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Umfang: 1 Online-Ressource.

ISBN: 978-3-031-44296-4

Serie: Progress in landslide research and technology

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Weitere Ausg.: Erscheint auch als Druck-Ausgabe, Paperback ISBN 978-3-031-44298-8

Sprache: Englisch

DOI: 10.1007/978-3-031-44296-4

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Umfang: 1 online resource (490 pages)

Ausgabe: First edition.

ISBN: 9783031442964 , 3031442962

Serie: Progress in Landslide Research and Technology Series.

Inhalt: This book is part of an open-access series by the International Consortium on Landslides, focusing on recent advancements in landslide research and technology. It contributes to the Kyoto Landslide Commitment 2020 and the 2030 Agenda for Sustainable Development, aiming to reduce landslide disaster risks globally. The volume includes original research, review articles, case studies, and educational materials, serving as a resource for academics, researchers, and professionals in the field of geology and civil engineering. The book's editors and contributors are international experts in landslide science, providing a comprehensive platform for sharing knowledge and practical applications to benefit society.

Anmerkung: Intro -- Editorial Board of the Book Series -- Editor-in-Chief -- Assistant Editors-in-Chief -- Editors -- KLC2020 Managing Committee -- Advisory Members for KLC2020 -- KLC2020 Official Promoters -- Public Sectors: KLC2020 Official Promoters-Public -- International Unions/Associations, Governmental Organizations, Universities and Research Institutes -- Private Sectors: KLC2020 Official Promoters-Private -- Companies and Corporation -- Standing Editors for KLC2020 Book Series -- Editorial Office -- 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 -- Part I: ICL Landslide Lesson -- Advancements in Shear Strength Interpretation, Testing, and Use for Landslide Analysis -- 1 Background -- 2 Causes of Landslides -- 3 Planning and Design of Landslide Stabilization Works -- 4 Brief Overview of Shear Strengths -- 5 Shear Strength Measurements -- 5.1 Direct Shear Tests -- 5.2 Triaxial Tests -- 5.3 Direct Simple Shear Tests -- 5.4 Ring Shear Tests -- 5.5 Cyclic Simple Shear Tests -- 5.6 Cyclic Triaxial Tests -- 6 Correlations Methods to Obtain Soil Shear Strengths -- 6.1 Fully Softened Shear Strength -- 6.2 Residual Shear Strength -- 6.3 Undrained Shear Strengths of Over-Consolidated Clays -- 6.4 Cyclic Shear Strength -- 6.5 Post-Cyclic Undrained Shear Strength -- 6.6 Various Other Correlations -- 7 Example of Shear Strength Estimation with Correlation Methods -- 8 Summary and Recommendations -- References -- Rock Avalanches in the Tibetan Plateau of China -- 1 Introduction -- 2 Geological Setting of the Studied Area -- 3 Distribution of Rock Avalanches in the Study Area -- 3.1 Spatial Distribution of Rock Avalanches in the Himalayan Range, China. , 3.2 Locations of the Typical Rock Avalanches -- 4 Characteristics of Typical Rock Avalanche Deposits -- 4.1 Luanshibao Rock Avalanche -- 4.1.1 Geological Setting and General Features of the Luanshibao Rock Avalanche -- 4.1.2 Sedimentary Features of the Avalanche Deposit -- 4.2 Nyixoi Chongco Rock Avalanche -- 4.2.1 Geological Setting and General Features of the Nyixoi Chongco Rock Avalanche -- 4.2.2 Sedimentary Features of the Avalanche Deposit -- 4.3 Tagarma Rock Avalanche -- 4.3.1 Geological Setting and