975-),男,博士,研究员,主要研究方向:泥石流减灾理论与技术。[HU Kaiheng(1975-), male, professor, research on debris flow mechanism and mitigation] E-mail:khhu@imde.ac.cn
更新日期/Last Update: 2020-11-30