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Progress in Landslide Research and Technology, Volume 3 Issue 1 2024



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Autore: Abolmasov Biljana Visualizza persona
Titolo: Progress in Landslide Research and Technology, Volume 3 Issue 1 2024 Visualizza cluster
Pubblicazione: Cham : , : Springer, , 2024
©2024
Edizione: 1st ed.
Descrizione fisica: 1 online resource (457 pages)
Altri autori: Alcántara-AyalaIrasema  
ArbanasŽeljko  
HuntleyDavid  
KonagaiKazuo  
Mihalić ArbanasSnježana  
MikosMatjaž  
RameshManeesha V  
SassaKyoji  
SassaShinji  
Nota di contenuto: Intro -- Foreword by Motoko Kotani -- Editorial Board of the Book Series -- Global Promotion Committee of the International Programme on Landslides and Kyoto Landslide Commitment 2020 -- A Commitment to the Sendai Framework and the Sustainable Development Goals -- Members of the IPL-KLC Global Promotion Committee -- Contents -- The Third-Year Publication of the Open Access Book Series "Progress in Landslide Research and Technology" -- 1 Introduction -- 1.1 Background -- 1.2 Open Access Book Series -- 2 Front Covers of the Published and Publishing Issues -- 3 Management of P-LRT -- 3.1 Basic Components for P-RLT -- 3.2 Editors on the Front Cover -- 3.3 New Awards -- 4 Countries /Regions of the Authors -- 5 Composition of Categories of each Issue -- 6 Call for Articles to Volume 3, Issue 2 -- References -- Part I: ICL Landslide Lesson -- Interpretation and Mapping for the Prediction of Sites at Risk of Landslide Disasters: From Aerial Photography to Detection by DTMs -- 1 Introduction (Basic Focus, Pointing Out Issues, etc.) -- 2 Mass-Movement on Slopes and Typology of Slope Disasters -- 2.1 Geomorphological Understanding of Slope Mass-Movement -- 2.2 The First Step in Understanding Slope Topography, Such As Landslides -- 2.3 Synthesize and Categorize the Slope Mass-Movement Phenomena -- 2.4 Autonomous Destruction Process by Landslides -- 3 Actual Interpretation of Landslide Topography and Utilization of Digital 3D Information -- 3.1 Development of Real Visual Interpretation of Landslide Topography -- 3.2 Considering the Significance of the Shift from Physical Vision to 3D Data Processing -- 4 Mapping Slope Changes Using AW3D -- 4.1 Mapping AW3D Data to Slope Variation -- 4.2 Example of Landslide Topography Distribution Map -- 4.2.1 AW3D-Based Landslide Topography Mapping in Vietnam and Sri Lanka -- 4.2.2 Mapping Results.
4.2.3 Wide-Area Landslide Topographic Distribution Map 1/25000 -- 5 Toward an Era in which Everyone Can Grasp the Terrain in Three Dimensions -- 6 Aerial Photo Interpretation and Slope Disaster Risk Mapping Training for Beginners -- 6.1 Focus and Aim -- 6.2 Aerial Photo Interpretation "Steps for the Technicalization" -- 6.2.1 Stage 1: Seeing Aerial Photography As a Reality -- 6.2.2 Stage 2: Talk About Impressions of "Things" That You See As a Reality -- 6.2.3 Stage 3: Focus on the Terrain (this Is the Core) -- 6.2.4 Stage 4: Observing the Longitudinal Profile from the Ridge to the Valley Floor and Considering the Formation Process -- 6.2.5 Stage 5: Deciphering Landslide-Induced Terrain -- 6.2.6 Stage 6: Find and Map Landslide Terrain Using Aerial Photography -- 7 Understanding Landslide Topography Using Contour Lines and Training for Evaluating Slope Instability -- 7.1 Perspectives and Approaches -- 7.2 Reading Data -- 7.3 Stages Using Airborne LiDAR Data -- 7.4 Extracting Landslide Topography with AW3D Data -- 7.5 Samples of the Landslide Topographic Area Mapping -- 8 Procedure for Preparing a 3D Map to Detect the Landslide Topography -- 8.1 3D Topographic Map for Landslide Topography Detection -- 8.1.1 The 3D Microtopography Map (MT3DM) -- 8.2 Creating a Three-Dimensional Microtopographic Map (MT3DM) -- 8.2.1 Software for Processing the MT3DM -- 8.2.2 (1) Setting and Transforming the Coordinate System -- 8.2.3 (2) How to Add Layers -- 8.2.4 (3) How to Save Project Data -- 8.3 Preparation for 3D Microtopographic Map -- 8.4 Creation of 3D Microtopographic Map (MT3DM) -- 8.4.1 Completion of Three-Dimensional Microtopographic Map (MT3DM) -- 8.5 Landslide Topography Decipherment Using 3D Microtopographic Map (MT3DM) -- 8.5.1 Topographic Decipherment Using 3D Microtopographic Maps (MT3DM).