General Features of the Tagarma Rock Avalanche -- 4.3.2 Sedimentary Features of the Avalanche Deposit -- 4.4 Iymek Rock Avalanche -- 4.4.1 Geological Setting and General Features of the Iymek Rock Avalanche -- 4.4.2 Sedimentary Features of the Avalanche Deposit -- 5 Discussion -- 6 Conclusion -- References -- Part II: Original Articles -- Landslide Susceptibility Zonation Using GIS-Based Frequency Ratio Approach in the Kulon Progo Mountains Area, Indonesia -- 1 Introduction -- 2 Research Area -- 3 Methodology -- 4 Dataset and Analysis -- 5 Result & -- Discussion -- 6 Conclusion -- References -- Physically-Based Regional Landslide Forecasting Modelling: Model Set-up and Validation -- 1 Introduction -- 2 HIRESSS Model and Study Are a -- 2.1 HIRESSS Model -- 2.2 Study Area -- 3 Data Collection and Preparation -- 3.1 Static Data -- 3.2 Dynamic Data -- 4 HIRESSS Simulation and Analysis of the Results -- 4.1 Monte Carlo Simulations -- 4.2 Analysis of the Model Output and Validation -- 5 Conclusion -- References -- Consequence: Frequency Matrix as a Tool to Assess Landslides Risk -- 1 Introduction -- 2 The Main Principle of Matrix Use -- 3 The Conceptual Background -- 4 Example of Risk Matrix -- 5 Issues Linked to the Use of Matrix -- 5.1 Scale and Verbal Terms -- 5.1.1 The Classes of Consequences and Frequency or Probability. , 5.2 Setting the Risk Limits for Risk Matrix and F-N Curves -- 5.3 Uncertainty -- 5.4 Risk Reduction -- 5.5 Representing the Cascading Effect -- 5.6 Adding Dimensions -- 5.7 Cumulative Versus Non-cumulative Scale -- 5.7.1 An Example Ambiguous Use of Matrix -- 6 Summaries of the Recommendations -- 7 Example of Integration of Assessment for all Classes -- 8 Method -- 8.1 The Belonging to a Class and its Uncertainty -- 8.2 Classes Definitions -- 8.3 The Expert Assessment for a Specific Event -- 8.4 The Matrix Construction -- 8.5 The Example of a Particular Unstable Mass of Pont Bourquin Landslide -- 8.5.1 Landslide Settings -- 8.5.2 The Classes and Scales -- 8.5.3 Setting the Prior Probabilities -- 8.5.4 Results -- 9 Discussion and Conclusion -- References -- Do not Let Your Guard Down: Landslide Exposure and Local Awareness in Mexico -- 1 Introduction -- 2 Landslide Exposure and Awareness -- 3 Studied Area -- 4 Methodology -- 4.1 Aerial Survey Using UAVs -- 4.2 Expansion of the Urban Area -- 4.3 Rainfall Series -- 5 Results -- 6 Concluding Remarks -- References -- Landslides in Higher Education Curricula and Beyond -- 1 Introduction -- 1.1 General Views on Higher Education -- 1.2 The Focus of this Article -- 2 Materials and Methods -- 3 Results and Discussion -- 3.1 Background Studies on Landslides and Study Programmes -- 3.2 Academic Programmes in Disaster Risk Management -- 3.3 University Study Programs in Disaster Risk Reduction & -- Management -- 3.4 Selected Summer Schools on Landslides -- 3.5 Landslide-Related Capacity Building Examples -- 3.6 Case 1: The International School on Landslide Risk Assessment and Mitigation (LARAM) -- 3.7 Case 2: Kokomerem Summer School on Rockslides and Related Phenomena in the Kokomeren River Valley (Kyrgyzstan) -- 3.8 Case 3: The International Research Association on Large Landslides (iRALL) School. , 3.9 Case 4: ICL Landslide School Network -- 3.10 Case 5: ICL Landslide Teaching Tools -- 3.11 Case 6: ICL/IPL World Report on Landslides -- 3.12 Case 7: UNDRR PreventionWeb Platform -- 3.13 Case 8: United States Geological Survey (USGS) Web Sources -- 3.14 Case 9: NASA