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BAESI: Earth and Life Through Time

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How do plates interact at their boundaries? ... cells that drag along overlying lithospheric plates - acts like conveyor belts. ... – PowerPoint PPT presentation

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Title: BAESI: Earth and Life Through Time


1
BAESI Earth and Life Through Time
  • Plate Tectonics Overview
  • Jonathan Hendricks
  • SJSU Department of Geology
  • jhendricks_at_sjsugeology.org

2
Plate Tectonics Overview
  • Lecture Overview
  • Have the positions of continents moved through
    time?
  • What is the history of the idea of continental
    drift?
  • How does plate tectonics work?
  • How do plates interact at their boundaries?

3
Plate Tectonics
  • Plate Tectonics The scientific theory that the
    surface of the Earth (lithosphere) is divided
    into plates that move relative to one another and
    that interact at their boundaries.
  • Slide shows an image of one tectonic plate being
    subducted beneath another.

Image from USGS
4
Map of the World
  • Slide shows a satellite map of the world.

Image from NASA
5
History of Plate Tectonics
  • Slide shows two images made by geographer Antonio
    Snider-Pellegrini, 1858. One shows the
    continents separated. The other shows North and
    South America connected with Europe and Africa.

Maps by geographer Antonio Snider-Pellegrini, 1858
6
Glossopteris Seed Fern
  • Slide shows a photo of a Glossopteris fossil, as
    well as locations on the world map where
    Glossopteris fossils have been found.

Image from USGS
Image from NASA
Stars show places where Glossopteris fossils have
been found.
7
Glossopteris Flora and Land Bridges?
  • Slide shows a photo of a Glossopteris fossil, as
    well as locations on the world map where
    Glossopteris fossils have been found. A circle
    shows the position of the ancient land mass known
    as Gondwana.

Gondwana
Image from USGS
Image from NASA
Was sea level lower during late Paleozoic?
8
Alfred Wegener (1880-1930)
  • German meteorologist who proposed idea of
    continental drift idea that continents moved
    (and continue to move) horizontally over the
    surface of the Earth.
  • In 1915 presented evidence for a single
    supercontinent, which he called Gondwana.
  • Early evidence presented by Wegener and other
    workers (especially Alexander du Toit) in support
    of continental drift
  • Continental fit.
  • Rock sequences.
  • Glacial flow directions.
  • Rift valleys.
  • Distributions of fossils.
  • Slide shows a photograph of Alfred Wegener.

Image from USGS
9
Glacial Flow Directions
  • Slide shows two images. One shows a picture of
    scratch marks on rocks caused by glacial flow.
    The second shows ancient glacial flow directions
    on the modern world map. The third shows that the
    glacial flow directions in the southern
    continents only make sense if the continents were
    once connected.

Image from USGS
Image from NASA
10
Rift Valleys of Africa
From NASA
  • Slide shows two images. One is a map of
    northeastern Africa showing the positions of
    major rift valleys. The second shows a satellite
    photo of a rift valley.

Image from USGS
11
Fossil Evidence
  • Slide shows the distributions of Glossopteris,
    Lystrosaurus, and Mesosaurus fossils when the
    southern continents are reunited as Gondwana.

12
History of Plate Tectonics
  • Despite the extensive evidence that the positions
    of the continents have changed through time, most
    geologists rejected the idea of continental
    drift.
  • This was because there was no known mechanism
    that could produce such change.

13
Interior of the Earth
  • Inner core mostly solid iron
  • Outer core mostly liquid iron
  • Mantle rocky material
  • Crust
  • Oceanic crust
  • Continental crust
  • Pressure increases with depth.
  • Slide shows two figures that detail the different
    parts of the interior of the Earth

Images from USGS
14
Earths Magnetism
  • Motion of iron-rich outer core creates a magnetic
    field.
  • Earth acts like giant bar magnet with N and S
    poles.
  • Geographic and magnetic poles offset.
  • Slide shows a cartoon image of Earths magnetic
    field.

Image from USGS
15
Magnetism is Recorded in Rocks
  • Some rocks contain iron minerals.
  • These minerals align themselves to Earths
    magnetic field as the rock forms.
  • Iron particles in sedimentary rock align as they
    fall out of suspension from water.
  • Iron particles in magma (igneous rocks) align
    before the magma cools.
  • Frozen orientations preserve record of the
    ancient orientations of Earths magnetic field.

16
Study of the Seafloor
  • The seafloor became much better explored during
    the 1940-1960s.
  • WWII, sonar.
  • Complex topography.
  • Mid-oceanic ridges with central furrow.
  • Volcanoes often associated with ridges.
  • Slide shows an artists painting of the
    Mid-Atlantic Ridge.

