Abstract
The Aizigou paleolandslide is a large basalt landslide in the Liucheng section of the Lower Jinsha River, southwestern Sichuan Province, China. Geological investigation and interpretation of remote sensing imagery, in addition to experiments, numerical simulation, and geochronological dating were used to determine the formation and movement of the landslide. Four factors were critical: a substantial height difference between the landslide shearing surface and the foot of the slope; multiple structural defects within the rock mass; a tuff intercalation in the basaltic series with long-term softening due to surface water and groundwater; and seismic activity. The kinematic behavior of the landslide was simulated using a 3-D discrete element model (3DEC), with four stages: (1) Seismic waves in the upper part of the slope were amplified by the mountain topography. When the vibrational energy exceeded the strength of the rock mass, the landslide formed, with deformation and failure by sliding and fracture. (2) Landslide materials with a volume of approximately 3.82 × 108 m3 slid at high speed from a high position, before colliding with the mountainside on the right bank of Aizi Valley. (3) The high-speed debris flow then moved 3 km downstream in Aizi Valley. (4) Landslide materials with a volume of 2.72 × 108 m3 blocked Jinsha River. A lake formed behind the barrier dam; its backwater region reached 75 km upstream. Optically stimulated luminescence dating of the lake sediments suggested that the landslide occurred about 25,000 years ago.
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References
Bao L (2012) Analysis and discussion on the stability of Jinjiang landslide under the operating conditions of earthquake. Carsologica Sinica 31(1):87–93 (In Chinese)
Bedford A, Drumheller DS (1994) Introduction to elastic wave propagation. Int J Rock Mech Min Sci 31(3):141–142
Cho SH, Ogata Y, Kaneko K (2003) Strain rate dependency of the dynamic tensile strength of rock. Int J Rock Mech Min Sci 40(5):763–777
Costa JE, Schuster RL (1988) The formation and failure of natural dams. Geol Soc Am Bull 100(7):1054–1068
Fang J, Yin X, Zhou L, Yan F (2017) Comprehensive study on strength parameters of the tuff at Jinshajiang grand bridge site on Huali freeway. Chin J Appl Mech 34(3):507–513 (In Chinese)
Fourney WL (1993) Mechanisms of rock fragmentation by blasting. Compr Rock Eng 4:39–69
Han G, Zhao Q, Peng S (2011) In-situ stress field evolution of deep fracture rock mass at dam area of Baihetan hydropower station. Rock Soil Mech 32(Supp1):583–589 (In Chinese)
Hermanns RL, Hewitt K, Strom A et al (2010) The classification of rock slide dams. Lect Notes Earth Sci 133:581–593
Hu G (1995) Dynamic landslide. Geological Publishing House, Beijing (In Chinese)
Hu X, Huang R, Shi Y, Lv X, Zhu H, Wang X (2009) Analysis of blocking river mechanism of Tangjiashan landslide and dam-breaking mode of its barrier dam. Chin J Rock Mech Eng 28(1):181–189
Huang R, Tang C, Li Y et al (2009a) Geohazard assessment of the Wenchuan earthquake. Science and Technology Press, Beijing, pp 236–237 (In Chinese)
Huang Z, Tim Law K, Liu H, Jiang T (2009b) The chaotic characteristics of landslide evolution: a case study of Xintan landslide. Environ Geol 56(8):1585–1591
Huang D, Yang D, Li L et al (2010) Incision rates of the Baihetan section of the Jinsha river. Quat Sci 30(5):872–876
Hungr O (1995) A model for the runout analysis of rapid flow slides, debris flows, and avalanches. Can Geotech J 32(2):610–623
Hungr O, Evans SG (2004) Entrainment of debris in rock avalanches: an analysis of a long run-out mechanism. Geol Soc Am Bull 116(9):1240–1252
Hungr O, McDougall S (2009) Two numerical models for landslide dynamic analysis. Comput Geosci 35(5):978–992