Models and Datasets -- 3.15 Case 10: The Landslide Blog in AGU Blogosphere -- 3.16 Case 11: BeSafeNet Platform -- 3.17 Case 12: The International Society for Rock Mechanics and Rock Engineering (ISRM) Course -- 3.18 Case 13: The LARIMIT Portal -- 3.19 Case 14: Humanitarian Library -- 3.20 Case 15: The VISUS Methodology -- 3.21 Case 16: The Twinkl Platform -- 4 Conclusions -- References -- Community Scale Landslide Resilience: A Citizen-Science Approach -- 1 Introduction -- 2 Related Works -- 2.1 Review of the Existing Citizen Science Approach -- 3 Citizen Science Approach -- 3.1 Requirements, Solutions, and Dimension of Landslide Resilience -- 4 Operationalization of the Citizen-Science Approach -- 4.1 Framework: Involving Citizens in Building Community-Scale Landslide Resilience -- 4.2 Pre-Disaster Measures -- 4.3 During-Disaster Measures -- 4.4 Post-Disaster Measures -- 5 Tools for Operationalization -- 5.1 Community Engagement -- 5.2 Social Media Data Analysis -- 5.3 AmritaKripa Mobile App -- 5.4 Landslide Tracker Mobile App -- 6 Case Study: Implementation of Framework -- 7 Discussion -- 7.1 Practical Challenges & -- Implementation Gaps -- 8 Conclusion -- References -- Remedial Measures Impact on Slope Stability and Landslide Occurrence in Small-Scale Slope Physical Model in 1 g Conditions -- 1 Introduction -- 2 Material and Methods -- 2.1 Physical Model -- 2.2 Soil Material Properties -- 2.3 Monitoring Equipment -- 2.4 Rainfall Simulator -- 2.5 Remedial Structures -- 3 Construction of Slope Models -- 3.1 Construction of Slope Models without Remedial Measure. , 3.2 Construction of Slope Model with Installation of Gravity Wall -- 3.3 Construction of Slope Model with Installation of Gabion Wall -- 3.4 Construction of Slope Model with Installation of Pile Wall -- 4 Testing and Results -- 4.1 Testing of Slope Models without Remedial Measures -- 4.2 Testing of Slope Model with Gravity Retaining Wall -- 4.3 Testing of Slope Model with Gabion Wall -- 4.4 Testing of Slope Model with Pile Wall -- 5 Discussion and Conclusions -- References -- Surficial Geology and Geomorphology of the North Slide, Thompson River Valley, British Columbia, Canada: Application of Fundam... -- 1 Introduction -- 1.1 Generalized Climate and Hydrology at North Slide -- 1.2 Historical Change Detection at North Slide -- 1.3 Baseline Geological Conditions at the North Slide -- 2 Methods and Observational Results -- 2.1 Terrain and Hydrogeological Mapping -- 2.1.1 Benchmarked Satellite Image Interpretation -- 2.1.2 Benchmarked UAV Orthomosaic Interpretation -- 2.2 Field Observations of Earth Material Textures, Porosity Variations, and Slope Failure in Terrain Units -- 2.2.1 Bedrock and Undifferentiated Weathered Lag (Unit 1 -- R, R-R) -- 2.2.2 Glaciolacustrine Sediments (Unit 2 -- GLb) -- 2.2.3 Glaciofluvial and Ice-Contact Sediments (Unit 3 -- GFb) -- 2.2.4 Ground Moraine (Unit 4 -- Tv, Tb, Tb-V, Td) -- 2.2.5 Glaciolacustrine and Glaciofluvial Sediments (Unit 5 -- GLt, GFt) -- 2.2.6 Alluvial Sediments (Unit 6 -- Ap, at, Af) -- 2.2.7 Colluvial Sediments (Unit 7 -- Cv, Cz, Cz-F) -- 2.2.8 Anthropogenic Deposits (Unit 8 -- Hb) -- 3 Discussion: Fundamental Geoscience Applied to Geospatial Monitoring Results -- 3.1 Hydrogeological Controls on Ancient Landslide Activity -- 3.2 Hydrogeological Controls on Historical Landslide Activity -- 3.3 Hydrogeological Controls on Recent Landslide Activity. -- 3.4 Projecting Future Landslide Activity and Consequences.

