Investigating the dynamic process of a rock avalanche through an MLS-MPM simulation incorporated with a nonlocal μ(I) rheology model

IF 5.8 2区 工程技术 Q1 ENGINEERING, GEOLOGICAL Landslides Pub Date : 2024-04-11 DOI:10.1007/s10346-024-02244-6
Shuxi Zhao, Siming He, Xinpo Li, Gianvito Scaringi, Yang Liu, Yu Deng
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Abstract

Rock avalanches typically entail the flow-like motion of angular rock blocks and fragments of diverse size. Numerical simulations are instrumental in understanding their dynamic process, supporting hazard and risk assessments. Simplified failure criteria, such as the Mohr-Coulomb or Drucker-Prager, are commonly adopted in landslide models relying on the material point method (MPM). However, these criteria cannot capture the transitions between solid-like, liquid-like, and gas-like behaviors exhibited by granular materials. Here, we relied on the moving least-squares MPM, which offers high computing efficiency and stability, and adopted a nonlocal μ(I) rheology model implemented by Haeri and Skonieczny (Comput Methods Appl Mech Eng, 2022). This approach can account for the rate-dependent, pressure-dependent, and size-dependent characteristics of friction in granular materials. By simulating a small-scale flume experiment as well as a large-scale event (the Nayong rock avalanche in Guizhou, China), we verified that the nonlocal μ(I) rheology model can capture the motion and deposition processes in rock avalanches effectively. This feature can be advantageous in physically based hazard assessments of such events.

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通过结合非局部 μ(I)流变模型的 MLS-MPM 模拟研究岩崩的动态过程
岩石崩塌通常是由不同大小的角状岩块和碎石组成的流动运动。数值模拟有助于了解其动态过程,支持危害和风险评估。基于材料点法(MPM)的滑坡模型通常采用简化的破坏标准,如莫尔-库仑(Mohr-Coulomb)或德鲁克-普拉格(Drucker-Prager)。然而,这些标准无法捕捉颗粒材料所表现出的固态、液态和气态行为之间的转变。在此,我们采用了计算效率高、稳定性强的移动最小二乘 MPM,并采用了 Haeri 和 Skonieczny(Comput Methods Appl Mech Eng,2022 年)提出的非局部 μ(I)流变模型。这种方法可以解释颗粒材料摩擦的速率依赖性、压力依赖性和尺寸依赖性特征。通过模拟小规模水槽实验和大规模事件(中国贵州纳雍岩崩),我们验证了非局部μ(I)流变模型能有效捕捉岩崩的运动和沉积过程。这一特点有利于对此类事件进行基于物理的危害评估。
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来源期刊
Landslides
Landslides 地学-地球科学综合
CiteScore
13.60
自引率
14.90%
发文量
191
审稿时长
>12 weeks
期刊介绍: Landslides are gravitational mass movements of rock, debris or earth. They may occur in conjunction with other major natural disasters such as floods, earthquakes and volcanic eruptions. Expanding urbanization and changing land-use practices have increased the incidence of landslide disasters. Landslides as catastrophic events include human injury, loss of life and economic devastation and are studied as part of the fields of earth, water and engineering sciences. The aim of the journal Landslides is to be the common platform for the publication of integrated research on landslide processes, hazards, risk analysis, mitigation, and the protection of our cultural heritage and the environment. The journal publishes research papers, news of recent landslide events and information on the activities of the International Consortium on Landslides. - Landslide dynamics, mechanisms and processes - Landslide risk evaluation: hazard assessment, hazard mapping, and vulnerability assessment - Geological, Geotechnical, Hydrological and Geophysical modeling - Effects of meteorological, hydrological and global climatic change factors - Monitoring including remote sensing and other non-invasive systems - New technology, expert and intelligent systems - Application of GIS techniques - Rock slides, rock falls, debris flows, earth flows, and lateral spreads - Large-scale landslides, lahars and pyroclastic flows in volcanic zones - Marine and reservoir related landslides - Landslide related tsunamis and seiches - Landslide disasters in urban areas and along critical infrastructure - Landslides and natural resources - Land development and land-use practices - Landslide remedial measures / prevention works - Temporal and spatial prediction of landslides - Early warning and evacuation - Global landslide database
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