Influence of local gradual water depth variation on landslide-induced wave characteristics along reservoir banks
KE Chao1, MIAO Fasheng1*, WANG Yang1, WU Yiping1, LIU Jizhixian2
(1. Faculty of Engineering, China University of Geosciences, Wuhan, Hubei 430074, China;
2. Faculty of Civil Engineering, Hubei Engineering University, Xiaogan, Hubei 432000, China)
Abstract:Landslides occurring along reservoir banks in narrow water bodies, due to local gradual water depth variations, may generate wave characteristics distinct from those in wider water bodies In this study, large-scale physical model experiments were conducted to investigate landslide-induced waves along reservoir banks in narrow water bodies. The wave propagation characteristics were analyzed in three specific regions: the water body above the riverbed (WRB), the water body above the opposite bank slope (WOB), and the water body above the original bank slope (WIB). The results reveal that the leading wave train, prior to the onset of run-up behavior, was influenced solely by the shoaling effect, without being affected by reflection, refraction, or breaking. The maximum relative amplitude of the first wave crest in the WRB and WOB regions occurred at an angle of 0° and decreased with increasing angles, while in the WIB region, it increased with increasing angles. The most significant attenuation of the first wave crest was observed at an angle of 10°, rather than at 0°. In regions closer to the landslide impact point, the propagating waves (excluding the edge waves in the WIB region) exhibited greater fluctuations. A relative distance of 4.85 (equivalent to 1.7 meters) was identified as the boundary beyond which the kinetic energy from the landslide no longer significantly influenced the first wave. Additionally, in areas closer to the landslide entry point, the correlation between the relative period and angle became more pronounced. The average initial wave velocities in the WRB, WIB, and WOB regions were 0.93, 0.87, and 1.03, respectively (all close to 1), indicating that the velocities of the first wave in all regions can be accurately approximated by long-wave theory.
柯 超1,苗发盛1*,汪 洋1,吴益平1,刘继芝娴2. 局部渐变水深对库岸滑坡涌浪特征影响的室内试验研究[J]. 岩石力学与工程学报, 2026, 45(7): 2082-2093.
KE Chao1, MIAO Fasheng1*, WANG Yang1, WU Yiping1, LIU Jizhixian2. Influence of local gradual water depth variation on landslide-induced wave characteristics along reservoir banks. , 2026, 45(7): 2082-2093.
[1] CHIOCCI F L,ROMAGNOLI C,TOMMASI P,et al. The Stromboli 2002 tsunamigenic submarine slide:characteristics and possible failure mechanisms[J]. Journal of Geophysical Research:Solid Earth,2008,113(B10).
[2] HEIDARZADEH M,ISHIBE T,SANDANBATA O,et al. Numerical modeling of the subaerial landslide source of the 22 December 2018 Anak Krakatoa volcanic tsunami,Indonesia[J]. Ocean Engineering,2020,195:106733.
[3] MILLER D J. The Alaska earthquake of July 10,1958:Giant wave in Lituya Bay[J]. Bulletin of the Seismological Society of America,1960,50(2):253–266.
[4] 李秋旺,黄波林,张 鹏,等. 滑体破碎程度对滑坡涌浪特征的影响研究[J]. 岩土力学,45(11):3 345–3 354.(LI Qiuwang,HUANG Bolin,ZHANG Peng,et al. Influence of the degree of landslide fragmentation on the characteristics of landslide impulse wave[J]. Rock and Soil Mechanics,2024,45(11):3 345–3 354.(in Chinese))
[5] WANG J,WARD S N,XIAO L. Numerical simulation of the December 4,2007 landslide-generated tsunami in Chehalis Lake,Canada[J]. Geophysical Journal International,2015,201(1):372–376.
[6] GYLFADÓTTIR S S,KIM J,HELGASON J K,et al. The 2014 Lake Askja rockslide-induced tsunami:Optimization of numerical tsunami model using observed data[J]. Journal of Geophysical Research:Oceans,2017,122(5):4 110–4 122.
[7] HUANG B,YIN Y,WANG S,et al. A physical similarity model of an impulsive wave generated by Gongjiafang landslide in Three Gorges Reservoir,China[J]. Landslides,2014,11:513–525.
[8] 黄波林,胡刘洋,李仁江,等. 水库区低 Froude 数的典型涉水滑坡涌浪缩尺物理模型试验研究——以王家山滑坡为例[J]. 岩石力学与工程学报,2023,42(8):1 899–1 909.(HUANG Bolin,HU Liuyang,LI Renjiang,et al. Scaled experimental study on impulse wave generated by a typical semi-submerged landslide with low Froude number in the reservoir area—Taking Wangjiashan landslide as an example[J] Chinese Journal of Rock Mechanics and Engineering,2023,42(8):1 899–1 909.(in Chinese))
[9] XIAO L,WANG J,WARD S N,et al. Numerical modeling of the June 24,2015,Hongyanzi landslide generated impulse waves in Three Gorges Reservoir,China[J]. Landslides,2018,15:2 385–2 398.