8.5.2 Interpretation Example of Landslide Topography in the Active Phase -- 8.6 Points to Note and Issues in the 3D Microtopographic Map (MT3DM) -- 8.6.1 Color Scale Thresholds and Terrain Representation -- 8.6.2 Topographic Volume Analysis Results and Threshold Settings of Landslide Terrain -- 8.6.3 Landslide Topography Representation and DTM Accuracy -- 9 Conclusion -- References -- Part II: Original Articles -- Observation of Seismic Ground Motion and Pore Water Pressure in Lineated Valley Fill of Wakayama, Southwest Japan -- 1 Introduction -- 2 Observations -- 3 Data and Analysis -- 4 Discussion -- 5 Conclusions -- References -- Global Warming May Accelerate Submarine Landslides in the Oceans -Possible Disaster Chain Reactions- -- 1 Introduction -- 2 Disaster Chain Reactions -- 3 Gas Hydrate May Introduce Submarine Landslide -- 4 Case Studies of Landslides in Connection to the Global Warnings -- 5 Concluding Remarks -- Storegga Slide and Landslide-Induced Tsunamis -- Gas Hydrate Melting Processes -- References -- Landslide Hazard Evaluation of a Large Waste Landfill in Bogotá City -- 1 Introduction -- 2 General Description of Doña Juana Waste Landfill and Previous Instability Problems -- 3 Operational Problems Related to Leachate and Gas Evacuation -- 4 Geotechnical Characterization and Monitoring -- 5 Analysis of Pore Pressure and Efficiency of the Pumping Systems -- 6 Stability Models -- 7 Hazard Analysis -- 8 Conclusions -- References -- Multiple Landslides in an Area Draped in Volcanic Matters: The Dual Impacts of Rains and Earthquakes -- 1 Introduction -- 2 Multiple Landslides in the 2018 Hokkaido Eastern Iburi Earthquake -- 3 Preceding Rains -- 4 Method -- 5 Rainfall Modeling -- 6 Impact of Rains and Earthquake -- 7 Conclusions and Future Works -- Appendix: Timeline -- References.