Weitere Ausg.: ISBN 9783031442957

Weitere Ausg.: ISBN 3031442954

Sprache: Englisch

DOI: 10.1007/978-3-031-44296-4

UID:

Umfang: 1 online resource (490 pages)

Ausgabe: 1st ed.

ISBN: 9783031442964

Serie: Progress in Landslide Research and Technology Series

Anmerkung: Intro -- Editorial Board of the Book Series -- Editor-in-Chief -- Assistant Editors-in-Chief -- Editors -- KLC2020 Managing Committee -- Advisory Members for KLC2020 -- KLC2020 Official Promoters -- Public Sectors: KLC2020 Official Promoters-Public -- International Unions/Associations, Governmental Organizations, Universities and Research Institutes -- Private Sectors: KLC2020 Official Promoters-Private -- Companies and Corporation -- Standing Editors for KLC2020 Book Series -- Editorial Office -- 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 -- Part I: ICL Landslide Lesson -- Advancements in Shear Strength Interpretation, Testing, and Use for Landslide Analysis -- 1 Background -- 2 Causes of Landslides -- 3 Planning and Design of Landslide Stabilization Works -- 4 Brief Overview of Shear Strengths -- 5 Shear Strength Measurements -- 5.1 Direct Shear Tests -- 5.2 Triaxial Tests -- 5.3 Direct Simple Shear Tests -- 5.4 Ring Shear Tests -- 5.5 Cyclic Simple Shear Tests -- 5.6 Cyclic Triaxial Tests -- 6 Correlations Methods to Obtain Soil Shear Strengths -- 6.1 Fully Softened Shear Strength -- 6.2 Residual Shear Strength -- 6.3 Undrained Shear Strengths of Over-Consolidated Clays -- 6.4 Cyclic Shear Strength -- 6.5 Post-Cyclic Undrained Shear Strength -- 6.6 Various Other Correlations -- 7 Example of Shear Strength Estimation with Correlation Methods -- 8 Summary and Recommendations -- References -- Rock Avalanches in the Tibetan Plateau of China -- 1 Introduction -- 2 Geological Setting of the Studied Area -- 3 Distribution of Rock Avalanches in the Study Area -- 3.1 Spatial Distribution of Rock Avalanches in the Himalayan Range, China. , 3.2 Locations of the Typical Rock Avalanches -- 4 Characteristics of Typical Rock Avalanche Deposits -- 4.1 Luanshibao Rock Avalanche -- 4.1.1 Geological Setting and General Features of the Luanshibao Rock Avalanche -- 4.1.2 Sedimentary Features of the Avalanche Deposit -- 4.2 Nyixoi Chongco Rock Avalanche -- 4.2.1 Geological Setting and General Features of the Nyixoi Chongco Rock Avalanche -- 4.2.2 Sedimentary Features of the Avalanche Deposit -- 4.3 Tagarma Rock Avalanche -- 4.3.1 Geological Setting and General Features of the Tagarma Rock Avalanche -- 4.3.2 Sedimentary Features of the Avalanche Deposit -- 4.4 Iymek Rock Avalanche -- 4.4.1 Geological Setting and General Features of the Iymek Rock Avalanche -- 4.4.2 Sedimentary Features of the Avalanche Deposit -- 5 Discussion -- 6 Conclusion -- References -- Part II: Original Articles -- Landslide Susceptibility Zonation Using GIS-Based Frequency Ratio Approach in the Kulon Progo Mountains Area, Indonesia -- 1 Introduction -- 2 Research Area -- 3 Methodology -- 4 Dataset and Analysis -- 5 Result & -- Discussion -- 6 Conclusion -- References -- Physically-Based Regional Landslide Forecasting Modelling: Model Set-up and Validation -- 1 Introduction -- 2 HIRESSS Model and Study Are a -- 2.1 HIRESSS Model -- 2.2 Study Area -- 3 Data Collection and Preparation -- 3.1 Static Data -- 3.2 Dynamic Data -- 4 HIRESSS Simulation and Analysis of the Results -- 4.1 Monte Carlo Simulations -- 4.2 Analysis of the Model Output and Validation -- 5 Conclusion -- References -- Consequence: Frequency Matrix as a Tool to Assess Landslides Risk -- 1 Introduction -- 2 The Main Principle of Matrix Use -- 3 The Conceptual Background -- 4 Example of Risk Matrix -- 5 Issues Linked to the Use of Matrix -- 5.1 Scale and Verbal Terms -- 5.1.1 The Classes of Consequences and Frequency or Probability. , 5.2 Setting the Risk Limits for Risk Matrix and F-N Curves -- 5.3 Uncertainty -- 5.4 Risk Reduction -- 5.5 Representing the Cascading Effect -- 5.6 Adding Dimensions -- 5.7 Cumulative Versus Non-cumulative Scale -- 5.7.1 An Example Ambiguous Use of Matrix -- 6 Summaries of the Recommendations -- 7 Example of Integration of Assessment for all Classes -- 8 Method -- 8.1 The Belonging to a Class and its Uncertainty -- 8.2 Classes Definitions -- 8.3 The Expert Assessment for a Specific Event -- 8.4 The Matrix Construction -- 8.5 The Example of a Particular Unstable Mass of Pont Bourquin Landslide -- 8.5.1 Landslide Settings -- 8.5.2 The Classes and Scales -- 8.5.3 Setting the Prior Probabilities -- 8.5.4 Results -- 9 Discussion and Conclusion -- References -- Do not Let Your Guard Down: Landslide Exposure and Local Awareness in Mexico -- 1 Introduction -- 2 Landslide Exposure and Awareness -- 3 