|本期目录/Table of Contents|

[1]王伟卓,赵超英*,刘晓杰,等.澜沧江德钦段地质灾害隐患InSAR识别与形变监测[J].地球科学与环境学报,2024,46(04):557-568.[doi:10.19814/j.jese.2023.12042]
 WANG Wei-zhuo,ZHAO Chao-ying*,LIU Xiao-jie,et al.Identification and Deformation Monitoring of PotentialGeotechnical Hazards in the Deqin Section of the Lancang River, China[J].Journal of Earth Sciences and Environment,2024,46(04):557-568.[doi:10.19814/j.jese.2023.12042]
点击复制

澜沧江德钦段地质灾害隐患InSAR识别与形变监测(PDF)
分享到:

《地球科学与环境学报》[ISSN:1672-6561/CN:61-1423/P]

卷:
第46卷
期数:
2024年第04期
页码:
557-568
栏目:
大地测量、遥感与地学大数据
出版日期:
2024-07-15

文章信息/Info

Title:
Identification and Deformation Monitoring of PotentialGeotechnical Hazards in the Deqin Section of the Lancang River, China
文章编号:
1672-6561(2024)04-0557-12
作者:
王伟卓1赵超英123*刘晓杰4陈立权1魏玉明4
(1. 长安大学 地质工程与测绘学院,陕西 西安 710054; 2. 长安大学 西部矿产资源与地质工程教育部重点实验室,陕西 西安 710054; 3. 长安大学 自然资源部生态地质与灾害防控重点实验室,陕西 西安 710054; 4. 兰州理工大学 土木工程学院,甘肃 兰州 730050)
Author(s):
WANG Wei-zhuo1 ZHAO Chao-ying123* LIU Xiao-jie4 CHEN Li-quan1 WEI Yu-ming4
(1. School of Geological Engineering and Geomatics, Chang'an University, Xi'an 710054, Shaanxi, China; 2. Key Laboratory of Western China's Mineral Resources and Geological Engineering of Ministry of Education,Chang'an University,Xi'an 710054, Shaanxi, China; 3. Key Laboratoryof Ecological Geology and Disaster Prevention ofMinistry of Natural Resources,Chang'an University, Xi'an 710054, Shaanxi, China; 4. School of Civil Engineering, Lanzhou University of Technology, Lanzhou 730050, Gansu, China)
关键词:
InSAR技术 石冰川 地质灾害 形变监测 奇异谱分析 澜沧江
Keywords:
InSAR technolgy rock glacier geohazard deformation monitoring singular spectrum analysis Lancang River
分类号:
P237
DOI:
10.19814/j.jese.2023.12042
文献标志码:
A
摘要:
青藏高原东南缘地形起伏大,构造运动活跃,发育着冰川和冻土,地质灾害种类多且发生频繁。为研究该地区地质灾害的分布特征和运动规律,选取澜沧江德钦段作为研究区,基于一个轨道的ALOS-2卫星和3个轨道的Sentinel-1A卫星数据,利用Stacking-InSAR和DS-InSAR技术分别进行了研究区大范围地质灾害调查和典型泥石流物源区的时间序列监测,并采用奇异谱分析(SSA)提取了形变的周期项特征。结果表明:研究区内共存在670个形变区域,石冰川占大部分,位于海拔较高的山顶,距澜沧江5 km的范围内有27个滑坡; 选取的典型泥石流物源区2017~2022年形变时间序列呈线性趋势,其中石冰川周期项形变与降水量和气温存在相关性。
Abstract:
The southeastern Qinghai-Xizang Plateau has significant topographical variations, active tectonic movements and developed glaciers and permafrost. A variety of geotechnical disasters occur frequently in this region. In order to study the distribution characteristics and movement patterns of geotechnical hazards in this region,theDeqin section ofthe Lancang River was selected as the research area. Based on thedata formALOS-2satellite of one track and Sentinel-1Asatelliteof three tracks,large-scale geotechnical hazards investigation in the study area were conducted using Stacking-InSAR technology, whiletime-seriesmonitoring of typical debris flow source areas was carried out using DS-InSAR technology. Singular spectrum analysis(SSA)was employed to extract the periodic characteristics of deformation. The results show that there are a total of 670 deformation areas in the study area, most of which are rock glaciers located on the mountain tops of high elevations, and 27 landslides are distributed within a 5 km-distance from theLancang River; the deformation time series of the selected typical debris flow source area from 2017 to 2022 shows a linear trend; both precipitation and temperature are correlated with the periodic deformation of the rock glacier from this source area.

