1. Chapter 3
Plate Tectonics

2. Plate Tectonics
In 1855, Antonio Snider published a sketch showing how the two continents could fit together, jigsaw-puzzle fashion
In 1912, Alfred Wegener published the concept of continental drift
Continental drift is just one aspect of a broader theory known as plate tectonics, which has evolved over the last several decades
Tectonics is the study of large-scale movement and deformation of the earth’s outer layers
Plate tectonics relates such deformation to the existence and movement of rigid “plates” over a weak or partly molten layer in the earth’s upper mantle

3. Figure 3.6

4. Continental Drift and Plate Tectonics
Jigsaw-puzzle fit of continents observed a few centuries ago
Mechanism to describe how continental masses moved was not easily visualized for decades
Later half of 20th century the concept of continental drift was incorporated into a broader concept of Plate Tectonics
Mechanisms and processes of continent scale movement detailed
Evidence based on physics, chemistry, mathematics, and geology used to explain how rigid plates move relative to each other

5. Figure 3.1

6. Figures 3.2 a and b

7. Rock Response to Plate Tectonics
Stress –force applied on a rock
Compressive stress – squeeze or compress an object
Tensile stress – pull or stretch an object
Shearing stress – different parts of an object move in different directions or at different rates
Strain – results from stress; is the change in shape or size of an object because of the stress it experienced

8. Strain Temporary or permanent
Elastic deformation – temporary strain, object recovers original size and shape once the stress is removed
Elastic limit – strain that becomes permanent in an object once limit of recoverable strain has been exceeded
Plastic deformation occurs in materials once elastic limit has been exceeded
Brittle deformation occurs at the limit of strength of the material, a rupture or a break occurs

9. Figure 3.3

10. Lithosphere and Asthenosphere
Earth’s crust and upper most mantle are solid and compose the lithosphere
Stresses cause brittle and elastic deformation
Beneath the lithosphere is a plastic layer called the asthenosphere
Lithospheric plates can move over this plastic layer; plate tectonics plausible
Boundaries of the plates are active with earthquake and some with volcanic activity

11. Figure 3.4

12. Evidence for Plate Tectonics
Earthquakes and volcanoes
Sea Floor topography
Trenches
Ridges
Paleomagnetism
Magnetic patterns imprinted on oceanic crust
Curie temperature
Magnetic reversals
Magnetic polar wandering curves
Sea Floor Spreading
Age of the sea floor
Other evidence
Fit of continents, GPS data, and more …

13. Figure 3.5

14. Figure 3.7

15. Figures 3.8 a and b

16. Figure 3.9

17. Figure 3.10

18. Other Evidence for Plate Tectonics
Distribution of rocks representing ancient deserts, sea shores, tropical areas, glaciated areas, swamps, and equatorial regions
Location of fossils that were originally restricted in their distribution but now separated by oceans and on separate continents
Fit of continents reveal super continent of Pangaea
Recognition of plate boundaries

19. Figure 3.13

20. Figure 3.14

21. Figure 3.6

22. Figures 3.15 a, b, and c

23. Plate Boundaries Divergent Plate Boundary
Lithospheric plates move apart; form oceanic ridges
Upwelling of asthenosphere injects magma forming oceanic ridges and new oceanic crust
Forces plates apart
Sea floor spreading occurs
Transform Boundaries – short segments of a ridge
Transform faults offset ridge
San Andreas Fault – transform fault under continental crust

24. Figures 3.16 a and b

25. Plate Boundaries Convergent Plate Boundaries
Lithospheric plates move toward each other
Higher density oceanic crust overridden by low density continental crust
Subduction zone forms and produces a trench
Subduction of older oceanic crust balances the spreading seafloor equation
Subduction zones are active geologic places
Volcanism
Earthquakes
Island arc formation

26. Figures 3.18 a, b, and c

27. Figure 3.19

28. Tectonics Convection cells operate in mantle
Upwelling of heat and magma occurs at divergent plate boundaries
New oceanic crust formed
Oceanic crust pushed away from spreading centers
Hot spots located independent of plate boundaries
High heat flow radiate from them
Volcanic activity associated with them
Hawaiian Islands
Yellowstone

29. Figure 3.20

30. Figure 3.21

31. Figure 3.22

32. Figure 3.23