Book contents
- Frontmatter
- Contents
- Preface
- Preface to the Second Edition
- ONE Plate Tectonics
- TWO Stress and Strain in Solids
- THREE Elasticity and Flexure
- FOUR Heat Transfer
- FIVE Gravity
- SIX Fluid Mechanics
- SEVEN Rock Rheology
- EIGHT Faulting
- NINE Flows in Porous Media
- TEN Chemical Geodynamics
- APPENDIX ONE Symbols and Units
- APPENDIX TWO Physical Constants and Properties
- Answers to Selected Problems
- Index
THREE - Elasticity and Flexure
- Frontmatter
- Contents
- Preface
- Preface to the Second Edition
- ONE Plate Tectonics
- TWO Stress and Strain in Solids
- THREE Elasticity and Flexure
- FOUR Heat Transfer
- FIVE Gravity
- SIX Fluid Mechanics
- SEVEN Rock Rheology
- EIGHT Faulting
- NINE Flows in Porous Media
- TEN Chemical Geodynamics
- APPENDIX ONE Symbols and Units
- APPENDIX TWO Physical Constants and Properties
- Answers to Selected Problems
- Index
Summary
Introduction
In the previous chapter we introduced the concepts of stress and strain. For many solids it is appropriate to relate stress to strain through the laws of elasticity. Elastic materials deform when a force is applied and return to their original shape when the force is removed. Almost all solid materials, including essentially all rocks at relatively low temperatures and pressures, behave elastically when the applied forces are not too large. In addition, the elastic strain of many rocks is linearly proportional to the applied stress. The equations of linear elasticity are greatly simplified if the material is isotropic, that is, if its elastic properties are independent of direction. Although some metamorphic rocks with strong foliations are not strictly isotropic, the isotropic approximation is usually satisfactory for the earth's crust and mantle.
At high stress levels, or at temperatures that are a significant fraction of the rock solidus, deviations from elastic behavior occur. At low temperatures and confining pressures, rocks are brittle solids, and large deviatoric stresses cause fracture. As rocks are buried more deeply in the earth, they are subjected to increasingly large confining pressures due to the increasing weight of the overburden. When the confining pressure on the rock approaches its brittle failure strength, it deforms plastically. Plastic deformation is a continuous, irreversible deformation without fracture. If the applied force causing plastic deformation is removed, some fraction of the deformation remains. We consider plastic deformation in Section 7–11.
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- Geodynamics , pp. 105 - 131Publisher: Cambridge University PressPrint publication year: 2002
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