Studied Area -- 4 Methodology -- 4.1 Aerial Survey Using UAVs -- 4.2 Expansion of the Urban Area -- 4.3 Rainfall Series -- 5 Results -- 6 Concluding Remarks -- References -- Landslides in Higher Education Curricula and Beyond -- 1 Introduction -- 1.1 General Views on Higher Education -- 1.2 The Focus of this Article -- 2 Materials and Methods -- 3 Results and Discussion -- 3.1 Background Studies on Landslides and Study Programmes -- 3.2 Academic Programmes in Disaster Risk Management -- 3.3 University Study Programs in Disaster Risk Reduction & -- Management -- 3.4 Selected Summer Schools on Landslides -- 3.5 Landslide-Related Capacity Building Examples -- 3.6 Case 1: The International School on Landslide Risk Assessment and Mitigation (LARAM) -- 3.7 Case 2: Kokomerem Summer School on Rockslides and Related Phenomena in the Kokomeren River Valley (Kyrgyzstan) -- 3.8 Case 3: The International Research Association on Large Landslides (iRALL) School. , 3.9 Case 4: ICL Landslide School Network -- 3.10 Case 5: ICL Landslide Teaching Tools -- 3.11 Case 6: ICL/IPL World Report on Landslides -- 3.12 Case 7: UNDRR PreventionWeb Platform -- 3.13 Case 8: United States Geological Survey (USGS) Web Sources -- 3.14 Case 9: NASA Models and Datasets -- 3.15 Case 10: The Landslide Blog in AGU Blogosphere -- 3.16 Case 11: BeSafeNet Platform -- 3.17 Case 12: The International Society for Rock Mechanics and Rock Engineering (ISRM) Course -- 3.18 Case 13: The LARIMIT Portal -- 3.19 Case 14: Humanitarian Library -- 3.20 Case 15: The VISUS Methodology -- 3.21 Case 16: The Twinkl Platform -- 4 Conclusions -- References -- Community Scale Landslide Resilience: A Citizen-Science Approach -- 1 Introduction -- 2 Related Works -- 2.1 Review of the Existing Citizen Science Approach -- 3 Citizen Science Approach -- 3.1 Requirements, Solutions, and Dimension of Landslide Resilience -- 4 Operationalization of the Citizen-Science Approach -- 4.1 Framework: Involving Citizens in Building Community-Scale Landslide Resilience -- 4.2 Pre-Disaster Measures -- 4.3 During-Disaster Measures -- 4.4 Post-Disaster Measures -- 5 Tools for Operationalization -- 5.1 Community Engagement -- 5.2 Social Media Data Analysis -- 5.3 AmritaKripa Mobile App -- 5.4 Landslide Tracker Mobile App -- 6 Case Study: Implementation of Framework -- 7 Discussion -- 7.1 Practical Challenges & -- Implementation Gaps -- 8 Conclusion -- References -- Remedial Measures Impact on Slope Stability and Landslide Occurrence in Small-Scale Slope Physical Model in 1 g Conditions -- 1 Introduction -- 2 Material and Methods -- 2.1 Physical Model -- 2.2 Soil Material Properties -- 2.3 Monitoring Equipment -- 2.4 Rainfall Simulator -- 2.5 Remedial Structures -- 3 Construction of Slope Models -- 3.1 Construction of Slope Models without Remedial Measure. , 3.2 Construction of Slope Model with Installation of Gravity Wall -- 3.3 Construction of Slope Model with Installation of Gabion Wall -- 3.4 Construction of Slope Model with Installation of Pile Wall -- 4 Testing and Results -- 4.1 Testing of Slope Models without Remedial Measures -- 4.2 Testing of Slope Model with Gravity Retaining Wall -- 4.3 Testing of Slope Model with Gabion Wall -- 4.4 Testing of Slope Model with Pile Wall -- 5 Discussion and Conclusions -- References -- Surficial Geology and Geomorphology of the North Slide, Thompson River Valley, British Columbia, Canada: Application of Fundam... -- 1 Introduction -- 1.1 Generalized Climate and Hydrology at North Slide -- 1.2 Historical Change Detection at North Slide -- 1.3 Baseline Geological Conditions at the North Slide -- 2 Methods and Observational Results -- 2.1 Terrain and Hydrogeological Mapping -- 2.1.1 Benchmarked Satellite Image Interpretation -- 2.1.2 Benchmarked UAV Orthomosaic Interpretation -- 2.2 Field Observations of Earth Material Textures, Porosity Variations, and Slope Failure in Terrain Units -- 2.2.1 Bedrock and Undifferentiated Weathered Lag (Unit 1 -- R, R-R) -- 2.2.2 Glaciolacustrine Sediments (Unit 2 -- GLb) -- 2.2.3 Glaciofluvial and Ice-Contact Sediments (Unit 3 -- GFb) -- 2.2.4 Ground Moraine (Unit 4 -- Tv, Tb, Tb-V, Td) -- 2.2.5 Glaciolacustrine and Glaciofluvial Sediments (Unit 5 -- GLt, GFt) -- 2.2.6 Alluvial Sediments (Unit 6 -- Ap, at, Af) -- 2.2.7 Colluvial Sediments (Unit 7 -- Cv, Cz, Cz-F) -- 2.2.8 Anthropogenic Deposits (Unit 8 -- Hb) -- 3 Discussion: Fundamental Geoscience Applied to Geospatial Monitoring Results -- 3.1 Hydrogeological Controls on Ancient Landslide Activity -- 3.2 Hydrogeological Controls on Historical Landslide Activity -- 3.3 Hydrogeological Controls on Recent Landslide Activity. , 3.4 Projecting Future Landslide Activity and Consequences.

