The seafloor spreading
KristineTablarin
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Jun 16, 2018
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About This Presentation
Scientists found a system of ridges or mountains in the seafloor similar to those found in the continents.These are called mid-ocean ridges. One of these is the famous Mid-Atlantic Ridge, an undersea mountain chain in the Atlantic Ocean.
It has a gigantic cleft about 32-48 km long and 1.6 km deep. ...
Slide Content
During the 1950s and 1960s, new techniques and
modern gadgets enabled scientists to make better
observations and gather new information about the
ocean floor. With the use of sonars and submersibles,
scientists had a clearer view of the ocean floors. They
have discovered underwater features deep within the
ocean.
modern gadgets enabled scientists to make better
observations and gather new information about the
ocean floor. With the use of sonars and submersibles,
scientists had a clearer view of the ocean floors. They
have discovered underwater features deep within the
ocean.
Scientists found a system of ridges or mountains in the seafloor
similar to those found in the continents.
These are called mid-ocean ridges. One of these is the famous Mid-
Atlantic Ridge, an undersea mountain chain in the Atlantic Ocean.
It has a gigantic cleft about 32-48 km long and 1.6 km deep. The ridge is
offset by fracture zones or rift valleys.
similar to those found in the continents.
These are called mid-ocean ridges. One of these is the famous Mid-
Atlantic Ridge, an undersea mountain chain in the Atlantic Ocean.
It has a gigantic cleft about 32-48 km long and 1.6 km deep. The ridge is
offset by fracture zones or rift valleys.
In the early 1960’s, scientist Harry Hess, together with Robert Dietz,
suggested an explanation to the continental drift. This is the Seafloor
Spreading Theory.
According to this theory, hot, less dense material from below the
earth’s crust rises towards the surface at the mid-ocean ridge.
This material flows sideways carrying the seafloor away from the
ridge, and creates a crack in the crust. The magma flows out of the crack,
cools down and becomes the new seafloor.
Overtime, the new oceanic crust pushed the old oceanic crust far
from the ridge. The process of seafloor spreading allowed the creation of new
bodies of water. For example, the Red Sea was created as the African plate
and the Arabian plate moved away from each other. Seafloor spreading is also
pulling the continents of Australia, South America, and Antarctica away from
each other in the East Pacific Rise. The East Pacific Rise is one of the most
active sites of seafloor spreading, with more than 14 centimeters every year.
suggested an explanation to the continental drift. This is the Seafloor
Spreading Theory.
According to this theory, hot, less dense material from below the
earth’s crust rises towards the surface at the mid-ocean ridge.
This material flows sideways carrying the seafloor away from the
ridge, and creates a crack in the crust. The magma flows out of the crack,
cools down and becomes the new seafloor.
Overtime, the new oceanic crust pushed the old oceanic crust far
from the ridge. The process of seafloor spreading allowed the creation of new
bodies of water. For example, the Red Sea was created as the African plate
and the Arabian plate moved away from each other. Seafloor spreading is also
pulling the continents of Australia, South America, and Antarctica away from
each other in the East Pacific Rise. The East Pacific Rise is one of the most
active sites of seafloor spreading, with more than 14 centimeters every year.
Figure 12. Diagram of Seafloor Spreading
In the place where two oceanic plates collide or where an oceanic
plate and a continental plate collide, a subduction zone occurs. As the new
seafloor is formed at the mid-ocean ridge, the old seafloor farthest from the
ridge is destroyed at the subduction zone.
In the place where two oceanic plates collide or where an oceanic
plate and a continental plate collide, a subduction zone occurs. As the new
seafloor is formed at the mid-ocean ridge, the old seafloor farthest from the
ridge is destroyed at the subduction zone.
Figure 13. Subduction Zone
The rate of formation of a new seafloor is not always as fast as the
destruction of the old seafloor at the subduction zone. This explains why the
Pacific Ocean is getting smaller and why the Atlantic Ocean is getting wider. If
subduction is faster than seafloor spreading, the ocean shrinks. When the
seafloor spreading is greater than the subduction, then the ocean gets wider.
The rate of formation of a new seafloor is not always as fast as the
destruction of the old seafloor at the subduction zone. This explains why the
Pacific Ocean is getting smaller and why the Atlantic Ocean is getting wider. If
subduction is faster than seafloor spreading, the ocean shrinks. When the
seafloor spreading is greater than the subduction, then the ocean gets wider.
Findings that support Seafloor Spreading Theory:
1. Rocks are younger at the mid-ocean ridge.
2. Rocks far from the mid-ocean ridge are older.
3. Sediments are thinner at the ridge.
4. Rocks at the ocean floor are younger than those at the continents.
1. Rocks are younger at the mid-ocean ridge.
2. Rocks far from the mid-ocean ridge are older.
3. Sediments are thinner at the ridge.
4. Rocks at the ocean floor are younger than those at the continents.
Magnetic Reversal
Seafloor spreading was strengthened with the discovery that the
magnetic rocks near the ridge follow a pattern aside from the fact that
rocks near the ridge are remarkably younger than those father from
the ridge.
