Lecture

Lecture - 31 Plate Tectonics - 2 and Earthquake

This module continues the study of plate tectonics, focusing on the relationship between tectonic activity and earthquakes. Students will analyze seismic data and learn about earthquake prediction and risk assessment.


Course Lectures
  • This module introduces the fundamental concepts of Engineering Geology, outlining its significance in engineering practices. Students will explore the historical context and evolution of the discipline, understanding how geological principles influence engineering decisions.

  • In this module, students will learn about geologic structures, including folds, faults, and joints. Understanding these structures is crucial for assessing stability and risk in engineering projects, particularly in areas prone to seismic activity.

  • This module covers geologic maps and stratigraphic sections, teaching students how to interpret these essential tools. Geologic mapping is integral for site investigations and understanding subsurface geology.

  • Remote sensing techniques such as LIDAR and SAR are explored in this module. Students will learn how to utilize these technologies for mapping and analyzing geological features, enhancing their understanding of engineering site assessments.

  • This module delves into the physical properties of minerals, including their identification and classification. Students will learn the significance of these properties in engineering applications, emphasizing the importance of minerals in construction materials.

  • The principles of crystallography and optical properties of minerals are introduced in this module. Students will learn to identify minerals using optical techniques, which is crucial for assessing material quality in engineering projects.

  • This module focuses on the chemical characteristics of minerals, emphasizing their composition and behavior under various conditions. Understanding these characteristics is vital for predicting material performance in engineering applications.

  • The origin and types of rocks are discussed in this module. Students will explore igneous, sedimentary, and metamorphic rocks, learning about their formation processes and classification, which is essential for site evaluation in engineering projects.

  • This module examines the origin and types of soils, focusing on their formation, classification, and engineering significance. Understanding soil properties is critical for construction and land use planning.

  • Lecture - 10 Igneous Rocks
    Dr. Debasis Roy

    Students will learn about igneous rocks, including their formation processes, classification, and significance in engineering geology. Understanding the properties of these rocks is vital for construction and infrastructure development.

  • This module focuses on sedimentary rocks, exploring their formation environments and textural classifications. Students will understand the importance of sedimentary rocks in the context of engineering and resource extraction.

  • Metamorphic rocks are the focus of this module, covering their formation processes and structures. Understanding metamorphism is crucial for assessing material properties in engineering applications, particularly in construction.

  • Lecture - 13 Weathering
    Dr. Debasis Roy

    This module introduces weathering processes, examining their effects on soil and rock formation. Students will learn to evaluate how weathering influences engineering projects and landscape stability.

  • Students will explore sediment transport and deposition processes in this module, learning how these processes shape geological features and their implications for engineering design and construction.

  • This module provides an introduction to subsurface exploration techniques. Students will learn about intrusive and non-intrusive methods used in site investigations to assess geological conditions for engineering projects.

  • Continuing the exploration of subsurface investigation, this module emphasizes drilling, sampling, and geophysical methods. Students will learn how to collect and analyze data essential for understanding subsurface conditions.

  • This module focuses on sampling and non-intrusive methods for assessing subsurface conditions. Students will learn how these techniques contribute to effective site evaluation and hazard assessment in engineering.

  • Index properties and classification of soils are the focus of this module. Students will learn how these properties affect engineering performance and their relevance to construction and design.

  • This module examines the index properties of rock and rock mass, emphasizing their importance in engineering assessments. Understanding these properties is crucial for material selection and structural design.

  • Students will explore the stress-strain behavior of soil and rock in this module. Concepts such as Mohr’s Circle and effective stress are introduced, which are essential for understanding material behavior under load.

  • This module continues the examination of stress-strain behavior, providing deeper insights into failure mechanisms in soil and rock. Students will analyze factors contributing to material failure under various conditions.

  • In this module, students will learn about in-situ state of stress and its implications for engineering design. Understanding in-situ stresses is crucial for evaluating site conditions and ensuring structural integrity.

  • This module addresses geological considerations in tunneling projects. Students will learn to assess geological conditions, select appropriate methods, and understand challenges faced during tunnel construction.

  • Students will explore geological considerations in dam construction, focusing on site selection, geological stability, and material characteristics. This knowledge is essential for ensuring the safety and longevity of dam structures.

  • This module introduces groundwater concepts, including sources, aquifers, and hydraulic conductivity. Students will learn how groundwater dynamics affect engineering projects and land use planning, emphasizing the importance of sustainable management.

  • Groundwater flow principles are explored in this module, highlighting Darcy’s Law and its applications in engineering. Students will learn to analyze groundwater flow patterns and their implications for construction and resource management.

  • This module continues the discussion on groundwater flow, focusing on advanced concepts and case studies. Students will apply their knowledge to real-world scenarios, enhancing their problem-solving skills in hydrology.

  • Groundwater-related engineering issues are examined in this module. Topics include groundwater contamination, resource depletion, and management strategies essential for sustainable engineering practices.

  • This module addresses groundwater over-utilization and its consequences for the environment and engineering practices. Students will learn about mitigation strategies and the importance of sustainable water management.

  • Students will explore plate tectonics in this module, learning about the movement of tectonic plates and its implications for geological hazards, including earthquakes and volcanic activity.

  • This module continues the study of plate tectonics, focusing on the relationship between tectonic activity and earthquakes. Students will analyze seismic data and learn about earthquake prediction and risk assessment.

  • In this module, students will learn about earthquake hazard assessment methods. The focus will be on evaluating risks and developing mitigation strategies to enhance resilience in engineering projects.

  • This module covers geological hazards, including seismicity and volcanism. Students will learn how these hazards affect infrastructure and the importance of geological studies for hazard mitigation.

  • Students will learn about shoreline processes in this module, including erosion and deposition. Understanding these processes is crucial for coastal engineering projects and managing coastal hazards.

  • This module continues the exploration of shoreline processes, focusing on their implications for coastal management. Students will learn about strategies for mitigating coastal hazards and preserving coastal ecosystems.

  • This module examines landslide hazards, discussing causes, classifications, and stability assessments for slopes. Students will learn to evaluate landslide risks and develop mitigation plans for engineering projects.

  • This module addresses subsidence and collapsible soils. Students will explore the effects of subsidence on structures and the importance of evaluating soil conditions during site investigations.

  • In this module, students will learn to prepare geologic sections. This skill is vital for visualizing subsurface conditions and is commonly used in engineering reports and site evaluations.

  • This module focuses on index testing of soil and rocks. Students will learn various testing methods to determine material properties essential for engineering design and construction.

  • In this module, students will learn how to identify minerals and rock samples. Mastery of identification techniques is essential for assessing material suitability for engineering projects.