Integrated Framework for Structural Geology - Kinematics, Dynamics, and Rheology of Deformed Rocks

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Informationen zum Autor Steven Wojtal is Professor of Geoscience at Oberlin College in Oberlin, Ohio, United States. Tom Blenkinsop is Professor in Earth Science at Cardiff University, United Kingdom. Basil Tikoff is Professor of Geoscience at the University of Wisconsin-Madison, United States. Klappentext A modern and practice-oriented approach to structural geology An Integrated Framework for Structural Geology: Kinematics, Dynamics, and Rheology of Deformed Rocks builds a framework for structural geology from geometrical description, kinematic analysis, dynamic evolution, and rheological investigation of deformed rocks. The unique approach taken by the book is to integrate these principles of continuum mechanics with the description of rock microstructures and inferences about deformation mechanisms. Field, theoretical and laboratory approaches to structural geology are all considered, including the application of rock mechanics experiments to nature. Readers will also find: Three case studies that illustrate how the framework can be applied to deformation at different levels in the crust and in an applied structural geology context Hundreds of detailed, two-color illustrations of exceptional clarity, as well as many microstructural and field photographs The quantitative basis of structural geology delivered through clear mathematics Written for advanced undergraduate and graduate students in geology, An Integrated Framework for Structural Geology will also earn a place in the libraries of practicing geologists with an interest in a one-stop resource on structural geology. Zusammenfassung AN INTEGRATED FRAMEWORK FOR STRUCTURAL GEOLOGYA modern and practice-oriented approach to structural geologyAn Integrated Framework for Structural Geology: Kinematics, Dynamics, and Rheology of Deformed Rocks builds a framework for structural geology from geometrical description, kinematic analysis, dynamic evolution, and rheological investigation of deformed rocks. The unique approach taken by the book is to integrate these principles of continuum mechanics with the description of rock microstructures and inferences about deformation mechanisms. Field, theoretical and laboratory approaches to structural geology are all considered, including the application of rock mechanics experiments to nature.Readers will also find:* Three case studies that illustrate how the framework can be applied to deformation at different levels in the crust and in an applied structural geology context* Hundreds of detailed, two-color illustrations of exceptional clarity, as well as many microstructural and field photographs* The quantitative basis of structural geology delivered through clear mathematicsWritten for advanced undergraduate and graduate students in geology, An Integrated Framework for Structural Geology will also earn a place in the libraries of practicing geologists with an interest in a one-stop resource on structural geology. Inhaltsverzeichnis Acknowledgements xvii Website xix 1 A Framework for Structural Geology 1 1.1 Introduction 1 1.1.1 Deformation 1 1.1.2 Empirical vs. Theoretical Approaches 1 1.1.3 Continuum Mechanics and its Applicability to Structural Geology 6 1.1.4 How to use this Book 6 References 8 2 Structures Produced by Deformation 10 2.1 Geological Structures 10 2.1.1 Structural Fabrics 10 2.1.2 Folds and Boudinage 12 2.1.3 Fractures and Stylolites 15 2.1.4 Faults and Fault Zones 17 2.1.5 Shear Zones 22 2.2 Additional Considerations 25 3 Microstructures 26 3.1 Introduction 26 3.1.1 Overview 26 3.1.2 Framework 27 3.1.3 Imaging of Microstructures 27 3.2 Fractures 28 3.3 Fault Rocks 30 3.4 Overgrowths, Pressure Shadows and...

Inhaltsverzeichnis

Acknowledgements xvii
 
Website xix
 
1 A Framework for Structural Geology 1
 
1.1 Introduction 1
 
1.1.1 Deformation 1
 
1.1.2 Empirical vs. Theoretical Approaches 1
 
1.1.3 Continuum Mechanics and its Applicability to Structural Geology 6
 
1.1.4 How to use this Book 6
 
References 8
 
2 Structures Produced by Deformation 10
 
2.1 Geological Structures 10
 
2.1.1 Structural Fabrics 10
 
2.1.2 Folds and Boudinage 12
 
2.1.3 Fractures and Stylolites 15
 
2.1.4 Faults and Fault Zones 17
 
2.1.5 Shear Zones 22
 
2.2 Additional Considerations 25
 
3 Microstructures 26
 
3.1 Introduction 26
 
3.1.1 Overview 26
 
3.1.2 Framework 27
 
3.1.3 Imaging of Microstructures 27
 
3.2 Fractures 28
 
3.3 Fault Rocks 30
 
3.4 Overgrowths, Pressure Shadows and Fringes, and Veins 33
 
3.5 Indenting, Truncating and Interpenetrating Grain Contacts, Strain Caps, and Stylolites 37
 
3.6 Aligned Grain Boundaries, T Grain Boundaries, and Foam Texture 38
 
3.7 Undulose Extinction, Subgrains, Deformation and Kink Bands, Deformation Lamellae, Grain Boundary Bulges, and Core-and-Mantle Microstructure 40
 
3.8 Deformation Twins 43
 
3.9 Grain Shape Fabrics, Ribbon Grains, and Gneissic Banding 43
 
3.10 Porphyroblasts 47
 
3.11 Crystallographic Fabrics (Crystallographic Preferred Orientations) 49
 
3.12 Shear Sense Indicators, Mylonites, and Porphyroclasts 49
 
3.12.1 Asymmetric Pressure Shadows and Fringes 53
 
3.12.2 Foliation Obliquity and Curvature 55
 
3.12.3 SC, SC', and SCC' Fabrics 55
 
3.12.4 Porphyroclast Systems 56
 
3.12.5 Precautions with Shear Sense Determination 59
 
3.13 Collecting Oriented Samples and Relating Sample to Geographic Frames of Reference 60
 
References 65
 
4 Displacements 66
 
4.1 Overview 66
 
4.2 Chapter Organization 66
 
4A Displacements: Conceptual Foundation 67
 
4A.1 Specifying Displacements or Individual Particles 67
 
4A.1.1 Basic Ideas 67
 
4A.1.2 Geological Example 69
 
4A.2 Particle Paths and Velocities 70
 
4A.2.1 Particle Paths 70
 
4A.2.2 Velocities 71
 
4A.3 Displacements of Collections of Particles - Displacement Fields 74
 
4A.3.1 Displacement Fields 74
 
4A.3.2 Uniform vs. Nonuniform and Distributed vs. Discrete Displacement Fields 76
 
4A.3.3 Classes of Displacement Fields 77
 
4A.4 Components of Displacement Fields: Translation, Rotation, and Pure Strain 79
 
4A.5 Idealized, Two-Dimensional Displacement Fields 85
 
4A.5.1 Simple Shear 87
 
4A.5.2 Pure Shear 88
 
4A.6 Idealized, Three-Dimensional Displacement Fields 89
 
4A.7 Summary 90
 
4B Displacements: Comprehensive Treatment 90
 
4B.1 Specifying Displacements for Individual Particles 90
 
4B.1.1 Defining Vector Quantities 90
 
4B.1.2 Types of Vectors 92
 
4B.1.3 Relating Position and Displacement Vectors 94
 
4B.1.4 Characterizing Vector Quantities 95
 
4B.2 Particle Paths and Velocities 97
 
4B.2.1 Incremental Displacements for Particles 97
 
4B.2.2 Particle Paths and Movement Histories 98
 
4b.2.3 Dated Particle Paths, Instantaneous Movement Directions, and Velocities 99
 
4B.3 Displacements of Collections of Particles - Displacement Fields 101
 
4B.3.1 Concept of a Displacement Field 101
 
4B.3.2 Field Quantities 103
 
4b.3.3 Gradients of the Displacement Field: