Alfred Wegener (1915)
proposed that in the past there had been
only one supercontinent,
Pangaea. Hundreds of million years ago,
Pangaea
broke up and the pieces began
to drift apart.
Strong support for this hypothesis comes from
fossils found in South America and Africa which
indicate that the regions had
similar lifeforms and from fossils which indicate that tropical lifeforms
existed in Antarctica around
200 million years ago. Further evidence is provided by
paleomagnetism [the study of the Earth's magnetic field.]
The continents currently
drift apart
at a rate of 2 - 4 cm per year.
The
reason that this
idea, which seems so compelling, was not initially accepted was
that no one could imagine
how things like continents could move around (or more precisely, what
could push continents
around).
We believe that we have a reasonable idea for
the mechanism underlying tectonic motions (however the details
still elude us).
Recall that the interior of the Earth is hot and that it can be
divided
into the crust, mantle, and core based upon chemical
differences but that
from a mechanical standpoint, it was better to consider the crust and the
outer part of the mantle
as one unit, the
lithosphere
and the plastic layer underneath as
one unit, the
asthenosphere.
Some properties of the lithosphere are as
follows:
- The lithosphere is less than ~ 100 km in thickness
- The lithosphere is composed of two types of material
distinct in
composition and structure; the oceanic crust (55 %) and the continental
crust (45 %).
The oceanic crust is thin (< 6 km) and is composed of basalts,
similar
to those found in lunar maria. The oceanic crust is denser than the
continental crust.
The continental crust is thicker
(~ 20 - 70 km) and is composed of
granites. Granites (as are the basalts) are igneuous rocks, however,
granites
were formed under high pressure below the surface of the Earth.
The continental crust is less dense than the oceanic crust.
- The lithosphere is not one unit, it is
segmented. It is
composed
of around 7 major plates and around
two dozen smaller ones. The places
where the
plates come together are well-marked as regions of enhanced geological
activity.
The lithospheric plates are thought to be moved around by
convective motions
(e.g.,
Oatmeal convection).
Because the Earth is
hottest at its center and cools as one moves outward an outward flow of
heat is set up. Through
the solid portions of the Earth, the heat is carried by
conduction, but in the liquid and
in the liquid and plastic portions of the Earth, the heat is
carried by
convection.
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The large scale circulations (motions) in the asthenosphere
move the overlying lithospheric plates on the surface of the Earth
leading to the continental drift observed today.
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The lithospheric plates separate
(new crustal material is
produced)
near rifts. There is a large
rift in the mid-Atlantic stretching from Iceland to Antarctica,
the mid-Atlantic Ridge.
Overall, there are around 60,000 km of active rifts
on the surface of the Earth.
Most are in the oceans, but some are on land, e.g.,
the Great Rift Valley in Africa. New crust is thus continuously
created. The oceanic crust is replaced roughly on a time scale of
200,000,000 years.
PLATE BOUNDARIES
Because the Earth is not growing in size while
crust is created continuously implies that
crustal material is also destroyed continuously. To see where
and how this occurs consider
the interactions when plates collide. There
are three types of interactions which occur near
plate boundaries:
- rift zones
or spreading centers occur where plates move
apart.
The upwelling convective motions in the asthenosphere push the
plates
apart. The upwelling lava cools forming basaltic rock. In addition
to new crust, heat and minerals are also deposited.
-
subduction zones
occur where continental plates meet oceanic
plates.
Because the oceanic plates are denser and thinner than are the
continental plates, they are forced inward (into the Earth). The
oceanic
plates are forced downward to the regions of high temperature where the
rocks are
melted (around 200 - 300 km below the surface). Some of the released
material
is re-inputed to the surface via volcanoes while most is recycled into
the
mantle to be spewed out in rift zones. Near
subduction zones you find oceanic trenches, mountain ranges,
volcanism, and earthquakes. Of particular interest to us is the
Juan de Fuca plate
which forms a shallow angle
subduction zone. Shallow angle subduction
zones lead to
violent activity such as earthquakes and volcanism. In Oregon, we get large
earthquakes every 300 years or so. We are currently due for a large
earthquake. When
two continental plates collide, because
there is no strong tendency for one plate to slide under the other, we get mountain range
formation
mountain range formation.
An example of this is the
Himalayan mountain range.
- transform faults
occur where two plates slide parallel to each other.
An example of this is the
San Andreas fault
in California. The Pacific
plate is forced northward at a rate of a few centimeters per year with
respect to most of the North American plate
(map).
At this rate, Los Angeles
will be next to San Francisco in about 20 million years. Earthquakes
occur near
fault lines because the plates do not slide smoothly. There is friction
between the plates which causes the motion to go in fits and spurts.
The San Andreas fault lets go every century or so. The last
big earthquake occured in
1906 in San Francisco where the
plates slipped by around 6 m (the 1989
earthquake relieved less than 3 m of stress). The southern section
moves about 7 m in a large earthquake
and hasn't really let go since the
great Fort Tejon earthquake of 1857. This is a concern.
THE HAWAIIAN ISLANDS & SHIELD VOLCANOS
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The Hawaiian Islands represent a different kind of volcanism (compared to
the volcanos found, e.g., in the Cascades).
They do not occur near plate boundaries.
They are formed near a hot-spot in the mantle of the Earth.
Through so-called
plumes, magma rises to the surface of the Earth.
The magma oozes to the surface
forming what are known as
shield volcanoes (as opposed to cinder cone volcanoes).
Shield volcanoes have gradual slopes and are produced by
lava flows building
on each other. The Hawaiian islands are the
largest volcanoes
on the Earth
having bases with diameters of ~ 200 km (120 mi) and
heights of 9 km (the volcano on the Big Island,
Mauna Loa,
is the largest active
volcano on the Earth). The reason that there is an island chain is due to the
fact
that the Pacific plate is moving (at a rate of a few cm per year). In 1
or 2
million years that plate moves a distance equal to the average
separation
between the islands. Thus the island chain represents a
time sequence
with the Big Island being the youngest. This process is continuing
and ancient.
There is another Hawaiian island forming,
Loihi, about 20 km southeast
of the Big Island. It is currently about a kilometer below the surface of
the water. It is expected to make its appearance in 50,000 years or so. |
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