Weitere Ausg.: Print version: Alcántara-Ayala, Irasema Progress in Landslide Research and Technology, Volume 2 Issue 2 2023 Cham : Springer International Publishing AG,c2024 ISBN 9783031442957

Sprache: Englisch

Schlagwort(e): Electronic books.

URL: Click to View

UID:

Umfang: XV, 503 p. 415 illus., 402 illus. in color. , online resource.

Ausgabe: 1st ed. 2023.

ISBN: 9783031442964

Serie: Progress in Landslide Research and Technology,

Inhalt: This open access book provides an overview of the progress in landslide research and technology and is part of a book series of the International Consortium on Landslides (ICL). It gives an overview of recent progress in landslide research and technology for practical applications and the benefit for the society contributing to understanding and reducing landslide disaster risk. Prof. Irasema Alcántara-Ayala is a former Director and current Professor at the Institute of Geography of the National Autonomous University of Mexico (UNAM). She is a member of the UNDRR R-STAG of the Americas and an Editor of the ICL book series P-LRT. Prof. Željko Arbanas is the Vice President of the ICL for Europe. He is a professor at the Faculty of Engineering, University of Rijeka, Croatia. He is an Assistant Editor-in-Chief of the International Journal Landslides and the ICL book series P-LRT. Dr. David Huntley is Research Scientist with the Geological Survey of Canada and Open Learning Faculty at Thompson Rivers University, British Columbia. He is an Editor of the ICL book series P-LRT. Prof. Kazuo Konagai is a Professor Emeritus at the University of Tokyo and Principal Researcher of the ICL headquarters. He is an Assistant Editor-in-Chief of the ICL book series P-LRT. Prof. Snježana Mihalić Arbanas a Professor of the Faculty of Mining, Geology and Petroleum, University of Zagreb in Croatia. She is the Chair of ICL Network Committee. Matjaž Mikoš, Professor at the Faculty of Civil and Geodetic Engineering, University of Ljubljana, Slovenia, is the Chairman of the Global Promotion Committee of the International Programme on Landslides and Kyoto Landslide Commitment 2020. Dr. Maneesha Vinodini Ramesh is the Provost of Amrita Vishwa Vidyapeetham, Dean, School for Sustainable Development, Director, AMRITA Center for Wireless Networks & Applications, Amrita Vishwa Vidyapeetham, India. She is an Editor of the ICL book series P-LRT. Prof. Kyoji Sassa is the Founding President and the Secretary General of the ICL and the Secretary General of the Kyoto Landslide Commitment 2020. He is the Editor-in-Chief of the International Journal Landslides and the ICL book series P-LRT. Dr. Shinji Sassa is the Head of Soil Dynamics Group and Research Director at Port and Airport Research Institute, National Institute of Maritime, Port and Aviation Technology, Japan. He is an Editor of the International Journal Landslides and the ICL book series P-LRT. Prof. Huiming Tang is the Vice President of China University of Geosciences (Wuhan) and a Chief Professor at the Faculty of Engineering. He is a full member of ICL, Chairman of the Engineering Geology commission of China and Vice President of IAEG. Prof. Binod Tiwari is the Vice President of the ICL for America. He is a professor of civil and environment engineering at the California State University, Fullerton California, USA. He is an Assistant Editor-in-Chief of the ICL book series P-LRT.

