Abstract
The events of landslides induced by the combined effect of earthquakes and rainfall are more dangerous than those induced by earthquake or rainfall. The Yongguang loess landslide induced by the Minxian–Zhangxian Ms 6.6 earthquake in 2013 is a typical example of a landslide induced by the combined effect of an earthquake and rainfall. A few scholars have carried out relevant research on this landslide, but the initiation mechanism of this kind of landslide has not been elucidated. Therefore, the initiation mechanism of loess landslide under the combined effect of earthquakes and rainfall is studied through indoor geotechnical tests, shaking table slope model tests and numerical simulations. The indoor geotechnical tests show that the mechanical properties of Q3 loess would change significantly (the mechanical strength would decrease sharply) when soaked in water and that its strength would be further lowered under dynamic action. The slope model test results show that the infiltration depth at the slope top is deeper than that of the slope surface after continuous heavy artificial rainfall and that the natural frequency of the shoulder of the front edge of the slope top is closer to the frequency of the loading wave than it is in other parts of the slope; so the amplification effect of the seismic ground motion at the shoulder of the front edge of the slope top is more significant and the soil damage is more serious under seismic dynamic action. With the rapid increase in the residual deformation and pore water pressure of the soil mass, the loess properties change substantially, that is, loess liquefaction occurs when the pore water pressure and residual deformation reach a certain threshold. Under the action of the subsequent seismic ground motion, the liquefied loess mass of the front edge of the slope top rushes out along the sliding bed and slides down the slope surface in the form of a loess mudflow; that is, a mudflow-like loess landslide is induced. A simplified mechanical model is used in the numerical simulation test and can reproduce the triggering process of this kind of loess landslide. In this research, the initiation mechanism of mudflow-like loess landslide induced by the combined effect of earthquakes and rainfall is revealed by comprehensively considering a variety of test results, and a sliding distance calculation formula is proposed, providing a foundation for the prevention and control of this kind of landslide disaster.
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References
Bo Z, Yunsheng W, Qianqian F et al (2020) Preliminary analysis of some characteristics of coseismic landslides induced by the Hokkaido Iburi-Tobu earthquake (September 5, 2018), Japan. Catena 189:104502. https://doi.org/10.1016/j.catena.2020.104502
Chen Y, Shi Y (2006) Characteristics of seismic landslide in loess area of Northwest China. Seismic Res 03:276–280
Deng L, Fan W (2013) Study on deformation and failure mechanism and development mechanism of loess landslide induced by magnitude 8.5 earthquake in Ningxia. J Disasters 3:30–37
Gao G (1980) Classification and collapsibility of loess microstructure. Chin Sci 12:1203–1208
Gong W, Li M, Wu Z (2012) Effects of rainfall and seismic coupling on landslide stability: a case study of Xihe III landslide in Gansu Province. Northwest Seismol J 2:161–166
Griffiths DV, Lane PA (1999) Slope stability analysis by finite element. Geotechnique 49(3):387–403
Jiang L, Yao LK, Wu W et al (2010) Application of transfer function analysis on slope shaking table model test. Rock Soil Mech 5:1368–1374
Jun K, Hiro K, Hirokazu M et al (2019) Fluidized landslides triggered by the liquefaction of subsurface volcanic deposits during the 2018 iburi–tobu earthquake. Hokkaido Sci Rep 9:13119. https://doi.org/10.1038/s41598-019-48820-y
Li H, Gao J, Zhang Y et al (2016) Analysis of Yan’an extreme rainfall chararacteristics and impacts of erosion disasters on terraces. J Soil Water Conserv 30(6):79–84
Lin ML, Wang KL (2006) Seismic slope behavior in a large scale shaking table model test. Eng Geol 86(2):118–133
Lin G, Zhu T, Lin B (2000) Similar techniques for structural dynamic model test. J Dalian Univ Technol 1:1–8
