Investigation, monitoring, stability and risk assessment of Geohazards are fundamental areas of study within the field of engineering geology. Multi-scale study on indoor experiments of geohazards encompasses the investigation of soil and rock behavior under various loading or unloading conditions, while stability and risk of geohazards focuses on the assessment and mitigation of risks associated with unstable slopes. Investigation and monitoring of geohazards mainly emphasize the early identification, stability evaluation, prediction, warning, and prevention of geohazards. In recent years, there has been growing recognition of the importance of enhancing basic theory of geohazards.
Advances in experimental, analytical, and numerical techniques for characterizing and modeling geohazard evolution mechanism in this field are necessary. The issue seeks articles that address innovative approaches for analyzing slope stability, predicting failure mechanisms, designing effective stabilization measures, and assessing landslides risk. Additionally, we encourage research that explores various engineering geological problems throughout the entire lifecycle of geohazards, such as new protective materials for geohazards, eco-friendly slope stabilization methods, geotechnical aspects of renewable energy projects, or life cycle assessment of geotechnical works. The goal of this special issue is to provide a platform for researchers and practitioners to share their experiences, knowledge, and research outcomes in geomechanics, slope stability, and geohazards.
In this Research Topic, original research articles and reviews are welcome. Research areas may include (but not limited to) the following:
• Mechanical Property of Rock Mass/Soil Mass of Landslide.
• Analytical, Physical and Numerical Techniques in Slope Stability.
• Physical Model Testing and Numerical Simulation.
• Landslide Evolution Mechanism.
• Artificial Intelligence for Geohazards.
• Advances in Sensors and Monitoring Techniques for Geohazards.
• Landslide Multi-source Remote Sensing Identification.
• Landslide Susceptibility Mapping.
• Stability of Rock Mass Surrounding Tunnel.
• Reliability Analysis of Geohazards.
• New Protective Materials for Geohazards.
• Risk Assessment and Hazard Evaluation.
• Causes and Physical Processes of Geohazards.
• Engineering Records of Geohazard Events.
• Monitoring, Forecast and Early Warning Technologies and Methods for Geohazards.
• Prevention and Control Technologies and Methods for Geohazards.
• Big data and Artificial Intelligence Technologies for Geohazard Prevention and Mitigation.
Investigation, monitoring, stability and risk assessment of Geohazards are fundamental areas of study within the field of engineering geology. Multi-scale study on indoor experiments of geohazards encompasses the investigation of soil and rock behavior under various loading or unloading conditions, while stability and risk of geohazards focuses on the assessment and mitigation of risks associated with unstable slopes. Investigation and monitoring of geohazards mainly emphasize the early identification, stability evaluation, prediction, warning, and prevention of geohazards. In recent years, there has been growing recognition of the importance of enhancing basic theory of geohazards.
Advances in experimental, analytical, and numerical techniques for characterizing and modeling geohazard evolution mechanism in this field are necessary. The issue seeks articles that address innovative approaches for analyzing slope stability, predicting failure mechanisms, designing effective stabilization measures, and assessing landslides risk. Additionally, we encourage research that explores various engineering geological problems throughout the entire lifecycle of geohazards, such as new protective materials for geohazards, eco-friendly slope stabilization methods, geotechnical aspects of renewable energy projects, or life cycle assessment of geotechnical works. The goal of this special issue is to provide a platform for researchers and practitioners to share their experiences, knowledge, and research outcomes in geomechanics, slope stability, and geohazards.
In this Research Topic, original research articles and reviews are welcome. Research areas may include (but not limited to) the following:
• Mechanical Property of Rock Mass/Soil Mass of Landslide.
• Analytical, Physical and Numerical Techniques in Slope Stability.
• Physical Model Testing and Numerical Simulation.
• Landslide Evolution Mechanism.
• Artificial Intelligence for Geohazards.
• Advances in Sensors and Monitoring Techniques for Geohazards.
• Landslide Multi-source Remote Sensing Identification.
• Landslide Susceptibility Mapping.
• Stability of Rock Mass Surrounding Tunnel.
• Reliability Analysis of Geohazards.
• New Protective Materials for Geohazards.
• Risk Assessment and Hazard Evaluation.
• Causes and Physical Processes of Geohazards.
• Engineering Records of Geohazard Events.
• Monitoring, Forecast and Early Warning Technologies and Methods for Geohazards.
• Prevention and Control Technologies and Methods for Geohazards.
• Big data and Artificial Intelligence Technologies for Geohazard Prevention and Mitigation.