Anmerkung: Part I: ICL Landslide Lesson -- Advancements in shear strength interpretation, testing, and use for landslide analysis -- Rock Avalanches in the Tibet Plateau of China -- Part II: Original articles -- Landslide Susceptibility Zonation Using GIS-based Frequency Ratio Approach in the Kulon Progo Mountains Area, Indonesia -- Physically-based regional landslide forecasting modelling: model set-up and validation -- Consequence - frequency matrix as a tool to assess landslides risk -- Do not let your guard down: landslide exposure and local awareness in Mexico -- Landslides in Higher Education Curricula and Beyond -- Community Scale Landslide Resilience: A citizen-science approach -- Remedial Measures Impact on Slope Stability and Landslide Occurrence in Small-Scale Slope Physical Model in 1g Conditions -- Surficial geology and geomorphology of the North Slide, Thompson River valley, British Columbia: application of fundamental geoscience information to interpretations of geospatial monitoring results -- High Resolution Numerical Weather Simulation for Orographic Precipitation as an Accurate Early Warning Tool for Landslide Vulnerable Terrains -- Climate Change as Modifier of Landslide Susceptibility: Case Study in Davao Oriental, Philippines -- Fractal-based evaluation of the spatial relationship between conditioning factors and the distribution of landslides (A case study in Tinh Tuc, Cao Bang province, Vietnam) -- Procedure of Data Processing for the Improvement of Failure Time of a Landslide Based on the Velocity and Acceleration of the Displacement -- Numerical analysis of the effect of rainfall on the stability of sandstone-covered mudstone cutting slopes -- Part III: Review articles -- Post-formation behaviour of Hattian Landslide Dam and post-breaching situation -- Investigation of debris flow impact mechanisms and designs -- A review of the disaster risk assessment perspectives -- Part IV: IPL/WCOE/KLC2020 -- Application of LAND-SUITE for landslide susceptibility modelling using different mapping units. A case study in Croatia -- An Integrated approach to landslides risk management for local and national authorities -- Assessing landslide hazard in the High City of Antananarivo, Madagascar (UNESCO Tentative site) -- Part V: ICL Landslide Teaching Tools -- Teaching Tools for LS-Tsnnamis -- Part VI: Technical Notes and Case Studies -- CliRtheRoads - An integrated approach to landslide risk management on roads in Serbia -- Part VII: World Landslide Reports -- Rock slope instabilities affecting the AlUla archaeological sites (KSA) -- Refugees' perception of landslide disasters: Insights from the Rohingya camps in Cox's Bazar, Bangladesh.

In: Springer Nature eBook

Weitere Ausg.: Printed edition: ISBN 9783031442957

Weitere Ausg.: Printed edition: ISBN 9783031442971

Weitere Ausg.: Printed edition: ISBN 9783031442988

Sprache: Englisch

DOI: 10.1007/978-3-031-44296-4

URL: https://doi.org/10.1007/978-3-031-44296-4

UID:

Umfang: 1 Online-Ressource(XV, 503 p. 415 illus., 402 illus. in color.)

Ausgabe: 1st ed. 2023.

ISBN: 9783031442964

Serie: Progress in Landslide Research and Technology

Inhalt: Part I: ICL Landslide Lesson -- Advancements in shear strength interpretation, testing, and use for landslide analysis -- Rock Avalanches in the Tibet Plateau of China -- Part II: Original articles -- Landslide Susceptibility Zonation Using GIS-based Frequency Ratio Approach in the Kulon Progo Mountains Area, Indonesia -- Physically-based regional landslide forecasting modelling: model set-up and validation -- Consequence - frequency matrix as a tool to assess landslides risk -- Do not let your guard down: landslide exposure and local awareness in Mexico -- Landslides in Higher Education Curricula and Beyond -- Community Scale Landslide Resilience: A citizen-science approach -- Remedial Measures Impact on Slope Stability and Landslide Occurrence in Small-Scale Slope Physical Model in 1g Conditions -- Surficial geology and geomorphology of the North Slide, Thompson River valley, British Columbia: application of fundamental geoscience information to interpretations of geospatial monitoring results -- High Resolution Numerical Weather Simulation for Orographic Precipitation as an Accurate Early Warning Tool for Landslide Vulnerable Terrains -- Climate Change as Modifier of Landslide Susceptibility: Case Study in Davao Oriental, Philippines -- Fractal-based evaluation of the spatial relationship between conditioning factors and the distribution of landslides (A case study in Tinh Tuc, Cao Bang province, Vietnam) -- Procedure of Data Processing for the Improvement of Failure Time of a Landslide Based on the Velocity and Acceleration of the Displacement -- Numerical analysis of the effect of rainfall on the stability of sandstone-covered mudstone cutting slopes -- Part III: Review articles -- Post-formation behaviour of Hattian Landslide Dam and post-breaching situation -- Investigation of debris flow impact mechanisms and designs -- A review of the disaster risk assessment perspectives -- Part IV: IPL/WCOE/KLC2020 -- Application of LAND-SUITE for landslide susceptibility modelling using different mapping units. A case study in Croatia -- An Integrated approach to landslides risk management for local and national authorities -- Assessing landslide hazard in the High City of Antananarivo, Madagascar (UNESCO Tentative site) -- Part V: ICL Landslide Teaching Tools -- Teaching Tools for LS-Tsnnamis -- Part VI: Technical Notes and Case Studies -- CliRtheRoads – An integrated approach to landslide risk management on roads in Serbia -- Part VII: World Landslide Reports -- Rock slope instabilities affecting the AlUla archaeological sites (KSA) -- Refugees’ perception of landslide disasters: Insights from the Rohingya camps in Cox’s Bazar, Bangladesh.

