A new DTM-based three-dimensional MPM model for simulating rapid flow-like landslides propagating on curved bed

IF 5.8 2区 工程技术 Q1 ENGINEERING, GEOLOGICAL Landslides Pub Date : 2024-04-26 DOI:10.1007/s10346-024-02261-5
Wei Shen, Zhitian Qiao, Tonglu Li, Ping Li, Jiheng Li, Jianbing Peng
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Abstract

Rapid flow-like landslides frequently occur in mountainous regions. To mitigate the disasters caused by these landslides, it is crucial to develop robust numerical models that can accurately predict their run-out processes. Models based on the material point method (MPM) offer significant advantages in simulating large deformation issues in geomaterials, including landslides. However, applying these models to accurately simulate real-world rapid flow-like landslides remains a challenge, primarily due to the complexities involved in handling the three-dimensional (3D) sliding bed boundary. This paper introduces a novel 3D MPM model specifically designed for simulating rapid flow-like landslides that propagate across curved beds. The constraints of the sliding bed on the landslide are imposed by the boundary nodes close to the bed. These boundary nodes carry information about the normal vector of the sliding bed, derived directly from the digital terrain model (DTM). Furthermore, the model integrates a hybrid formulation that combines the Full Lagrangian Implicit Particle (FLIP) method with the Particle In Cell (PIC) method, facilitating a stable solution for the velocity and position of material points. The effectiveness of the proposed model is confirmed through a numerical analysis of a rigid block sliding down an inclined plane and an experiment of sand flow on a curved bed. The simulation results from these two benchmark scenarios align closely with both analytical and experimental data, attesting to the validity of the model. The model is then applied to analyze a rapid flow-like landslide that occurred in Gansu Province, China, characterized by a curved sliding bed. The outcomes illustrate the model’s capability to efficiently capture the landslide’s climbing and turning motions induced by the meandering topography. Moreover, it successfully reproduces the main deposition characteristics observed in the field, demonstrating the model’s strong suitability for simulating the propagation of rapid flow-like landslides on naturally curved beds.

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基于 DTM 的新型三维 MPM 模型,用于模拟在弯曲河床上传播的急流式滑坡
山区经常发生急流式滑坡。为了减轻这些滑坡造成的灾害,开发能够准确预测其冲出过程的强大数值模型至关重要。基于材料点法(MPM)的模型在模拟包括滑坡在内的地质材料大变形问题方面具有显著优势。然而,将这些模型用于精确模拟现实世界中的快速流动型滑坡仍是一项挑战,这主要是由于处理三维(3D)滑动床边界所涉及的复杂性。本文介绍了一种新颖的三维 MPM 模型,该模型专为模拟在弯曲床面传播的快速流动式滑坡而设计。滑动床对滑坡的约束是由靠近滑动床的边界节点施加的。这些边界节点带有直接从数字地形模型(DTM)中获得的滑动床法向量信息。此外,该模型还采用了一种混合方法,将全拉格朗日隐含粒子(FLIP)方法与单元内粒子(PIC)方法相结合,从而为材料点的速度和位置提供了一个稳定的解决方案。通过对刚性块体在斜面上滑动的数值分析和沙粒在弯曲床面流动的实验,证实了所提模型的有效性。这两个基准场景的模拟结果与分析和实验数据非常吻合,证明了模型的有效性。随后,该模型被用于分析发生在中国甘肃省、以弯曲滑床为特征的急流式滑坡。结果表明,该模型能够有效捕捉蜿蜒地形引起的滑坡爬升和转弯运动。此外,它还成功地再现了现场观察到的主要沉积特征,证明该模型非常适合模拟自然弯曲滑床上的急流型滑坡的传播。
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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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