The document summarizes plate tectonics and the development of the theory. It describes how early scientists like Wegener proposed continental drift but lacked evidence. Later, mapping of the ocean floor revealed patterns of magnetic stripes and rock ages indicating the seafloor spreads from mid-ocean ridges. This led scientists in the 1960s to develop the modern theory of plate tectonics, which proposes that Earth's crust is divided into plates that move due to convection currents in the mantle.
2. Review
Inside the Earth
The Earth is divided into four main layers:
Crust
Mantle
Outer Core
Inner Core
3. The Crust
The crust makes up 1% of the
Earth.
The crust of the Earth is broken
into many pieces called plates.
Two types of crust:
Oceanic (made of basalt)
Continental (made of granite)
4. The Mantle
The upper part of
the mantle and the
crust make up the
Lithosphere.
The mantle is the
largest layer of the
Earth.
The mantle can be
divided into two
regions: the upper
and lower mantle.
6. Asthenosphere
Soft layer of the mantle on which
pieces of the lithosphere move.
7. Mesosphere
Beneath the
Asthenosphere
is the
strongest part
of the mantle
—the
Mesophere.
8. The Core
The core extends from
the bottom of the
mantle to the center
of the Earth.
The outer core is
liquid.
The inner core is the
solid dense center of
our planet.
9. Tectonic Plates
Pieces of the lithosphere that move
around on the top of the
asthenosphere.
11. Continental Drift
*Continents can
drift apart from
one another and
have done so in the
past.
*The continents
are still slowly
moving, at about
the speed your
fingernails grow.
12. Alfred Wegener suggested that
all continents were joined
together at some time in the
past. This is called the
hypothesis of “continental drift”.
According to continental drift,
continents have moved slowly to
their current locations.
He called this large landmass as
Pangaea (“all land”)
17. Landforms
• Mountains in
South Africa
line up with
mountains in
Argentina
• Coal mines
line up on
different
continents
18. Mountain Structures
Similar rock structures
are found on different
continents.
For example, parts of
Appalachian mountains
are similar to those
found in Greenland
and western Europe.
19. Appalachian Mountains
strike through the eastern
United States and
Canada then end at the
sea off of Newfoundland.
The Caledonides
Mountains are found in
eastern Greenland,
Ireland, Great Britain
and Norway.
These two mountain
ranges are the same age
with the same rock types
and structures.
20. Fossils
Besides the puzzlelike fit of continents, fossils provided
support for continental drift.
For example: fossils of the reptile Mesosaurus have
been found in South America and Africa.
21. Another fossil that supports the continental
drift is Glossopteris which has been found in
Africa, Australia, India, South America,
and Antarctica.
22. Climate Clues
Fossils of tropical plants were found in
Spitsbergen, an ice covered island in the
Arctic Ocean (north of Norway).
23. Glacier Activity
Glacial deposits and rock
surfaces scoured and polished by
glaciers are found in South
America, Africa, India and
Australia.
24. Why was it not accepted?
Wegener could not provide an
adequate explanation for the force
that pushes or pulls the continents.
25. Although Wegener provided evidence to support his
hypothesis, he couldn’t answer two questions:
1. What was causing the continents to move?
Wegener said that this force might be the rotation of Earth,
however, physicists were able to show that this force was not
great enough to move continents.
26. 2. How were the continents moving?
Wegener proposed that the continents were
plowing through a stationary ocean floor. But, his
peers argued that continents could not push through
the ocean floor without fracturing, because crustal
rock is too brittle. And no evidence of fracturing had
been found.
27. And the rest of the story….
Undaunted by rejection, Wegener devoted the rest
of his life to doggedly pursuing additional
evidence to defend his theory. He froze to death in
1930 during an expedition crossing the Greenland
ice cap, but the controversy he spawned raged on.
However, after his death, new evidence from
ocean floor exploration and other studies rekindled
interest in Wegener's theory, ultimately leading to
the development of the theory of plate tectonics.
http://bumileluhur.blogspot.com/2011/01/this-dyniamic-earth-story-of-plate.html
28. The controversy continues!
Plate tectonics has proven to be as important to the earth
sciences as the discovery of the structure of the atom was to
physics and chemistry. Even though the theory of plate
tectonics is now widely accepted by the scientific
community, aspects of the theory are still being debated
today. Ironically, one of the chief outstanding questions is the
one Wegener failed to resolve: What is the nature of the
forces propelling the plates? Scientists also debate how plate
tectonics may have operated (if at all) earlier in the Earth's
history and whether similar processes operate, or have ever
operated, on other planets in our solar system.
Will you be the one to solve the
mystery?
32. Mapping The
Ocean Floor
Scientists began using sound waves on moving
ships to map large areas of ocean floor in detail.
Sound waves echo off the ocean bottom – the
longer the sound waves take to return to the
ship, the deeper the water is.
33. Mapping the Mid-Ocean Ridge
Also known as the Mid-
Atlantic Ridge
Longest mountain
chain in the world
Divided by a trench
34. Most is hundreds of meters under water, but part
reaches above the ocean surface.