参考文献/References:

[1] 彭建兵,马润勇,卢全中,等.青藏高原隆升的地质灾害效应[J].地球科学进展,2004,19(3):457-466.
PENG Jian-bing,MA Run-yong,LU Quan-zhong,et al.Geological Hazards Effects of Uplift of Qinghai-Tibet Plateau[J].Advance in Earth Sciences,2004,19(3):457-466.
[2]李朝月,崔 鹏,郝建盛,等.1960年以来藏东南地区气温和降水的变化特征[J].高原气象,2023,42(2):344-358.
LI Chao-yue,CUI Peng,HAO Jian-sheng,et al.Variation Characteristics of Temperature and Precipitation over the Southeast Xizang Since 1960[J].Plateau Meteorology,2023,42(2):344-358.
[3]崔 鹏,郭晓军,姜天海,等.“亚洲水塔”变化的灾害效应与减灾对策[J].中国科学院院刊,2019,34(11):1313-1321.
CUI Peng,GUO Xiao-jun,JIANG Tian-hai,et al.Disaster Effect Induced by Asian Water Tower Change and Mitigation Strategies[J].Bulletin of Chinese Academy of Sciences,2019,34(11):1313-1321.
[4]李媛茜,张 毅,苏晓军,等.白龙江流域潜在滑坡InSAR识别与发育特征研究[J].遥感学报,2021,25(2):677-690.
LI Yuan-xi,ZHANG Yi,SU Xiao-jun,et al.Early Identification and Characteristics of Potential Landslides in the Bailong River Basin Using InSAR Technique[J].NationalRemote SensingBulletin,2021,25(2):677-690.
[5]刘星洪,姚 鑫,杨 波,等.川西高原活动性滑坡识别与空间分布特征研究[J].地质力学学报,2023,29(1):111-126.
LIU Xing-hong,YAO Xin,YANG Bo,et al.InSAR-based Identification and Spatial Distribution Analysis of Active Landslides in the Western Sichuan Plateau[J].Journal of Geomechanics,2023,29(1):111-126.
[6]LIU X J,ZHAO C Y,ZHANG Q,et al.Integration of Sentinel-1 and ALOS/PALSAR-2 SAR Datasets for Mapping Active Landslides Along the Jinsha River Corridor,China[J].Engineering Geology,2021,284:106033.
[7]戴可人,吴明堂,卓冠晨,等.西南山区大型水电工程库岸滑坡InSAR早期识别与监测研究进展[J].地球科学与环境学报,2023,45(3):559-577.
DAI Ke-ren,WU Ming-tang,ZHUO Guan-chen,et al.Review on InSAR Early Identification and Monitoring of Reservoir Landslides for Large Hydropower Engineering Projects in Southwest Mountainous Area of China[J].Journal of Earth Sciences and Environment,2023,45(3):559-577.
[8]WANG B H,ZHAO C Y,ZHANG Q,et al.Sequential DS-ISBAS InSAR Deformation Parameter Dynamic Estimation and Quality Evaluation[J].Remote Sensing,2023,15(8):2097.
[9]LI B,ZHAO C Y,LI J,et al.Mechanism of Mining-induced Landslides in the Karst Mountains of Southwestern China:A Case Study of the Baiyan Landslide in Guizhou[J].Landslides,2023,20(7):1481-1495.
[10]杨成生,李晓阳,张 勤,等.基于InSAR技术的尼泊尔辛杜帕尔乔克区震后滑坡监测与分析[J].武汉大学学报(信息科学版),2023,48(10):1684-1696.
YANG Cheng-sheng,LI Xiao-yang,ZHANG Qin,et al.Monitoring and Analysis of Post-earthquake Landslide in Sindhupalchowk District,Nepal Based on InSAR Technology[J].Geomatics and Information Science of Wuhan University,2023,48(10):1684-1696.
[11]盛 磊,张 露,杜玉玲,等.基于DS-InSAR技术的金沙江流域贡觉地区滑坡与地裂缝形变特征[J].地球科学与环境学报,2022,44(5):814-825.
SHENG Lei,ZHANG Lu,DU Yu-ling,et al.Characteristics of Deformation of Landslide and Ground Fissure in Gongjue Area of Jinsha River Basin,China Based on DS-InSAR Technology[J].Journal of Earth Sciences and Environment,2022,44(5):814-825.
[12]徐晓雪,季灵运,张文婷,等.基于相干性的InSAR时间序列方法追溯四川雅安地区汉源滑坡灾前形变[J].地球科学与环境学报,2022,44(4):632-640.
XU Xiao-xue,JI Ling-yun,ZHANG Wen-ting,et al.Pre-failure Displacements of Hanyuan Landslide in Ya'an Area of Sichuan,China Traced by a Coherence-based InSAR Time Series Method[J].Journal of Earth Sciences and Environment,2022,44(4):632-640.
[13]姚 鑫,邓建辉,刘星洪,等.青藏高原泛三江并流区活动性滑坡InSAR初步识别与发育规律分析[J].工程科学与技术,2020,52(5):16-37.
YAO Xin,DENG Jian-hui,LIU Xing-hong,et al.Primary Recognition of Active Landslides and Development Rule Analysis for Pan Three-river-parallel Territory of Tibet Plateau[J].Advanced Engineering Sciences,2020,52(5):16-37.
[14]刘晓杰.星载雷达遥感广域滑坡早期识别与监测预测关键技术研究[D].西安:长安大学,2022.
LIU Xiao-jie.Research on Key Technologies for Early Identification,Monitoring and Forecasting of Wide-area Landslides with Spaceborne Radar Remote Sensing[D].Xi'an:Chang'an University,2022.
[15]崔 鹏,陈 容,向灵芝,等.气候变暖背景下青藏高原山地灾害及其风险分析[J].气候变化研究进展,2014,10(2):103-109.
CUI Peng,CHEN Rong,XIANG Ling-zhi,et al.Risk Analysis of Mountain Hazards in Tibetan Plateau Under Global Warming[J].Progressus Inquisitiones de Mutatione Climatis,2014,10(2):103-109.