[10] 肖莉丽,王佳佳,李枝强,等. 考虑滑体–水体相互作用的滑坡涌浪产生过程动力学模型研究[J]. 岩石力学与工程学报,2022,41(12):2 404–2 416.(XIAO Lili,WANG Jiajia,LI Zhiqiang,et al. Research on dynamic models of landslide tsunami generation considering slide/water interactions[J] Chinese Journal of Rock Mechanics and Engineering,2022,41(12):2 404–2 416.(in Chinese))
[11] HU Y,YU Z,ZHOU J. Numerical simulation of landslide-generated waves during the 11 October 2018 Baige landslide at the Jinsha River[J]. Landslides,2020,17(10):2 317–2 328.
[12] HELLER V,RUFFINI G. A critical review about generic subaerial landslide-tsunami experiments and options for a needed step change[J]. Earth-Science Reviews,2023,242:104459.
[13] PANIZZO A,DE GIROLAMO P,PETACCIA A. Forecasting impulse waves generated by subaerial landslides[J]. Journal of Geophysical Research:Oceans,2005,110(C12):1–23.
[14] 叶耀琪. 黄河小浪底水库滑坡涌浪试验介绍[J]. 人民黄河,1982,(4):20–24.(YE Yaoqi. Introduction of the landslide tsunami tests of Xiaolangdi reservoir,Yellow river[J]. Yellow River,1982,(4):20–24.(in Chinese))
[15] HELLER V,SPINNEKEN J. On the effect of the water body geometry on landslide-tsunamis:Physical insight from laboratory tests and 2D to 3D wave parameter transformation[J]. Coastal Engineering,2015,104:113–134.
[16] WANG Y,LIU J,LI D,et al. Optimization model for maximum tsunami amplitude generated by riverfront landslides based on laboratory investigations[J]. Ocean Engineering,2017,142:433–440.
[17] CHEN S,XU W,FENG Y,et al. Experimental investigation on potential high-position landslide-generated impulse waves:A case study of the Meilishi landslide in the Gushui Reservoir,China[J]. Ocean Engineering,2024,314:119723.
[18] WANG J,XIAO L,WARD S N. Tsunami squares modeling of landslide tsunami generation considering the ‘Push Ahead’ effects in slide/water interactions:Theory,experimental validation,and sensitivity analyses[J]. Engineering Geology,2021,288:106141.
[19] 袁培银,王平义,赵 宇,等. 三峡库区滑坡沿程涌浪传播特性模型试验研究[J]. 重庆交通大学学报:自然科学版,2020,39(10):100–104.(YUAN Peiyin,WANG Pingyi,ZHAO Yu,et al. Model test study on propagation characteristics of landslide-generated surge along river in Three Gorges Reservoir Area[J]. Journal of Chongqing Jiaotong University:Natural Science,2020,39(10):100–104.(in Chinese))
[20] 韩林峰,王平义,牟 萍,等. 三维岩体滑坡诱发冲击波近场波的特性试验研究[J]. 西南交通大学学报,2021,57(2):346–352.(HAN Linfeng,WANG Pingyi,MU Ping,et al. Experimental study on near-field characteristics of impulse waves generated by three-dimensional rock slide[J]. Journal of Southwest Jiaotong University,2021,57(2):346–352.(in Chinese))
[21] 陈世壮,徐卫亚,石安池,等. 高坝大库滑坡涌浪灾害链研究综述[J]. 水利水电科技进展,2023,43(3):83–93.(CHEN Shizhuang,XU Weiya,SHI Anchi,et al. Review of hazard chain of landslide surge for dams and large reservoirs[J]. Advances in Science and Technology of Water Resources,2023,43(3):83–93.(in Chinese))
[22] EVERS F M. Spatial propagation of landslide generated impulse waves[Ph. D. Thesis][D]. Zurich:ETH Zurich,2017.
[23] 殷坤龙,刘艺梁,汪 洋,等. 三峡水库库岸滑坡涌浪物理模型试验[J]. 地球科学,2012,37(5):1 067–1 074.(YIN Kunlong,LIU Yiliang,WANG Yang,et al. Physical model experiments of landslide-induced surge in Three Gorges Reservoir[J]. Earth Science—Journal of China University of Geosciences,2012,37(5):1 067–1 074. (in Chinese))
[24] LIU J,WANG Y,YIN K,et al. Landslide-tsunami prediction in narrow reservoirs involving reflection[J]. Natural Hazards,2023,115(3):2 457–2 482.
[25] GRILLI S T,SVENDSEN I A,SUBRAMANYA R. Breaking criterion and characteristics for solitary waves on slopes[J]. Journal of Waterway,Port,Coastal,and Ocean Engineering,1997,123(3):102–112.
[26] TAKABATAKE T,HAN D C,VALDEZ J J,et al. Three-dimensional physical modeling of tsunamis generated by partially submerged landslides[J]. Journal of Geophysical Research:Oceans,2022,127(1):e2021JC017826.
[27] MOHAMMED F,FRITZ H M. Physical modeling of tsunamis generated by three-dimensional deformable granular landslides[J]. Journal of Geophysical Research:Oceans,2012,117(C11):1–20.