It is almost twice as deep as the Grand Canyon.
Iceland is part of the mid-ocean ridge
35. In the early 1960s, Harry Hess proposed that hot,
less dense material below Earth’s crust rises
toward the surface at the mid-ocean ridges.
Then, it flows sideways, carrying seafloor away
from the ridge in both directions. This theory is
known “seafloor spreading”.
36. In 1968, a research ship, Glomar Challenger, began
gathering rock samples from mid-ocean ridges.
They made a remarkable discovery as they studied the
ages of rock samples.
The younger rocks are closer to the mid-ocean ridges
and older rocks are farther from the ridges.
37. Evidence of Sea-Floor Spreading
Molten Material
Magnetic Stripes
Drilling Samples
38. Magnetic Clues
Iron-bearing minerals,
such as magnetite, that
are found in the rocks of
the seafloor can record
Earth’s magnetic field
direction when they
form.
The magnetic alignment
in the rocks reverses
back and forth over time
in strips parallel to the
mid-ocean ridges.
40. Subduction of Deep-Ocean
Trenches
Subduction is the
process by which
the ocean floor
sinks beneath a
deep-ocean trench
and back into the
mantle.
41. Subduction and Earth’s Ocean
Subduction and sea-floor spreading can
change the size and shape of the oceans.
The ocean floor is renewed about every 200
million years.
42. The Pacific Ocean is shrinking; a trench swallows
more oceanic crust than the mid-ocean ridge can
produce.
The Atlantic Ocean is expanding.
There are only a few trenches in the Atlantic.
The continental crust is attached to the ocean floor, so
as the Atlantic expands and moves, the continents
move with it.
43. Section 3:
theory of Plate
tectonicS
In the 1960s, scientists developed a new theory that
combined continental drift and seafloor spreading .
According to the theory of plate tectonics, Earth’s
crust and part of upper mantle are broken into
sections. These sections are called plates, move on a
plastic-like layer of the mantle.
44. Where did the theory come
from?
J. Tuzo Wilson combined Earth’s plates,
continental drift, and sea-floor spreading into a
single theory---PLATE TECTONICS
45. A Theory of Plate Tectonics
Plate tectonics states that pieces of Earth’s
lithosphere are in constant, slow motion, driven by
convection currents in the mantle, and it explains
the formation, movement, and subduction of
Earth’s plates.
46. Basically….
The plates on the lithosphere float on the
asthenosphere, convection currents rise in the
asthensophere and spread out beneath the
lithosphere.
http://youtu.be/ryrXAGY1dmE
47. Earth’s crust and a part of upper mantle combined
are the lithosphere. (100km=62 mile thick)
The plastic-like layer below the lithosphere is
called asthenosphere. The rigid plates of the
lithosphere float and move around on the
asthenosphere.
48. Causes of Plate Tectonics
Convection currents cause the movements of plates
Hot, less dense liquid or gas is forced upward, as it
reaches the surface, it cools down and sinks back
down. This entire cycle of heating, rising, cooling
and sinking is called a convection current.
49. No plate can budge without affecting
the other plates surrounding it!
50.
51.
52. Plate Boundaries
When plates move, they can interact in several
ways. Three different moving types of plates are:
Plates moving apart (Divergent)
Plates moving together (Convergent)
Plates slide past each other (Transform)
53. Faults break in Earth’s crust
where rocks have slipped past each
other.
Plate boundaries are where the
edges of different pieces of the
lithosphere meet.
55. Transform Boundary
Two plates slip past each other, moving in
opposite directions. (Do not push or pull)
Crust is neither created nor destroyed near a
transform boundary.
Earthquakes occur frequently along these
boundaries.
56. Divergent Boundary
Two plates move apart or diverge.
Most occur at the mid-ocean ridge; they can also
occur on land (poor Africa).
A rift valley is a deep valley that forms along the
divergent valley.
The Great Rift Valley in Africa marks a deep crack
in the African continent that runs for about 3,000
km.
When divergent boundaries develop on land, two
of Earth’s plates pull apart.
57. Convergent Boundary
Two plates come together or collide (converge)
Results: earthquakes, trenches, volcanoes,
mountains
When two plates collide the denser of the two
plates will sink or slide beneath the other.
61. The continents’ slow dance
The plates move at slow rates about 1 to 10 cm
per year.
http://youtu.be/hSdlQ8x7cuk
62. To prevent confusion
Not all volcanoes
occur at plate
boundaries. For
example, the
Hawaiian islands
formed from a hot
spot volcano. As the
Pacific plate moves
across a fixed hot spot
(mantle plume), new
volcanoes (and
islands) form.
63. Summary
Theories: Continental Drift Theory of Plate
Theory Tectonics
Forces of Plate Cycle of Gravity Heated Core
Movement: Convection
Currents
Types of Plate Divergent Convergent Transform
Movement/
Interactions:
(Boundary)
Processes or Sea-floor Subduction Earthquakes
Types of Spreading (Volcanoes) and
Movement Mountains
(Results):
Stress: Tension Compression Shearing
Faults: Normal Reverse Strike Slip