[1]姚维益,常鸣,李为乐.都江堰龙溪河流域典型泥石流物源演化特征遥感监测[J].水土保持研究,2018,25(03):205-209.
 YAO Weiyi,CHANG Ming,LI Weile.Dynamic Evolution Characteristics of Material of Typical Debris Flow Using Remote Sensing Technology, in Lonngxi Catchment, Dujiangyan, China[J].Research of Soil and Water Conservation,2018,25(03):205-209.
点击复制

都江堰龙溪河流域典型泥石流物源演化特征遥感监测

《水土保持研究》[ISSN:1005-3409/CN:61-1272/P] 卷: 25 期数: 2018年03期 页码: 205-209 栏目: 出版日期: 2018-04-10
Title:
Dynamic Evolution Characteristics of Material of Typical Debris Flow Using Remote Sensing Technology, in Lonngxi Catchment, Dujiangyan, China
作者:
姚维益1,2, 常鸣3, 李为乐3
1. 成都理工大学 地球物理学院, 成都 610059;
2. 都江堰市国土资源局, 四川 都江堰 611830;
3. 成都理工大学 地质灾害防治与地质环境保护国家重点实验室, 成都 610059
Author(s):
YAO Weiyi1,2, CHANG Ming3, LI Weile3
1. School of Geophysics, Chengdu University of Technology, Chengdu 610059, China;
2. Dujiangyan Bureau of land and resources, Dujiangyan, Sichuan 611800, China;
3. State Key Laboratory of GeoHazard Prevention and GeoEnvironment Protection, Chengdu University of Technology, Chengdu 610059, China
关键词:
汶川地震泥石流滑坡动态演变遥感监测
Keywords:
Wenchuan Earthquakedebris flowlandslidesdynamic evolutionremote sensing monitoring
分类号:
P642.4;P642.5
摘要:
2008年"5·12"汶川地震致使都江堰龙溪河流域产生了大量的碎屑体,为震后暴雨泥石流的发生提供了丰富的固体物源物质。2010年8月14日,都江堰龙溪河流域暴发大型泥石流,堵塞龙溪河致使河水改道,威胁城镇居民的生命财产安全。为研究泥石流物源的演变特征,选取5条泥石流及覆盖其范围的5期高精度影像,结合野外详细调查,通过ArcGIS空间分析发现,地震前这些泥石流流域内植被良好,未发现大规模的地质灾害,均属于清水沟。汶川地震后崩塌滑坡体的面积由震前的0.10万m2增加到地震后的41.28万m2,崩塌滑坡个数由震前的1个增加到汶川地震后的283个。2010年"8·13"泥石流后,受降雨地表径流的冲刷侵蚀作用影响,部分崩塌滑坡扩大及新产生,经统计研究区泥石流流域内扩大及新增滑坡个数47处,崩塌滑坡体的面积在暴雨后与地震相比增加了8.29万m2,比例达16.72%。同时经过5期新增及扩大崩塌滑坡体增长率的统计,发现随着时间的推移其增长速度逐年降低,有力证明了震后研究区泥石流内崩塌滑坡体逐步稳定,生态环境得到有效恢复。
Abstract:
After ‘5·12’ Wenchuan Earthquake, the massive loose solid matters were produced in Longxi River, Dujiangyan, which provides the rich materials for debris flows. On 14th August, 2010, debris flows occurred in five valleys, which thrust in farmland and jammed the Longxi River diversions, threatened the old Longchi town.In order to research the dynamic evolution of source, we selected five debris flows as study examples and five high precision image covering the study areas, compared the evolution characters of the valleys by ArcGIS.The results indicated that:before ‘5·12’ earthquake, the study area cover was good, geologic hazards were not found, the basin stream all belonged to the clear ditch; after ‘5·12’ Earthquake,the number of landslide was 283 and the area was 41.28 hm2; after ‘8·13’ debris flow event, the number of landslide was 47 and the area was 8.29 hm2 due to rainfall, surface runoff scouer erosion, expansion and new generation of partial collapse and the landslide. After five periods of high resolution remote sensing interpretation of the landslides, the growth rates of landslides were declining year by year, the ecological environment gradually recovered.

参考文献/References:

[1] 余斌, 马煜, 张健楠,等.汶川地震后四川省都江堰市龙池镇群发泥石流灾害[J].山地学报,2011,29(6):738-746.
[2] 黄润秋,李为乐.汶川大地震触发地质灾害发育分布规律研究[J].岩石力学与工程学报,2008,27(12):119-128.
[3] 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.
[4] 梁京涛,唐川,王军,等.强震区小流域泥石流发育特征研究:以四川省绵竹市罗家沟泥石流为例[J].灾害学,2013,28(3):100-104.
[5] Tang C, Van Asch T W J, Chang M, et al. Catastrophic debris flows on 13 August 2010 in the Qingping area, southwestern China:The combined effects of a strong earthquake and subsequent rainstorms[J]. Geomorphology, 2012,139(2):559-576.
[6] Tang C, Zhu J, Chang M, et al. An empirical-statistical model for predicting debris-flow runout zones in the Wenchuan earthquake area[J]. Quaternary International, 2012, 250(250):63-73.
[7] Tang C, Zhu J, Ding J, et al. Catastrophic debris flows triggered by a 14 August 2010 rainfall at the epicenter of the Wenchuan earthquake[J]. Landslides, 2011,8(4):485-497.
[8] Tang C, Zhu J, Li W L, et al. Rainfall-triggered debris flows following the Wenchuan earthquake.[J]. Bulletin of Engineering Geology & the Environment, 2009, 68(2):187-194.
[9] 屈永平,唐川,刘洋,等.四川省都江堰市龙池地区"8·13"泥石流堆积扇调查和分析[J].水利学报,2015,46(2):197-207.
[10] 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, 32(1):89-97.
[11] 刘清华,唐川.都江堰市龙池镇"8·13"蜂桶岩泥石流灾害特征[J].成都理工大学学报,2012,39(6):636-642.
[12] Chang C W, Lin P S, Tsai C L. Estimation of sediment volume of debris flow caused by extreme rainfall in Taiwan[J]. Engineering Geology, 2011,123:83-90.
[13] Khattak G A, Owen L A, Kamp U, et al. Evolution of earthquake-triggered landslides in the Kashmir Himalaya, northern Pakistan[J]. Geomorphology, 2010,115:102-108.
[14] Lin W T, Lin C Y, Chou W C. Assessment of vegetation recovery and soil erosion at landslides caused by a catastrophic earthquake:A case study in Central Taiwan[J]. Ecological Engineering, 2006,28:79-89.

