Plate Tectonics

1. Plate Tectonics Chapter 8

2. What Is Plate Tectonics? • The Earth’s crust and upper mantle are broken into sections called plates • Plates move around on top of the asthenosphere like rafts and support both continents and oceans • Plate tectonics is a theory that describes the formation, movements, and interactions of plates

3. Plate Tectonics

4. The Theory of Continental Drift

5. Continental Drift Theory • Proposed by Alfred Wegener (German scientist) in 1912 • 250 million years ago, all of the continents were combined into one super-continent called “Pangaea” • The continents gradually drifted apart to where they are today

6. Evidence to Support the Theory

7. “Puzzle Pieces” • Continents look like they could be part of a giant jigsaw puzzle

8. Distribution of Fossils • Plant and animal fossils found on the coastlines of different continents

9. Sequence of Rocks • Same rock patterns found in South America, India, Africa, Antarctica and Australia

10. Ancient Climates • Tropical plant remains (coal deposits) found in Antarctica • Glaciation in Africa, South America, India, and Australia during the same time

11. Problems With The Theory • Wegener couldn’t explain how continents moved • Wind and currents could possibly move fossils • Theory was not accepted by scientists

12. The Theory of Plate Tectonics • Recall: continents are embedded in lithospheric plates. As the plates move they carry continents and oceans with them • Discoveries in the 1950s & 1960s added some support to Wegener’s ideas: • Earthquakes • Magnetism • Age of rocks on the ocean floor

13. Location of Earthquakes and Volcanoes • Earthquakes and volcanoes do not occur randomly – instead in concentrated belts • Belts mark plate boundaries • Boundaries are where 2 plates are pushing toward, pulling away, or sliding past each other • Strain builds up along plate boundaries and can cause fractures to occur leading to an earthquake • Boundaries are also areas of high heat flow  molten rock moves upward to the surface causing volcanic activity

14. Magnetism and the Age of the Ocean Floor • Some igneous rocks contain minerals that are magnetic  provide a record of the direction of Earth’s magnetic field at the time when molten matter that formed the rock cooled • One important discovery made by scientists studying these rocks: • Some rocks recorded reversals in the direction of Earth’s magnetic field (north become south and south became north) • A number of magnetic reversals have taken place over millions of years

15. Magnetism and Age of the Ocean Floor • Igneous rocks on the sides of mid-ocean ridges • Mid-ocean ridge: long chain of volcanic mountains on the ocean floor with a deep central valley • Discovery: • Bands of rocks on both sides of a mid-ocean ridge record periods of magnetic reversals • Rocks at the center of the mid-ocean ridge are the youngest and the rocks are older as you move farther from the ridge

16. Magnetism and Age of the Ocean Floor • Conclusion: • Mid-ocean ridges represent boundaries where plates are moving APART • Why? • The newer rock along the ridge are formed by hot, molten rock rising between spreading plates • As the new rock forms, older rock moves away from the ridge on either side

17. Types of Plate Boundaries • Divergent • Convergent • Transform

18. Divergent Boundary • Plates are moving apart • Creates rift valleys • Deep valleys at the center of a mid-ocean ridge

21. Features of Divergent Boundaries • Mid-ocean ridges • rift valleys • Volcanic activity • Earthquakes at mid-ocean ridges

22. Convergent Boundary • Two plates are moving toward each other • 2 Types: • Subduction boundaries • Collision boundaries

23. Subduction Boundary • Oceanic plate plunges beneath another plate: the oceanic plate is said to be subducting beneath the overriding plate • Important feature: deep-sea trench (deepest part of the ocean floor) • Subduction boundaries can be: • 2 oceanic plates colliding OR • Oceanic plate colliding with a continental plate

24. Two Oceanic Plates Colliding • Creates an island arc and a trench • Example: Japan

25. Aleutian Islands, Alaska

26. Oceanic Plate Colliding with a Continental Plate • Oceanic plates = denser than continental plate and subduct under the continental plate • Forms a volcanic mountain range and trench • Example: Cascade and Andes Mountains

27. Andes Mountains, South America

28. Collision Boundaries • Two continents collide and a re welded into a single, larger continent • Forms a folded mountain range • Example: Himalayas, Alps and Appalachian Mountains

29. Transform Boundaries • Boundary where two plates slide past each other • Forms fault lines and causes earthquake activity • Example: San Andreas Fault Line (California)

30. San Andreas Fault, CA

31. Causes of Plate Movement • There are 3 hypotheses: • Mantle Convection • Ridge Push • Slab Pull

32. Mantle Convection • Mantle may be moving plates along with it as it convects

33. How it Happens… • Hot magma in the Earth moves toward the surface, cools, then sinks again. • Creates convection currents beneath the plates that cause the plates to move.

34. The Problem With It… • Model does not account for the enormous force needed to move the plates

35. Ridge Pull • Recall what happens at a mid-ocean ridge • Molten magma rises at a mid-ocean ridge • The magma cools and forms rock • New rock closest to the ridge is less dense and more buoyant because rock is very hot but as it cools and ages it becomes more dense • Gravity causes the older, denser rock to slide away from the ridge • As the rock slides away, new molten magma wells up at the mid-ocean ridge • The cooling, subsiding rock exerts a force on spreading plates that could help drive their movement

36. Slab Pull • At a subduction boundary, one plate is denser and heavier than the other plate • The edge of the subducting plate is much colder and heavier than the mantle, so it continues to sink, pulling the rest of the plate with it • The force produced is called slab pull • Currently: scientists find this explanation to be the strongest in driving plate movement