Inhalt: This open access book provides an overview of the progress in landslide research and technology and is part of a book series of the International Consortium on Landslides (ICL). It gives an overview of recent progress in landslide research and technology for practical applications and the benefit for the society contributing to understanding and reducing landslide disaster risk. Prof. Irasema Alcántara-Ayala is a former Director and current Professor at the Institute of Geography of the National Autonomous University of Mexico (UNAM). She is a member of the UNDRR R-STAG of the Americas and an Editor of the ICL book series P-LRT. Prof. Željko Arbanas is the Vice President of the ICL for Europe. He is a professor at the Faculty of Engineering, University of Rijeka, Croatia. He is an Assistant Editor-in-Chief of the International Journal Landslides and the ICL book series P-LRT. Dr. David Huntley is Research Scientist with the Geological Survey of Canada and Open Learning Faculty at Thompson Rivers University, British Columbia. He is an Editor of the ICL book series P-LRT. Prof. Kazuo Konagai is a Professor Emeritus at the University of Tokyo and Principal Researcher of the ICL headquarters. He is an Assistant Editor-in-Chief of the ICL book series P-LRT. Prof. Snježana Mihalić Arbanas a Professor of the Faculty of Mining, Geology and Petroleum, University of Zagreb in Croatia. She is the Chair of ICL Network Committee. Matjaž Mikoš, Professor at the Faculty of Civil and Geodetic Engineering, University of Ljubljana, Slovenia, is the Chairman of the Global Promotion Committee of the International Programme on Landslides and Kyoto Landslide Commitment 2020. Dr. Maneesha Vinodini Ramesh is the Provost of Amrita Vishwa Vidyapeetham, Dean, School for Sustainable Development, Director, AMRITA Center for Wireless Networks & Applications, Amrita Vishwa Vidyapeetham, India. She is an Editor of the ICL book series P-LRT. Prof. Kyoji Sassa is the Founding President and the Secretary General of the ICL and the Secretary General of the Kyoto Landslide Commitment 2020. He is the Editor-in-Chief of the International Journal Landslides and the ICL book series P-LRT. Dr. Shinji Sassa is the Head of Soil Dynamics Group and Research Director at Port and Airport Research Institute, National Institute of Maritime, Port and Aviation Technology, Japan. He is an Editor of the International Journal Landslides and the ICL book series P-LRT. Prof. Huiming Tang is the Vice President of China University of Geosciences (Wuhan) and a Chief Professor at the Faculty of Engineering. He is a full member of ICL, Chairman of the Engineering Geology commission of China and Vice President of IAEG. Prof. Binod Tiwari is the Vice President of the ICL for America. He is a professor of civil and environment engineering at the California State University, Fullerton California, USA. He is an Assistant Editor-in-Chief of the ICL book series P-LRT.

Anmerkung: Open Access

Weitere Ausg.: ISBN 9783031442957

Weitere Ausg.: ISBN 9783031442971

Weitere Ausg.: ISBN 9783031442988

Weitere Ausg.: Erscheint auch als Druck-Ausgabe ISBN 9783031442957

Weitere Ausg.: Erscheint auch als Druck-Ausgabe ISBN 9783031442971

Weitere Ausg.: Erscheint auch als Druck-Ausgabe ISBN 9783031442988

Sprache: Englisch

Schlagwort(e): Erdrutsch ; Geotechnik ; Starkregen ; Hang ; Böschung ; Rutschung ; Naturkatastrophe ; Ingenieurgeologie ; Bodenmechanik ; Gebirgsmechanik ; Geotextilien ; Lockergestein ; Naturgefahr ; Bergsturz ; Felssturz ; Massenbewegung ; Prognose ; Aufsatzsammlung

DOI: 10.1007/978-3-031-44296-4

URL: kostenfrei