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Earth ~200 million years ago

Earth ~200 million years ago. The Geologic Time Scale. Based on. *Fossils *Correlation. Later. *Calibrated with radiometric dating. The Continental Drift Hypothesis. Proposed by Alfred Wegener in 1915. Supercontinent Pangaea started to break up about 200 million years ago.

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Earth ~200 million years ago

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  1. Earth ~200 million years ago

  2. The Geologic Time Scale Based on *Fossils *Correlation Later *Calibrated with radiometric dating

  3. The Continental Drift Hypothesis Proposed by Alfred Wegener in 1915. Supercontinent Pangaea started to break up about 200 million years ago. Continents "drifted" to their present positions. Continents "plowed" through the ocean crust.

  4. Continental Drift: Evidence Geographic fit of South America and Africa Fossils match across oceans Rock types and structures match across oceans Ancient glacial features

  5. Continental Drift: Evidence Tight fit of the continents, especially using continental shelves.

  6. Continental Drift: Evidence Fossil critters and plants

  7. Continental Drift: Evidence Correlation of mountains with nearly identical rocks and structures

  8. Continental Drift: Evidence Glacial features of the same age restore to a tight polar distribution.

  9. Continental Drift: Reactions Received well in Europe and southern hemisphere. Rejected in U.S., where scientists staunchly preferred induction (incremental progress built on observation) over what they perceived as speculative deduction. Lack of a suitable mechanism crippled continental drift’s widespread acceptance. Conflict remained unresolved because seafloors were almost completely unexplored.

  10. The Rise of Plate Tectonics WW II and the Cold War: Military Spending U.S. Navy mapped seafloor with echo sounding (sonar) to find and hide submarines. Generalized maps showed: oceanic ridges—submerged mountain ranges fracture zones—cracks perpendicular to ridges trenches—narrow, deep gashes abyssal plains—vast flat areas seamounts—drowned undersea islands Dredged rocks of the seafloor included only basalt, gabbro, and serpentinite—no continental materials.

  11. The Rise of Plate Tectonics Marine geologists found that seafloor magnetism has a striped pattern completely unlike patterns on land. Mason & Raff, 1961 Black: normal polarity White: reversed polarity Both: very magnetic

  12. The Rise of Plate Tectonics Hypothesis: Stripes indicate periodic reversal of the direction of Earth’s magnetic field. To test this hypothesis, scientists determined the eruptive ages AND the polarity of young basalts using the newly developed technique of K-Ar radiometric dating. The study validated the reversal hypothesis...

  13. The Rise of Plate Tectonics And then (1962-1963) geologists realized that the patterns are SYMMETRICAL across oceanic ridges. The K-Ar dates show the youngest rocks at the ridge.

  14. The Rise of Plate Tectonics Meanwhile, U.S. military developed new, advanced seismometers to monitor Soviet nuclear tests. By the late 1950s, seismometers had been deployed in over 40 allied countries and was recording 24 hrs/day, 365 days/year. Besides the occasional nuclear test, it recorded every moderate to large earthquake on the planet. With these high-precision data, seismologists found that activity happens in narrow bands.

  15. Bands of seismicity—chiefly at trenches and oceanic ridges

  16. The Theory of Plate Tectonics “group authorship” in 1965-1970 Earth’s outer shell is broken into thin, curved plates that move laterally atop a weaker underlying layer. Most earthquakes and volcanic eruptions happen at plate boundaries. Three types of relative motions between plates: divergent convergent transform

  17. Tectonic Plates on Modern Earth

  18. Divergent boundaries: Chiefly at oceanic ridges (aka spreading centers)

  19. How magnetic reversals form at a spreading center

  20. Divergent boundaries also can rip apart (“rift”) continents

  21. How rifting of a continent could lead to formation of oceanic lithosphere. e.g., East Africa Rift e.g., Red Sea e.g., Atlantic Ocean

  22. Presumably, Pangea was ripped apart by such continental rifting & drifting.

  23. Subduction zones form at convergent boundaries if at least one side has oceanic (denser) material. Modern examples: Andes, Cascades Major features: trench, biggest EQs, explosive volcanoes

  24. Another subduction zone—this one with oceanic material on both sides. Modern example: Japan

  25. Earthquake depth indicates subduction zones

  26. Collison zones form where both sides of a convergent boundary consist of continental (buoyant) material. Modern example: Himalayas This probably used to be a subduction zone, but all the oceanic material was subducted.

  27. Most transform boundaries are in the oceans. Some, like the one in California, cut continents. The PAC-NA plate boundary is MUCH more complex than this diagram shows.

  28. Hotspots, such as the one under Hawaii, have validated plate tectonic theory.

  29. Why do the plates move? Two related ideas are widely accepted: Slab pull: Denser, colder plate sinks at subduction zone, pulls rest of plate behind it. Mantle convection: Hotter mantle material rises beneath divergent boundaries, cooler material sinks at subduction zones. So: moving plates, EQs, & volcanic eruptions are due to Earth’s loss of internal heat.

  30. How does convection work? No one knows—but they aren’t afraid to propose models! Whole-mantle convection Two mantle convection cells Complex convection

  31. Field Trip Briefing The California subduction zone (9’ seismic line) Subduction to transform (Atwater animation) Faults of the Bay Area (SF-SJ maps) Rock types we’ll encounter

  32. Landslide north of Mussel Rock Occurred between 2 am and 8 am, 2/21/05

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