This book discusses the impact of climate change, land use and land cover, and socio-economic dynamics on landslides in Asian countries. Scholars recently have brought about a shift in their focus regarding triggering factors for landslides, from rainfall or earthquake to claiming rapid urbanization, extreme population pressure, improper land use planning, illegal hill cutting for settlements and indiscriminate deforestation. This suggests that the occurrence or probabilities of landslides are shaped by both climate-related and non-climate-related anthropogenic factors. Among these issues, land use and land cover change or improper land use planning is one of the key factors. Further climate change shapes the rainfall pattern and intensity in different parts of the world, and consequently rainfall-triggered landslides have increased. These changes cause socio-economic changes. Conversely, socio-economic and lifestyle changes enhance inappropriate land use and climate change. All these changes in land use, climate and socio-economic aspects are dynamics in nature and shape landslide risks in Asian countries, where they are given serious attention by governments, disaster management professionals, researchers and academicians.
This book comprises 21 chapters divided into three major sections highlighting the effect of climate change on landslide incidence with the influence on vegetation and socio-economic aspects. The sections address how climate change and extreme events have triggered landslides. The advances in geospatial techniques with the focus on land use and land cover change along with the effect on socio-economic aspects are also explored.
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Part I Climate Change and Extreme Events On Landslide |
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1 Association of Climate Change to Landslide Vulnerability and Occurrences in Bhutan |
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3 | (36) |
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2 A Framework for Assessing Landslide Risk in Hilly Terrains |
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39 | (26) |
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3 Landslide Dam Outburst in Myagdi, Nepal: Early Warning and Preparedness Key to Minimizing Disaster |
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65 | (18) |
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4 Landslide Risk Along the Sichuan-Tibetan Railway |
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83 | (40) |
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5 Landslide, Agricultural Vulnerability, and Community Initiatives: A Case Study in South-East Part of Bangladesh |
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123 | (26) |
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Part II Advanced Geospatial Modelling On Land-Use and Land-Cover Change |
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6 Landslide, Land Cover, and Land use Changes and Its Impacts in Nepal |
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149 | (16) |
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7 Comparison Between Two Different Methods Applied to Define Rainfall Thresholds for Landslide Forecasting in Idukki District of Kerala, India |
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165 | (16) |
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8 Prediction of Amount of Rainfall on Landslide day Using Artificial Neural Network for Bhutan |
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181 | (16) |
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9 Measuring Landslide Susceptibility of Phuentsholling, Bhutan Using Novel Ensemble Machine Learning Methods |
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197 | (24) |
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10 Application of RBF and MLP Neural Networks Integrating with Rotation Forest in Modeling Landslide Susceptibility of Sampheling, Bhutan |
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221 | (26) |
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11 Use of Probabilistically Generated Scenario Earthquakes in Landslide Hazard Zonation: A Semi-qualitative Approach |
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247 | (28) |
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12 Predicting the Landslide Susceptibility Using Ensembles of Bagging with RF and REPTree in Logchina, Bhutan |
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275 | (26) |
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Part III Effect On Socio-Economic Aspects Due to Landslides |
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13 Assessing Social Vulnerability to Landslide Disasters in Chittagong City, Bangladesh |
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301 | (18) |
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14 The Vulnerability of Human Population to Landslide Disaster: A Case Study of Sikkim Himalayas |
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319 | (16) |
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15 Integration of Socioeconomic Dynamics and Communities' Resilience to Landslides in Swat Valley, Pakistan |
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335 | (36) |
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16 Refugee Camps at Landslide Risk: Studying Mitigation Measures |
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371 | (26) |
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17 Introducing Japanese Landslide Warning System to Sri Lanka: Analyzing the Social Differences for Successful Technology Transfer |
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397 | (16) |
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18 Land Cover Changes and Landslide Risk in Sri Lanka |
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413 | (22) |