Kan R, Zhang S, Yan F et al (1977) A study on the characteristics of modern tectonic stress field and modern tectonic activity in Southwest China. Acta Geophys Sin 20(2):96–109 (In Chinese)
Li P (1993) Xianshuihe-Xiaojiang fracture. Seismological Press, Beijing, pp 22–100 (In Chinese)
Li G, Wang S, Sun C (2001) Comprehensive assessment of engineering geological environment in hydroelectric development zone, Jinshajiang River. Earth Sci J China Univ Geosci 26(3):309–313 (In Chinese)
Liu W, He S (2016) A two-layer model for simulating landslide dam over mobile river beds. Landslides 13(3):565–576
Luo Y, Wang Y (2013) A study on the mountain slope ground motion topography amplification effect induced by Wenchuan earthquake. J Mt Sci 31(2):200–210 (In Chinese)
Lysmer J (1969) Finite dynamic model for infinite media. J Eng Mech Div 95(4):859–878
Qiaojia Chorography compilation committee of Qiaojia (1997) History of Qiaojia. People’s Press of Yunnan, Kunming (In Chinese)
Song F, Wang Y, Yu W et al (1998) Xiaojiang active fracture. Seismological Press, Beijing, pp 5–206 (In Chinese)
Tang C (1997) Numerical simulation of progressive rock failure and associated seismicity. Int J Rock Mech Min Sci 34(2):249–261
Tang H, Liu X, Hu X, Griffiths DV (2015) Evaluation of landslide mechanisms characterized by high-speed mass ejection and long-run-out based on events following the Wenchuan earthquake. Eng Geol 194:12–24
Wang G, Wang E (2005) Extensional structures within the compressional orogenic belt and its mechanism: a case study for the late Cenozoic deformation in central Yunnan. Seismol Geol 27(2):188–199
Wen X (1993) The rupture segmentation and seismic potential probability estimation of Xiaojiang Fracture. Acta Seismol Sin 15(3):322–330 (In Chinese)
Xu L (2004) A study on genetic mechanism and stability of Jinjiang landslide at the Baihetan hydropower station in the Jinsha River. Master degree thesis of Chengdu University of Technology (In Chinese)
Xu X (2012) Research on rock mass mechanical characteristics and stability of high slope of Baihetan hydropower station. Doctoral dissertation of Chengdu University of Technology (In Chinese)
Xu Q, Pei X, Huang R et al (2009) Large-scale landslide induced by the Wenchuan earthquake. Science and Technology Press, Beijing, pp 1–52 (In Chinese)
Yin Y, Wang M, Li B, Feng Z (2012) Dynamic response characteristics of Daguangbao landslide triggered by Wenchuan earthquake. Chin J Rock Mech Eng 31(10):1969–1982
Yuan X, Xu Q, Cheng Q, Xing A (2016) An analysis of air-blasts induced by rock avalanche. Hydrogeol Eng Geol 43(6):113–119
Zhang S (2007) Engineering geological feasibility study of high arch dam construction at Baihetan hydropower station, Jinsha River. Doctoral dissertation of Chengdu University of Technology (In Chinese)
Zhang X, Wang Y (2017) Activities of Xiaojiang fault zone in Baihetan hydropower station reservoir. J Eng Geol 25(2):531–540
Zhang Z, Wang S, Wang L (1994) Engineering geology analysis principle. Geological Publishing House, Beijing (In Chinese)
Funding
This study has been supported by the Funds for Creative Research Groups of China (Project No. 41521002), the National Key Research and Development Program of China (Project No. 2017YFC1501000), the Independent Fund of State Key Laboratory of Geohazard Prevention and Geoenvironment Protection (Chengdu University of Technology) (Project No. SKLGP2015Z001) and the National Natural Science Foundation of China (Project No. U1704243). The authors express their gratitude for the financial assistance.
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Shen, T., Wang, Y., Huang, Z. et al. Formation mechanism and movement processes of the Aizigou paleolandslide, Jinsha River, China. Landslides 16, 409–424 (2019). https://doi.org/10.1007/s10346-018-1082-1
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DOI: https://doi.org/10.1007/s10346-018-1082-1