الاثنين، 25 يوليو 2011

CONTINENTAL DRIFT


In 1915, the German geologist and meteorologist Alfred Wegener first proposed the theory of continental drift, which states that parts of the Earth's crust slowly drift atop a liquid core. The fossil record supports and gives credence to the theories of continental drift and plate tectonics. 
Wegener hypothesized that there was a gigantic supercontinent 200 million years ago, which he named Pangaea, meaning "All-earth". 
Pangaea started to break up into two smaller supercontinents, called Laurasia and Gondwanaland, during the Jurassic period. By the end of the Cretaceous period, the continents were separating into land masses that look like our modern-day continents.

Evidence that continents 'drift'

Evidence for continental drift is now extensive. Similar plant and animal fossils are found around different continent shores, suggesting that they were once joined. The fossils of Mesosaurus, a freshwater reptile rather like a small crocodile, found both in Brazil and South Africa, are one example; another is the discovery of fossils of the land reptile Lystrosaurus from rocks of the same age from locations in South America, Africa, and Antarctica.There is also living evidence — the same animals being found on two continents. Some earthworm families (e.g.: Ocnerodrilidae, Acanthodrilidae, Octochaetidae) are found in South America and Africa, for instance.
The complementary arrangement of the facing sides of South America and Africa is obvious, but is a temporary coincidence. In millions of years, slab pull and ridge-push, and other forces of tectonophysics will further separate and rotate those two continents. It was this temporary feature which inspired Wegener to study what he defined as continental drift, although he did not live to see his hypothesis become generally accepted.
Widespread distribution of Permo-Carboniferous glacial sediments in South America, Africa, Madagascar, Arabia, India, Antarctica and Australia was one of the major pieces of evidence for the theory of continental drift. The continuity of glaciers, inferred from oriented glacial striations and deposits called tillites, suggested the existence of the supercontinent of Gondwana, which became a central element of the concept of continental drift. Striations indicated glacial flow away from the equator and toward the poles, in modern coordinates, and supported the idea that the southern continents had previously been in dramatically different locations, as well as contiguous with each other.
Earth's Plates:
Earth's Crust



 The Earth's crust is divided into huge, thick plates that drift atop the soft mantle. The plates are made of rock and are from 80 to 400 miles (50 to 250 km) thick. They move both horizontally and vertically. Over long periods of time, the plates also change in size as their margins are added to, crushed together, or pushed back into the Earth's mantle. 

plate tectonics

The theory of plate tectonics has done for geology what Charles Darwin's theory of evolution did for biology. It provides geology with a comprehensive theory that explains "how the Earth works." The theory was formulated in the 1960s and 1970s as new information was obtained about the nature of the ocean floor, Earth's ancient magnetism, the distribution of volcanoes and earthquakes, the flow of heat from Earth's interior, and the worldwide distribution of plant and animal fossils.  

 

The theory states that Earth's outermost layer, the lithosphere, is broken into 7 large, rigid pieces called plates: the African, North American, South American, Eurasian, Australian, Antarctic, and Pacific plates. Several minor plates also exist, including the Arabian, Nazca, and Philippines plates.
The plates are all moving in different directions and at different speeds (from 2 cm to 10 cm per year--about the speed at which your fingernails grow) in relationship to each other. The plates are moving around like cars in a demolition derby, which means they sometimes crash together, pull apart, or sideswipe each other. The place where the two plates meet is called a plate boundary. Boundaries have different names depending on how the two plates are moving in relationship to each other 
Earth's Major Plates:

The current continental and oceanic plates include: the Eurasian plate, Australian-Indian plate, Philippine plate, Pacific plate, Juan de Fuca plate, Nazca plate, Cocos plate, North American plate, Caribbean plate, South American plate, African plate, Arabian plate, the Antarctic plate, and the Scotia plate. These plates consist of smaller sub-plates. 



 
Continental Drift

Looking at a map of the Earth, it appears that the continents could fit
together like a jigsaw puzzle.


Alfred Wegener (1915) proposed the idea of "continental drift."

Wegener suggested that a single "supercontinent" called Pangaea once
existed in the past.


Continental Drift

Wegener developed his idea based upon 4 different types of evidence:

     1. Fit of the Continents
     2. Fossil Evidence
     3. Rock Type and Stuctural Similarities
     4. Paleoclimatic Evidence

Evidence for Continental Drift:


     Fit of the Continents
It was the amazingly good
fit of the continents that first
suggested the idea of
continental drift.

In the 1960's, it was
recognized that the fit of the
continents could be even
further improved by fitting
the continents at the edge
of the continental slope —
the actual extent of the
continental crust.


Evidence for Continental Drift:

     Fossil Evidence
Wegener found that identical fossils were located directly opposite on
widely separated continents.
This had been realized previously but the idea of "land bridges" was the
most widely accepted solution.
Wegener found fossils to be convincing evidence that a supercontinent
had existed in the past.


Example:
Mesosaurus



Evidence for Continental Drift:

     Rock Type and Structural Similarities
We find similar rock types on continents on opposite sides of the Atlantic
Ocean.
Similar, age, structure and rock types are found in the Appalachian Mtns.
(N.A.) and mountains in Scotland and Scandinavia.