[16]杨彦敏,杨玮琳,肖 菁,等.青藏高原东南缘折多山石冰川的形成年代及发育特征[J].冰川冻土,2024,https:∥link.cnki.net/urlid/62.1072.P.20231228.1659.002.
YANG Yan-min,YANG Wei-lin,XIAO Jing,et al.Formation Age and Development Characteristics of Rock Glaciers in the Zheduo Mountain,Hengduan Mountains,on the Southeastern Qinghai-Xizang(Tibet)Plateau[J].Journal of Glaciology and Geocryology,2024,https:∥link.cnki.net/urlid/62.1072.P.20231228.1659.002.
[17]RAN Z Z,LIU G N.Rock Glaciers in Daxue Shan,South-Eastern Tibetan Plateau:An Inventory,Their Distribution,and Their Environmental Controls[J].The Cryosphere,2018,12(7):2327-2340.
[18]KANG Y,LU Z,ZHAO C Y,et al.InSAR Monitoring of Creeping Landslides in Mountainous Regions:A Case Study in Eldorado National Forest,California[J].Remote Sensing of Environment,2021,258:112400.
[19]RAN Y H,LI X,CHENG G D,et al.New High-resolution Estimates of the Permafrost Thermal State and Hydrothermal Conditions over the Northern Hemisphere[J].Earth System Science Data,2022,14(2):865-884.
[20]BEKAERT D P S,WALTERS R J,WRIGHT T J,et al.Statistical Comparison of InSAR Tropospheric Correction Techniques[J].Remote Sensing of Environment,2015,170:40-47.
[21]SANDWELL D T,PRICE E J.Phase Gradient Approach to Stacking Interferograms[J].Journal of Geophysical Research:Solid Earth,1998,103(B12):30183-30204.
[22]张成龙,李振洪,余 琛,等.利用GACOS辅助下InSAR Stacking对金沙江流域进行滑坡监测[J].武汉大学学报(信息科学版),2021,46(11):1649-1657.
ZHANG Cheng-long,LI Zhen-hong,YU Chen,et al.Landslide Detection of the Jinsha River Region Using GACOS Assisted InSAR Stacking[J].Geomatics and Information Science of Wuhan University,2021,46(11):1649-1657.
[23]蒋 弥,丁晓利,李志伟.时序InSAR同质样本选取算法研究[J].地球物理学报,2018,61(12):4767-4776.
JIANG Mi,DING Xiao-li,LI Zhi-wei.Homogeneous Pixel Selection Algorithm for Multitemporal InSAR[J].Chinese Journal of Geophysics,2018,61(12):4767-4776.
[24]戴可人,张乐乐,宋 闯,等.青藏高原交通廊道沿线Sentinel-1影像几何畸变与升降轨适宜性定量分析[J].武汉大学学报(信息科学版),2021,46(10):1450-1460.
DAI Ke-ren,ZHANG Le-le,SONG Chuang,et al.Quantitative Analysis of Sentinel-1 Imagery Geome-tric Distortion and Their Suitability Along Qinghai Tibet Plateau Traffic Corridor[J].Geomatics and Information Science of Wuhan University,2021,46(10):1450-1460.
[25]崔 鹏,郭 剑.沟谷灾害链演化模式与风险防控对策[J].工程科学与技术,2021,53(3):5-18.
CUI Peng,GUO Jian.Evolution Models,Risk Prevention and Control Countermeasures of the Valley Disaster Chain[J].Advanced Engineering Sciences,2021,53(3):5-18.
[26]魏云杰,王 猛,王俊豪,等.澜沧江德钦段地质灾害精细调查方法研究[M].北京:科学出版社,2022.
WEI Yun-jie,WANG Meng,WANG Jun-hao,et al.A Study on Detailed Geohazard Investigation in the Deqin Section of Lancang River[M].Beijing:Science Press,2022.
[27]崔之久,熊黑钢,刘耕年,等.中天山冰冻圈地貌过程与沉积特征[M].石家庄:河北科学技术出版社,1998.
CUI Zhi-jiu,XIONG Hei-gang,LIU Geng-nian,et al.Geomorphic Processes and Sedimentary Characteristics of the Middle Tianshan Cryosphere[M].Shijia-zhuang:Hebei Science & Technology Publishing House,1998.
[28]HASSAN J,CHEN X Q,MUHAMMAD S,et al.Rock Glacier Inventory,Permafrost Probability Distribution Modeling and Associated Hazards in the Hunza River Basin,Western Karakoram,Pakistan[J].Science of the Total Environment,2021,782:146833.
[29]KOFLER C,MAIR V,GRUBER S,et al.When Do Rock Glacier Fronts Fail?Insights from Two Case Studies in South Tyrol(Italian Alps)[J].Earth Surface Processes and Landforms,2021,46(7):1311-1327.
[30]KUMMERT M,DELALOYE R,BRAILLARD L.Erosion and Sediment Transfer Processes at the Front of Rapidly Moving Rock Glaciers:Systematic Observations with Automatic Cameras in the Western Swiss Alps[J].Permafrost and Periglacial Processes,2018,29(1):21-33.
[31]SEELIG S,WAGNER T,KRAINER K,et al.The Role of Thermokarst Evolution in Debris Flow Initiation[J].Natural Hazards and Earth System Sciences,2023,23(7):2547-2568.
[32]GOLYANDINA N,NEKRUTKIN V,ZHIGLJAVSKY A.Analysis of Time Series Structure:SSA and Related Techniques[M].Boca Raton:Chapman and Hall,2001.
[33]HUGGEL C,CAREY M,CLAGUE J J,et al.The High-mountain Cryosphere:Environmental Changes and Human Risks[M].Cambridge:Cambridge University Press,2015.

