Precursors and Motion Characteristics of the 1965 Lannigou Rockslides and the Subsequent Evolution

WEN Baoping; WANG Fan

doi:10.16030/j.cnki.issn.1000-3665.202108065

2021 Vol. 48, No. 6

Article Contents

Article navigation > Hydrogeology & Engineering Geology > 2021 > 48(6): 72-80

Next Article Previous Article

WEN Baoping, WANG Fan. Precursors and Motion Characteristics of the 1965 Lannigou Rockslides and the Subsequent Evolution[J]. Hydrogeology & Engineering Geology, 2021, 48(6): 72-80. doi: 10.16030/j.cnki.issn.1000-3665.202108065

Citation:

WEN Baoping, WANG Fan. Precursors and Motion Characteristics of the 1965 Lannigou Rockslides and the Subsequent Evolution[J]. Hydrogeology & Engineering Geology, 2021, 48(6): 72-80. doi: 10.16030/j.cnki.issn.1000-3665.202108065

Precursors and Motion Characteristics of the 1965 Lannigou Rockslides and the Subsequent Evolution

WEN Baoping^1,,
WANG Fan^1,2

1.
School of Water Resources and Environment, China University of Geosciences (Beijing), Beijing　100083, China
2.
Xi’an Center of Mineral Resources Investigation of China Geological Survey, Xi’an, Shaanxi　710100, China

Received Date: 20 August 2021

Revised Date: 20 September 2021

Publish Date: 15 November 2021

Abstract

Abstract

The Lannigou rockslide is one of the most well-known giant and rapid rockslides with long runout in China. The 1965 Lannigou rockslides caused the most catastrophic consequence in China since 1920’s, and were followed by two more rockslides in 1991 and 2007, respectively. However, it remains unclear that how precursors of the 1965 rockslides were and relationship between the two movement sequences was, so did the following activities in 1991 and 2007. Those unclear questions were explored in this paper based on 23 remote sensing satellite images taken during the period between 1965 and 2020 and the UAV image taken in 2019 as well as field survey then. It is found that: 1) tension cracks could be seen on the northern slope of the source area before the 1965 rockslides, evidencing the precursors there, 2) the 1965 rockslide first occurred on the northern slope, and subsequently induced the rockslide on the southern slope next day resulted from its strong impact, 3) rapid granular flows of the two rockslides jumped and flew over the northern slope of the transition zone, and scrapped, entrained surficial layer there, 4) the granular flow did not reach the Jingsha River, but ended ca. 2.8 km east of the intersection between the Lannigou and the Pufu river; 5) the source area of the 1991 rockslide just neighbored the northwestern boundary of the 1965 rockslide on the northern slope, while the 2007 rockslide neighbored the upper boundary of the 1991 rockslide, and 6) the detached volumes and runouts of the 1965, 1991 and 2007 rockslides showed a decrease order. Recently, tension cracks can be clearly seen on both the northwestern and southwestern slopes. One of tension cracks on the northwestern slope is extending with a rate of 16.7 m/a, while those on the southwestern slope has shown no sign of extension since 2014, indicating that the northwestern slope may fail again. It is thus that an attention should be paid to the northwestern slope via monitoring its deformation and keeping local people away from the area likely affected.
- rapid rockslide with long runout /
- remote sensing satellite imaginary /
- precursor /
- relationship between movement sequences /
- motion characteristics /
- evolution trend

FullText(HTML)

References

[1]	施雅风, 唐邦兴, 徐兵, 等. 云南省禄劝县普福河烂泥沟特大崩塌型滑坡调查研究[C]//首届全国泥石流滑坡防治学术会议论文集. 昆明: 云南科学技术出版社, 1993: 188−194. Google Scholar SHI Yafeng, TANG Bangxing, XU Bing, et al. Survey of the Lannigou rock avalanche of the Pufu river, Luquan County of Yunnan province[C]// Proceedings of first symposium on landslides and debris flows. Kunming: Scientific and Technology Press of Yunnan, 1993: 188−194. (in Chinese) Google Scholar
[2]	程先锋, 祝传兵, 齐武福, 等. 云南省禄劝县普福滑坡形成条件、发展趋势与防治对策[J]. 矿产与地质,2015,29(3):395 − 401. [CHENG Xianfeng, ZHU Chuanbing, QI Wufu, et al. Formation conditions, development tendency and preventive measures of Pufu landslide in Luquan of Yunnan[J]. Mineral Resources and Geology,2015,29(3):395 − 401. (in Chinese with English abstract) doi: 10.3969/j.issn.1001-5663.2015.03.021 CrossRef Google Scholar
[3]	徐则民. 云南禄劝县烂泥沟滑坡[C]//中国典型灾难性滑坡. 北京: 科学出版社, 2008. Google Scholar XU Zemin. The Lannigou landslide in Luquan of Yunnan [C]//Catastrophic Landslides in China. Beijing: Science Press, 2008. (in Chinese) Google Scholar
[4]	BRÜCKL E, BRUNNER F K, KRAUS K. Kinematics of a deep-seated landslide derived from photogrammetric, GPS and geophysical data[J]. Engineering Geology,2006,88(3/4):149 − 159. Google Scholar
[5]	DELACOURT C, ALLEMAND P, CASSON B, et al. Velocity field of the "La Clapière" landslide measured by the correlation of aerial and QuickBird satellite images[J]. Geophysical Research Letters,2004,31(15):L15619. doi: 10.1029/2004GL020193 CrossRef Google Scholar
[6]	蒋树, 文宝萍, 黎志恒, 等. 甘肃舟曲锁儿头滑坡活动特征分析[J]. 水文地质工程地质,2016,43(2):69 − 74. [JIANG Shu, WEN Baoping, LI Zhiheng, et al. An analysis of the activity features of the Suoertou landslide in Zhouqu County of Gansu[J]. Hydrogeology & Engineering Geology,2016,43(2):69 − 74. (in Chinese with English abstract) Google Scholar
[7]	JIANG S, WEN B P, ZHAO C, et al. Kinematics of a giant slow-moving landslide in Northwest China: Constraints from high resolution remote sensing imagery and GPS monitoring[J]. Journal of Asian Earth Sciences,2016,123:34 − 46. doi: 10.1016/j.jseaes.2016.03.019 CrossRef Google Scholar
[8]	STROM A, LI L, LAN H. Rock avalanche mobility: optimal characterization and the effects of confinement[J]. Landslides,2019,16(8):1437 − 1452. doi: 10.1007/s10346-019-01181-z CrossRef Google Scholar