Loess Landslides-Peculiarities of Deformation Mechanism -- 1 Introduction -- 2 Loess and Its Prevalence -- 3 Specific Features of Landslide Occurrence in Loess Rocks -- 3.1 Rotational Loess Slides -- 3.2 Translational Loess Slides -- 3.3 Loess Falls -- 3.4 Loess Flow Slides -- 3.5 Dry Loam Avalanches and Sudden Liquefaction Loess Slides -- 3.6 Suffosion Loess Slides -- 4 Stability of Slopes Composed of Loess Rocks and Factors Influencing Its Changes -- 5 Conclusion -- References -- Spatio-Temporal Distribution of Rainfall-Induced Landslides in Nicaragua (2000-2022): Preliminary Insights to Communicate Landslide Disaster Risk -- 1 Introduction -- 2 Landslide Databases and Inventories -- 3 Studied Area -- 4 Methodology -- 5 Results -- 5.1 Landslide Disaster Risk Communication -- 6 Concluding Remarks and Future Steps -- References -- Emerging Seismicity Trends Linked to Catastrophic Landslides Behavior in Sri Lanka -- 1 Introduction -- 2 Landslides Initiation with Rockslides -- 3 Facilitation from the SATREPS Project for Seismicity Monitoring in Landslides Proven Areas -- 4 History of Seismicity and Earthquake in Sri Lanka -- 4.1 First Recorded Earthquake in Sri Lanka -- 4.2 Other Historical Records -- 5 Reservoir Induced Seismicity Records -- 5.1 Micro-Seismicity Recording -- 6 Emerging Trend of Earthquakes in the Indian Ocean -- 7 Discussion on Regional Effects -- 8 Recent Development of Seismicity Monitoring -- 9 Micro-Seismicity Impact on Catastrophic Landslides -- 10 Stability Evaluations -- 11 Seismic Coefficients According to Eurocode 8 -- 12 Conclusions -- References -- Centrifuge Modeling of Slopes Subjected to Groundwater Flow and Rainfall Infiltration -- 1 Introduction -- 2 Experimental Setup -- 2.1 Centrifuge Model Testing -- 2.2 Slope Construction -- 2.3 Slope Material.
2.4 Groundwater Flow Simulation -- 3 Validating the Functioning of the Centrifuge Chamber -- 3.1 Porewater Pressure Variation during Seepage -- 3.2 Porewater Pressure Variation During Rainfall -- 3.3 Evolution of Failure -- 4 Influence of the Initial Groundwater Flow on Landslide Initiation -- 4.1 Porewater Pressure Variation -- 4.2 Evolution of Failure -- 4.3 Landslide Mobility -- 5 Conclusions -- References -- Evaluation of Assessment Models for Landslide Susceptibility Mapping in Permafrost Areas -- 1 Introduction -- 2 Study Area -- 3 Materials -- 4 Methods -- 4.1 Information Value Model -- 4.2 Random Forest Model -- 4.3 Frequency Ratio Method -- 4.4 ROC Curve Verification -- 5 Result and Discussion -- 6 Conclusion -- References -- The Slope Monitoring Using Embedded System with Optical-Thermal Image Fusion and Machine Learning -- 1 Introduction -- 2 Instrument Design and Image Analysis Process -- 3 Laboratory Vibration Table Experiment -- 4 NCU Field Experiment -- 5 AI Image Analysis for Decision Support -- 6 Conclusion and Suggestions -- References -- Sendai Framework Voluntary Commitments: Monitoring Landslide Stakeholders' Contributions -- 1 Introduction -- 2 Data and Methods -- 3 Results -- 4 Comparing Landslide-Related Initiatives with All Voluntary Commitments -- 5 A Closer Look at Landslide-Related VCs -- 6 Conclusions -- Appendix -- References -- Influence of Intra-Particle Saturation Ratio on Strength Degradation of Pumice Soil -- 1 Introduction -- 2 Material and Method -- 2.1 Material -- 2.2 Test Method -- 2.2.1 Single Particle Fragmentation Test -- 2.2.2 Determination of Intra-Particle Saturation Ratio -- 2.2.3 Direct Shear Tests -- 3 Results and Discussion -- 3.1 Single Particle Fragmentation Test -- 3.2 Intra-particle Saturation Ratio -- 3.3 Direct Shear Test -- 4 Conclusions -- References.
Regional Debris Flow Hazard Assessment of the Grdelica Gorge (Serbia).
Titolo autorizzato: Progress in Landslide Research and Technology, Volume 3 Issue 1 2024  Visualizza cluster
ISBN: 9783031551208
Formato: Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione: Inglese
Record Nr.: 9910865261403321
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Serie: Progress in Landslide Research and Technology Series