Liu K (2020) Earthquake-induced failure mechanism and stability evaluation of loess slope under rainfall effects. Lanzhou University, Lanzhou
Pan P (2017) Study on mechanism and treatment of landslide in Heifangtai. Zhejiang University, Zhejiang
Pu X, Wang L, Wang P, et al (2018) A portable and scalable artificial rainfall device for complex terrain. Chinese patent, CN201821575252.7, 2018–09–27
Ren L (2016) Formation mechanism of mud-flow loess landslide induced by earthquake. Xi’an University of Science Technology, Xian
Sassa K, Fukuoka H, Wang F et al (2007) Landslides Induced by a Combined Effect of Earthquake and Rainfall Progress of landslide. In: Sassa F, Wang W (eds) Progress in Landslide Science. Springer, Berlin, pp 193–207
Sassa K, Nagai O, Solidum R et al (2010) An integrated model simulating the initiation and motion of earthquake and rain induced rapid landslides and its application to the 2006 Leyte landslide. Landslides 7(3):219–236
Sassa K, Wang G, Fukuoka H et al (2004) Landslide risk evaluation and hazard mapping for rapid and long-travel landslides in urban development areas. Landslides 1(3):221–235
Shi Y, Wang L, Zhang Y (1999) Effects of thickness and topographic condition of loess field on earthquake dynamic amplification. Northwest Seismol J 2:262–273
Standardization Administration of China (2015) Seismic ground motion parameters zonation map of China (GB18306–2015), China
Sun J, Wang L, Long P et al (2011) Method for evaluation of regional landslide disaster, coupled with earthquake and rainfall. J Rock Mech Eng 30(4):752–760
Tian X, Li Z, Xu Q et al (2013) Observation records and preliminary analysis of strong motion of the Minxian-Zhangxian Ms6.6 earthquake. China Earthq Eng J 35(03):497–502
Wang L (2003) Loess dynamics, 1st edn. Earthquake Press, Beijing
Wang L, Wu Z (2013a) Earthquake damage characteristics of the Minxian-Zhangxian Ms6.6 earthquake and its lessons. China Earthq Eng J 35(3):401–412
Wang L, Wu Z (2013b) Earthquake damage characteristics of the Minxian-Zhangxian MS 6.6 earthquake and its lessons. China Earthq Eng J 35(3):401–412
Wang L, Yuan Z, Shi Y et al (1999) Study on index and method of seismic disaster division in loess Plateau. J Nat Disasters 3:87–92
Wen Y (2018) Experimental research of the stability of terrace slopes in loess area under extreme rainfall. Northwest A&F University, Xianyang
Wu Z, Chen Y, Wang Q et al (2019) Disaster-causing mechanism of Yongguang landslide under Minxian-Zhangxian Ms6.6 Earthquake. Chin J Geotech Eng 41(Supp. 2):165–168
Wu W, Wang N (2006) Gansu landslide disaster. Lanzhou University Press, Lanzhou
Wu Z, Wang L, Chen T et al (2012) Study on the magnifying mechanism of earthquake ground in the far field loess site of wenchuan earthquake. Rock Soil Mech 33(12):3736–3740
Wu W, Wang G, Ren L et al (2015) Characteristics and causes of mudflow-landslides in loess. J Glaciol Geocryol 37(1):138–146
Xu S, Wu Z, Sun J et al (2012) Study of the characteristics and inducing mechanism of typical earthquake landslides of the Minxian-Zhangxian MS 6.6 earthquake. China Earthq Eng J 35(3):471–476
Xu C, Wu X, Xu X (2018) Earthquake induced landslides in Loess Plateau and its adjacent areas. J Eng Geol 26:260–273
Yang Y (1988) Study on the mechanism of loess collapse. Chin Sci (Ser B) 7:754–766
Zhang Z (1999) Loess earthquake disaster prediction. Earthquake Press, Beijing
Zhang J, Yu Y, Pu J et al (2004) Development of electro hydraulic servo control centrifuge shaking table system. Chin J Geotech Eng 6:843–845
Acknowledgements
This work was supported by Basic Scientific Research Fund, Science and Technology Innovation Base of Lanzhou, Institute of Earthquake Forecasting, China Earthquake Administration (No. 2020IESLZ07), and the National Natural Science Foundation of China (No. U1939209). Dr. Q. Wang, Dr. S, Chai, Dr. S, Xu, Ms. X. Zhong, and Ms. G. Che are appreciated for their assistance during the experimental tests.
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Pu, X., Wan, L. & Wang, P. Initiation mechanism of mudflow-like loess landslide induced by the combined effect of earthquakes and rainfall. Nat Hazards 105, 3079–3097 (2021). https://doi.org/10.1007/s11069-020-04442-6
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DOI: https://doi.org/10.1007/s11069-020-04442-6