A magnetic compass tells us directions on Earth. It also proves
that the Earth has a magnetic field.
The Earth’s magnetic field is generated in the very hot molten outer
core and has already existed since the birth of our planet. The
Earth’s magnetic field is a dipole, one that has a North Pole and a
South Pole.
Magnetic reversal is also called magnetic ‘flip’ of the Earth. It
happens when the North Pole is transformed into a South Pole and
the South Pole becomes the North Pole. This is due to the change
in the direction of flow in the outer core.
Seafloor spreading was strengthened with the discovery that the
magnetic rocks near the ridge follow a pattern aside from the fact that
rocks near the ridge are remarkably younger than those father from
the ridge.
A magnetic compass tells us directions on Earth. It also proves
that the Earth has a magnetic field.
The Earth’s magnetic field is generated in the very hot molten outer
core and has already existed since the birth of our planet. The
Earth’s magnetic field is a dipole, one that has a North Pole and a
South Pole.
Magnetic reversal is also called magnetic ‘flip’ of the Earth. It
happens when the North Pole is transformed into a South Pole and
the South Pole becomes the North Pole. This is due to the change
in the direction of flow in the outer core.
Magnetic reversals happened many times in the past. The occurrence
of magnetic reversals can be explained through the magnetic patterns in
magnetic rocks, especially those found in the ocean floor. When lava solidifies,
iron bearing minerals crystallize. As these crystallize, the minerals behave like
tiny compasses and align with the Earth’s magnetic field. So when magnetic
reversal occurs, there is also a change in the polarity of the rocks.
This allowed scientists to visualize the magnetic stripes in the ocean
floor similar to Figure 14, and to construct a magnetic polarity time scale
similar to Figure 15.
of magnetic reversals can be explained through the magnetic patterns in
magnetic rocks, especially those found in the ocean floor. When lava solidifies,
iron bearing minerals crystallize. As these crystallize, the minerals behave like
tiny compasses and align with the Earth’s magnetic field. So when magnetic
reversal occurs, there is also a change in the polarity of the rocks.
This allowed scientists to visualize the magnetic stripes in the ocean
floor similar to Figure 14, and to construct a magnetic polarity time scale
similar to Figure 15.
Figure 14. Magnetic Reversal
Figure 15. Magnetic Polarity Time Scale
Figure 15. Magnetic Polarity Time Scale
magnetic stripes
Q22. What do the stripes in the paper represent?
Q23. What does the middle slit represent? What occurs in this
region?
Q24. What is the role of the mid–ocean ridge in the movement of
lithospheric plates?
Q25. How does the new seafloor form at the mid-ocean ridge?
Q26. What process/es happen at the side slits?
Q27. Is the earth getting larger and wider when plates drift away
from each other? Explain briefly.
Q23. What does the middle slit represent? What occurs in this
region?
Q24. What is the role of the mid–ocean ridge in the movement of
lithospheric plates?
Q25. How does the new seafloor form at the mid-ocean ridge?
Q26. What process/es happen at the side slits?
Q27. Is the earth getting larger and wider when plates drift away
from each other? Explain briefly.
Objectives:
Analyze a magnetic polarity map.
Use legends and scales of the map properly.
Calculate the rate of seafloor spreading using
magnetic clues.
Analyze a magnetic polarity map.
Use legends and scales of the map properly.
Calculate the rate of seafloor spreading using
magnetic clues.
Magnetic polarity map
Procedure:
1. Study the magnetic polarity map. You will be working only with normal polarity
readings, these are the peaks above the baseline on the top half of the graph.
2. Place the long edge of the ruler vertically on the graph. Align the ruler with the
center peak 1 of the Mid-Atlantic Ridge.
3. Determine and record the distance and age that line up with the center of peak 1
west. Repeat this process for peak 1 east of the ridge.
4. Calculate the average age and distance for this pair of peaks.
5. Repeat steps 2 to 4 for the remaining pairs of normal polarity peaks.
6. Calculate the rate of movement in centimeters per year using the formula
Rate = distance / time.
Q28. How far do the plates move away from each other every year?
Q29. If Africa is approximately 2400 km away from the Mid-Atlantic Ridge, how
long ago was it when Africa was directly at or near the Mid-Atlantic Ridge?
1. Study the magnetic polarity map. You will be working only with normal polarity
readings, these are the peaks above the baseline on the top half of the graph.
2. Place the long edge of the ruler vertically on the graph. Align the ruler with the
center peak 1 of the Mid-Atlantic Ridge.
3. Determine and record the distance and age that line up with the center of peak 1
west. Repeat this process for peak 1 east of the ridge.
4. Calculate the average age and distance for this pair of peaks.
5. Repeat steps 2 to 4 for the remaining pairs of normal polarity peaks.
6. Calculate the rate of movement in centimeters per year using the formula
Rate = distance / time.
Q28. How far do the plates move away from each other every year?
Q29. If Africa is approximately 2400 km away from the Mid-Atlantic Ridge, how
long ago was it when Africa was directly at or near the Mid-Atlantic Ridge?
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