相似文献/References:

[1]王高峰,唐川,王洪德,等.初咱磨子沟泥石流特征及危险性评价研究[J].水土保持研究,2012,19(04):234.
 WANG Gao-feng,TANG Chuan,WANG Hong-de,et al.Characteristics and Hazard Assessment of Debris Flows in Chuzanmozigou Catchment[J].Research of Soil and Water Conservation,2012,19(03):234.
[2]田冰,王裕宜.基于功率谱分析的蒋家沟泥石流侵蚀输沙量准周期的探讨[J].水土保持研究,2012,19(04):244.
 TIAN Bing,WANG Yu-yi.Power Spectral Analysis on Periodicity of Sediment Transport in Debris Flow in Jiangjiagou Watershed[J].Research of Soil and Water Conservation,2012,19(03):244.
[3]胡桂胜,陈宁生,邓虎.基于GIS的西藏林芝地区泥石流易发与危险区分析[J].水土保持研究,2012,19(03):195.
 HU Gui-sheng,CHEN Ning-sheng,DENG Hu.Analysis of Debris Flow-prone and Dangerous Area in Nyingchi of Tibet Based on GIS[J].Research of Soil and Water Conservation,2012,19(03):195.
[4]李朝安,胡卸文,李冠奇,等.四川省“8·13”特大泥石流灾害成生机理与防治原则[J].水土保持研究,2012,19(02):257.
 LI Chao-an,HU Xie-wen,LI Guan-qi,et al.Formation Mechanism of the ’8·13’ Catastrophic Debris Flow in Sichuan and the Principles of Controlling[J].Research of Soil and Water Conservation,2012,19(03):257.
[5]张黎勇.皖南山区山体滑坡、泥石流的成因及其防治[J].水土保持研究,1997,4(01):171.
 Zhang Liyong.The Cause and Prevention of Slideslope, Debris Flow in the Hilly Areas of Southern Anhui Province[J].Research of Soil and Water Conservation,1997,4(03):171.
[6]李树德.中国滑坡、泥石流灾害的时空分布特点[J].水土保持研究,1999,6(04):33.
 Li Shude.The Temporal and Spacial Distribution of Landslide and Debris Flow Disasters in China[J].Research of Soil and Water Conservation,1999,6(03):33.
[7]吴正华.北京泥石流灾害及其降水触发条件[J].水土保持研究,2001,8(01):67.
 WU Zhenghua.The Mud-rock Flow Disaster and Their Touch off Condition by Rainfall in Beijing Area[J].Research of Soil and Water Conservation,2001,8(03):67.
[8]崔之久,冯金良.东川蒋家沟泥石流沉积亚相组合特征[J].水土保持研究,2001,8(02):2.
 CUI Zhi-jiu,FENG Jin-liang.Combination Features of Depositional Sub-facies of Debris-flowon the Jiangjiagou Valley, Yunnan Province[J].Research of Soil and Water Conservation,2001,8(03):2.
[9]冯金良,崔之久,李庆辰.太行山区下瓦岔泥石流灾害实录[J].水土保持研究,2001,8(02):41.
 FENG Jin-liang,CUI Zhi-jiu,LI Qing-chen.The Record of Xiawacha Debris-flow in Taihang Mountains[J].Research of Soil and Water Conservation,2001,8(03):41.
[10]李永化,张小咏,崔之久.陇南山地泥石流期、气候期与构造期的耦合[J].水土保持研究,2003,10(02):96.
 LI Yonghua,ZHANG Xiaoyong,CUI Zhijiu.Coupling of Debris Flow Period, Climate Period and Tectonic Period in the Mountainous Area of Longnan[J].Research of Soil and Water Conservation,2003,10(03):96.

备注/Memo

收稿日期:2017-05-15;改回日期:2017-08-22。
基金项目:四川省地理国情与资源环境承载力监测工程技术研究中心项目(GC201505);地质灾害防治与地质环境保护国家重点实验室自由探索课题(SKLGP2014Z004);成都理工大学中青年骨干教师培养计划(JXGG201507)
作者简介:姚维益(1981-),男,四川省阆中市人,工程师,在读博士,从事地质灾害监测预警研究工作。E-mial:93701403@qq.com
通讯作者:李为乐(1982-),男,安徽省安庆市人,副研究员,在读博士,从事地质灾害防治与地质环境保护科研和教学工作。E-mail:whylwl01@163.com

更新日期/Last Update: 1900-01-01