Image from USGS
17
Harry H. Hess Seafloor Spreading
  • Hess Hypothesis of Seafloor Spreading
  • 1962
  • Continental and oceanic crust move together.
  • New oceanic crust forms from rising magma at
    mid-continental ridges
  • Oceanic crust moves away from ridge as it cools.
  • Mechanism thermal convection.
  • Slide shows a photograph of Harry Hess.

Image from USGS
18
Thermal Convection
  • Thermal convection is thought to be the process
    driving the movement of plates.
  • Earth is hotter (due to radioactive decay -
    fission) in some portions of the deep mantle than
    in others.
  • This causes the formation of convection cells
    that drag along overlying lithospheric plates -
    acts like conveyor belts.
  • Think about a container full of boiling water.
  • Slide shows two images. One is a cross-section
    through the Earth showing how convection cells in
    the mantle may operate. The other shows a
    container of boiling water.

Images from USGS
19
Testing Hess Hypothesis
  • How could one test Hess hypothesis of seafloor
    spreading?
  • What pattern should one find on either side of
    mid-ocean ridge systems if Hess hypothesis is
    true?
  • Slide shows an image of the Mid-Atlantic Ridge.

Image from Google Earth
20
Magnetic Reversals
  • The polarity of Earths magnetic field has
    flipped many times throughout the geologic
    past.
  • The reason(s) why are not at all clear.
  • Durations of normal and reversed polarity
    highly variable in length.

21
Test of Hess Hypothesis
  • During the early 1960s, it was discovered that
    changes in Earths magnetic polarity have been
    recorded into rocks on the seafloor (oceanic
    crust) as they cooled.
  • Symmetrical banding on each side of mid-oceanic
    ridge systems.
  • Younger rock near ridge, older away.
  • Slide shows two images that illustrate magnetic
    reversals on either side of a mid-ocean ridge.
    These reversals form symmetrical patterns on each
    side of the mid-ocean ridge.

Images from USGS
22
Ages of the Worlds Ocean Basins
  • Slide has one image showing the ages of different
    oceanic crust rocks in the worlds ocean basins.

Image from USGS
23
Hess Hypothesis Was NOT FalsifiedEnough
support has since been provided for plate
tectonics that the idea is now accepted as a
unifying theory for geology.Simple idea with
great explanatory power.
24
Major Plates of the World
  • Slide shows the major plates of the world.

Image from USGS
25
Plates Interact at Their Boundaries
  • Slide shows a figure that details where recent
    earthquakes have occurred. Most occurred near
    plate boundaries.

Image from USGS Earthquakes over last 30 days
(http//neic.usgs.gov/neis/qed/)
26
Different Plate Boundaries
  • Three major types of plate boundaries
  • Divergent - plates diverge from each other.
  • Convergent - plates converge toward each other.
  • Oceanic-Continental - oceanic crust (denser)
    subducts (goes under) beneath continental crust.
  • Continental-Continental - neither body of
    continental crust subducts (equal density).
  • Transform - plates slide past each other.

27
Different Plate Boundaries
  • Slide shows a figure that provides an overview of
    the three major types of plate boundaries
    divergent plate boundaries, convergent plate
    boundaries, and transform plate boundaries.

Image from USGS
28
Divergent Plate Boundary
Mid-Atlantic Ridge
  • Slide shows two images. The first shows a
    picture that illustrates a divergent plate
    boundary. The second shows the mid-Atlantic ridge
    system.

Image from USGS
Image from Google Earth
29
Oceanic-Continental Convergent Plate Boundary
Andes, South America
  • Slide shows two images. On is an illustration of
    a oceanic-continental convergent boundary. The
    second is an image of the west coast of South
    America, which is an oceanic-continental
    convergent boundary.

Image from USGS
Image from Google Earth
30
Continental-Continental Convergent Plate Boundary
Himalaya Mountains, Asia
  • Slide shows three images. One is an illustration
    of a continental-continental convergent boundary.
    The second is an image of the Himalayan
    mountains, which is an example of a
    continental-continental convergent boundary. The
    third is a cartoon that shows how India crashed
    into Asia.

Image from USGS
Image from USGS
Image from Google Earth
31
Transform Plate Boundary
Northwestern United States
  • Slide shows two images, both of which illustrate
    the positions of transform plate boundaries near
    the northwest coast of the United States.

San Andreas Fault
Image from USGS
Image from Google Earth
32
Earth Today
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
33
Earth in the Cretaceous
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
34
Earth in the Jurassic
GONDWANA South America, Africa, Antarctica,
India, and Australia
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
35
Earth in the Permian
SUPERCONTINENT OF PANGEA!!
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
36
Earth in the Devonian
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
37
Earth in the Ordovician
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
38
Earth in the Cambrian
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
39
Earth in the Late Proterozoic
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
40
Earth Today
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
41
Earth in 150 Million Years
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
42
Earth in 250 Million Years
Plate tectonic maps and Continental drift
animations by C. R. Scotese, PALEOMAP Project
(www.scotese.com)
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