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Chapter 7: Plate Tectonics Section 4: Deforming the Earth’s Crust

Chapter 7: Plate Tectonics Section 4: Deforming the Earth’s Crust. Chapter 7. Section 4 Deforming the Earth’s Crust. Deformation. Whether a material bends or breaks depends on how much stress is applied to the material. Stress is the amount of force per unit area on a given material.

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Chapter 7: Plate Tectonics Section 4: Deforming the Earth’s Crust

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  1. Chapter 7: Plate TectonicsSection 4: Deforming the Earth’s Crust

  2. Chapter 7 Section4 Deforming the Earth’s Crust Deformation • Whether a material bends or breaks depends on how much stressis applied to the material. • Stress is the amount of force per unit area on a given material. • Different things happen to rock when different types of stress are applied.

  3. Chapter 7 Section4 Deforming the Earth’s Crust Deformation, continued • The process by which the shape of a rock changes because of stress is called deformation. • Rock layers bend when stress is placed on them. • When enough stress is placed on rocks, they can reach their elastic limit and break.

  4. When a small amount of stress is placed on uncooked spaghetti, the spaghetti bends. Additional stress causes the spaghetti to break.

  5. Chapter 7 Section4 Deforming the Earth’s Crust Deformation, continued • The type of stress that occurs when an object is squeezed, such as when two tectonic plates collide, is called compression. • When compression occurs at a convergent boundary, large mountain ranges can form.

  6. Chapter 7 Section4 Deforming the Earth’s Crust Deformation, continued • Tensionis stress that occurs when forces act to stretch an object. • Tension occurs at divergent plate boundaries, such as mid-ocean ridges, when two tectonic plates pull away from each other.

  7. Chapter 7 Section4 Deforming the Earth’s Crust Folding • The bending of rock layers because of stress in the Earth’s crust is called folding. • Types of Folds:Depending on how rock layers deform, different types of folds are made.

  8. Chapter 7 Section4 Deforming the Earth’s Crust Folding, continued • Anticlines are upward-arching folds. • Synclines are downward, troughlike folds.

  9. Chapter 7 Section4 Deforming the Earth’s Crust Folding, continued • In amonocline,rock layers are folded so that both ends of the fold are horizontal.

  10. Chapter 7 Section4 Deforming the Earth’s Crust Faulting • Some rock layers break when stress is applied. The surface along which rocks break and slide past each other is called afault. • The blocks of crust on each side of the fault are calledfault blocks.

  11. Chapter 7 Section4 Deforming the Earth’s Crust Faulting, continued • When a fault is not vertical, its two sides are either a hanging wall or a footwall.

  12. Chapter 7 Section4 Deforming the Earth’s Crust Faulting, continued • The type of fault depends on how the hanging wall and footwall move in relationship to each other. • When a normal fault moves, it causes the hanging wall to move down relative to the footwall.

  13. Chapter 7 Section4 Deforming the Earth’s Crust Faulting, continued • When a reverse fault moves, it causes the hanging wall to move up relative to the footwall.

  14. The photo at left is a normal fault. The photo at right is a reverse fault.

  15. Chapter 7 Section4 Deforming the Earth’s Crust Faulting, continued • A third major type of fault is a strike-slip fault. These faults form when opposing forces cause rock to break and move horizontally.

  16. Chapter 7 Section4 Deforming the Earth’s Crust Plate Tectonics and Mountain Building • When tectonic plates collide, land features that start as folds and faults can eventually become large mountain ranges. • When tectonic plates undergo compressions or tension, they can form mountains in several ways.

  17. The Andes Mountains formed on the edge of the South American plate where it converges with the Nazca plate.

  18. Chapter 7 Section4 Deforming the Earth’s Crust Mountain Building, continued • FoldedMountains form when rock layers are squeezed together and pushed upward. • Fault-Block Mountains form when large blocks of the Earth’s crust drop down relative to other blocks. • Volcanic Mountains form when magma rises to the Earth’s surface and erupts.

  19. The Appalachian Mountains were once as tall as the Himalaya Mountains but have been worn down by hundreds of millions of years of weathering and erosion.

  20. When the crust is subjected to tension, the rock can break along a series of normal faults, which creates fault-block mountains.

  21. The Tetons formed as a result of tectonic forces that stretched the Earth’s crust and caused it to break in a series of normal faults.

  22. Chapter 7 Section4 Deforming the Earth’s Crust Uplift and Subsidence • Vertical movements in the crust are divided into two types—uplift and subsidence. • Uplift is the rising of regions of the Earth’s crust to higher elevations. • Subsidence is the sinking of regions of the Earth’s crust to lower elevations.

  23. Chapter 7 Section4 Deforming the Earth’s Crust Uplift and Subsidence, continued • Uplifting of Depressed Rocks: Uplift can occur when large areas of land risewithout deforming. • One way areas rise without deforming is process known as rebound. When the crust rebounds, it slowly springs backto its previous elevation.

  24. Chapter 7 Section4 Deforming the Earth’s Crust Uplift and Subsidence, continued • Subsidence of Cooler Rocks: Rocks that are hot take up more space than cooler rocks. • The lithosphere is relatively hot at mid-ocean ridges, but coolsas it moves farther from the ridge. • As it cools, the oceanic lithosphere takes up less volume and the ocean floor subsides.

  25. Chapter 7 Section4 Deforming the Earth’s Crust Uplift and Subsidence, continued • Tectonic Letdown: Subsidence can also occur when the lithosphere becomes stretchedin rift zones. • A rift zone is a set of deep cracks that forms between two tectonic plates that are pulling away from each other. • As tectonic plates pull apart, stress between the plates causes a series of faults to form along the rift zone.

  26. The East African Rift, from Ethiopia to Kenya, is part of a divergent boundary, but you can see how the crust has subsided relative to the blocks at the edge of the rift zone.

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