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19 Urban-Rural Connectivity for Forest Management and Landslide Risk Reduction: Case of Japan |
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435 | (18) |
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20 Slope Stabilization Using Soil Nails, Practice and Construction Realities: A Case Study on the Construction of Soil Nailed Wall Along Phuentsholing-Thimphu Highway, Bhutan |
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453 | (18) |
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21 Cross-Cutting Issues in Landslide Hazard of Japan: Forest Management, Climate Change, Demographic Change and Aging Society |
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Prof. Raju Sarkar is a professor in the Department of Civil Engineering, Delhi Technological University (DTU). Prior to rejoining his parent organization, DTU, Prof. Sarkar was working as a professor in the Department of Civil Engineering and Architecture, College of Science and Technology, Royal University of Bhutan, Bhutan, under the Ministry of External Affairs, Government of India Deputation to Bhutan. During his tenure in Bhutan, he established the Research Centre for Disaster Risk Reduction and Community Development Studies and worked as founding coordinator and head of the research centre. Prof. Sarkar also worked as a team leader to start the new undergraduate programme in engineering geology in the Royal University of Bhutan. He has more than 23 years of teaching, research, consultancy and industrial experience. At present he is also the chair of the Commission on Education and Outreach and the co-chair of the Commission on Earthquake Hazard, Risk and Strong Ground Motion of the International Association of Seismology and Physics of the Earth's Interior (IASPEI) IUGG. He has vast experience of working in the Hindu-Kush Himalayas region both at government and community levels. He has published a number of original research articles in peer-reviewed journals as well as books, book chapters and proceedings of international societies. Prof. Sarkar has worked as principal investigator (PI), co-PI, and co-I in a number of research projects funded by the International Council for Science (ICSU), the Global Challenges Research Fund (GCRF-UK), the World Bank (WB), the Royal Astronomical Society (RAS-UK), the Druk Holding InvestmentRoyal Government of Bhutan (DHI), and the Ministry of Environment and ForestsGovernment of Assam (MoEF). He has a keen interest in geohazards risk management, landslides, seismology, geotechnical engineering, construction engineering, community resilience and other, allied fields of study.
Prof. Rajib Shaw, a Japanese national of Indian origin, is a professor in the Graduate School of Media and Governance in Keio Universitys Shonan Fujisawa Campus (SFC). Earlier, he was the executive director of the Integrated Research on Disaster Risk (IRDR), a decade-long research program co-sponsored by the International Council for Science (ICSU), the International Social Science Council (ISSC), and the United Nations International Strategy for Disaster Reduction (UNISDR). He is also a senior fellow of the Institute of Global Environmental Strategies (IGES) Japan, the chairperson of SEEDS Asia and the Church World Service (CWS) Japan, two Japanese NGOs. Previously, he served as a professor in the Graduate School of Global Environmental Studies of Kyoto University. His expertise includes community-based disaster risk management, climate change adaptation, urban risk management, and disaster and environmental education. Prof. Shaw is the chair of the United Nations Science Technology Advisory Group (STAG) for disaster risk reduction and also the co-chair of the Asia Science Technology Academic Advisory Group (ASTAAG). He has published more than 45 books and over 300 academic papers and book chapters and is an editor of a book series on disaster risk reduction published by Springer.
Prof. Biswajeet Pradhan is a distinguished professor and an internationally established scientist in the field of geospatial information systems (GIS), remote sensing and image processing, complex modelling/geo-computing, machine learning and soft-computing applications, natural hazards and environmental modelling. He is the founding director of the Centre for Advanced Modelling and Geospatial Information Systems (CAMGIS) at the Faculty of Engineering and IT, the University of Technology Sydney, Australia, where he is also a distinguished professor. He is listed as the Worlds Most Highly Cited Researcher by the Clarivate Analytics Report in 2016, 2017 and 2018as one of the worlds most influential minds. In 2018 and 2019, the award as World Class Professor was bestowed on him by the Ministry of Research, Technology and Higher Education, Indonesia. In 2011, he received his habilitation in remote sensing from the Dresden University of Technology, Germany. Since March 2015, he has served as the Humboldt Ambassador Scientist for the Alexander Von Humboldt Foundation, Germany. Dr. Pradhan is the recipient of the prestigious German Academic Exchange Research (DAAD) fellowship award. He has more than 18 years of teaching, research, consultancy and industrial experience. Of his more than 550 articles, over 450 have been published in science citation index (SCI/SCIE) technical journals. He has written 8 Books and 13 book chapters. He is a member of many international professional bodies such as the Committee of Space research (COSPAR), a senior member of IEEE and United Nations Outer Space Research Programme (UNOOSA), among many others. He sits as a board member of many national programmes in Southeast Asia. He is a regular reviewer for many international bodies such as the European Science Foundation, Dutch Research Council, Austrian Science Foundation, Research Council UK (RCUK), Swiss National Science Foundation, Belgian Remote Sensing Programme and many more. He is an associate editor and an editorial member of more than 8 ISI journals.