相似文献/References:

[1]张永红,刘冰,吴宏安,等.雄安新区2012~2016年地面沉降InSAR监测[J].地球科学与环境学报,2018,40(05):652.
 ZHANG Yong-hong,LIU Bing,WU Hong-an,et al.Ground Subsidence in Xiong’an New Area from 2012 to 2016 Monitored by InSAR Technique[J].Journal of Earth Sciences and Environment,2018,40(04):652.
[2]朱 武,杨璐瑶,张金敏,等.联合InSAR和质量守恒法估计西藏贡觉地区雄巴滑坡厚度[J].地球科学与环境学报,2023,45(03):535.[doi:10.19814/j.jese.2022.12081]
 ZHU Wu,YANG Lu-yao,ZHANG Jin-min,et al.Thickness Estimation of Xiongba Landslide in Gongjue Area of Tibet, China by Combining InSAR and Mass Conservation Method[J].Journal of Earth Sciences and Environment,2023,45(04):535.[doi:10.19814/j.jese.2022.12081]
[3]戴可人,吴明堂,卓冠晨,等.西南山区大型水电工程库岸滑坡InSAR早期识别与监测研究进展[J].地球科学与环境学报,2023,45(03):559.[doi:10.19814/j.jese.2022.12080]
 DAI Ke-ren,WU Ming-tang,ZHUO Guan-chen,et al.Review on InSAR Early Identification and Monitoring of Reservoir Landslides for Large Hydropower Engineering Projects in Southwest Mountainous Area of China[J].Journal of Earth Sciences and Environment,2023,45(04):559.[doi:10.19814/j.jese.2022.12080]

备注/Memo

备注/Memo:
收稿日期:2023-12-23; 修回日期:2024-04-06投稿网址:http:∥jese.chd.edu.cn/
基金项目:国家重点研发计划项目(2022YFC3004302)
*通信作者:赵超英(1976-),男,山西平遥人,教授,博士研究生导师,工学博士,E-mail:cyzhao@chd.edu.cn。
更新日期/Last Update: 2024-08-20