Evidence for Continental Drift:

     Rock Type and Structural Similarities
When the continents are reassembled, the mountain chains from a
continuous belt — having the same rock types, structures and rock ages.



Evidence for Continental Drift:

     Paleoclimatic Evidence
Glacial till of the same age is found in southern Africa, South America,
India and Australia — areas that it would be very difficult to explain the
occurrence of glaciation.
At the same time, large coal
deposits were formed from tropical
swamps in N. America and
Europe.

Pangaea with S. Africa centered
over the South Pole could account
for the conditions necessary to
generate glacial ice in the
southern continents.

In addition, the areas with
extensive coal deposits from the
same time period occur in regions
that would have been equatorial.


Science is based on more than mere empirical observation — we strive to
understand the mechanisms.

We must develop a theory to explain our observations.

Wegener's idea of continental drift was not generally accepted because no
one could come up with a reasonable mechanism for the movement of the
continents.


(Movie: Breakup of Pangaea)
It was not until the 1960's that further data led to the development of a the
theory of plate tectonics that could explain the movement of continents.


Paleomagnetism

The Earth's magnetic field produces invisible lines of force that extend from
one pole to the other.


A compass needle aligns itself with these lines of force — points toward the
magnetic poles.
When igneous rocks
containing magnetic minerals
crystallize, the crystals align
themselves with the Earth's
magnetic field.

The magnetic field of the rock
then points toward the
magnetic pole that existed
when the rock formed.

If the rock is moved, its
magnetic field will act as a
"fossil compass."


Magnetized minerals can also
The Earth's magnetic field is
curved, and the inclination of
the magnetic grains gives an
estimate of the paleolatitude.
Magnetized minerals can also
The Earth's magnetic field is
curved, and the inclination of
the magnetic grains gives an
estimate of the paleolatitude.
Paleomagnetism

be used to determine the
latitude of their origin.

Equator: horizontal
Mid-latitude: high angle
Pole: straight up


Pole Wandering

Looking at igneous rocks, the apparent position of the North Pole was
determined from the paleomagnetism of the rock.

Assuming that the magnetic
poles are approximately

coincident with the pole of
rotation, the apparent
movement of the poles
must be due to movement
of the continents.

Curves are similar shape
for N. America & Europe
except that they were offset
by ~24° of longitude.


Pole Wandering

If the two continents are placed next to one another to how we believe
they fit in Pangaea, the apparent pole wandering paths coincide.

This would represent the time
before the opening of the
Atlantic Ocean


Seafloor Spreading

Harry Hess (1960's) proposed the theory of seafloor spreading based
upon this evidence and newly published maps of the seafloor topography
indicating the existence of a world-wide mid-ocean ridge system.


He proposed
that ridges are
located above
zones of
upwelling in the
mantle —
resulting in the
creation of
seafloor.

He also
proposed
subduction as a
mechanism for
recycling of the
seafloor.


Geomagnetic Reversals

Earth's magnetic field periodically reverses polarity — the north and south
poles switch.
Rocks crystallizing during one of these periods of magnetic reversal will be
magnetized with a polarity opposite of rocks the crystallize today.




Geomagnetic Reversals — Seafloor

Using a magnetometer, oceanographers discovered that the seafloor has
regions of low- and high-intensity magnetism.
It was further found that these zones occur as stripes parallel to the ridge
crest.


High-intensity zones
correspond to seafloor
formed during a period of
normal magnetic polarity (2
fields add together).


Low intensity zones
correspond to seafloor
formed during a period of
reversed magnetic polarity (2
fields cancel each other out).



Geomagnetic Reversals — Seafloor

As new seafloor is created at the ridge, it is added in equal amounts to
both trailing edges of the spreading seafloor.
We would expect to see the pattern of stripes as mirror images on both
sides of the ridge — strongest evidence for seafloor spreading.


In the Pacific, the
stripes are much wider

— indicating a faster
rate of spreading (or
creation of new
seafloor).
In the Atlantic, the
stripes are much more
narrow — indicating a
relatively slow rate of
spreading.


Theory of Plate Tectonics

Concepts of continental drift and seafloor spreading are united into a
much more encompassing theory known as plate tectonics.


This is a far-reaching theory that has become the basis for viewing most
geologic processes — mountain building, paleontology, volcanism,
earthquakes, etc.


The Earth's surface is composed of rigid plates known as the lithosphere.
These plates overly a weaker region of the mantle known as the
aesthenosphere.


There are 7 major plates and over a dozen smaller plates.
Plates move slowly but continously on the order of a few cm/year.



Plate Boundaries

There are 3 distinct types of boundaries:

1. divergent — plates move away from one another
2. convergent — plates move into one another (collision)
3. transform — plate grind past one another
Each plate is bounded by a variety of plate boundaries.

New plates can be created by forces that split plates apart such as at
the East African Rift Valleys.

Two plates may suture together to form one plate such as may happen
with the Himalayans.


Most situated along the crests of the mid-Most situated along the crests of the mid-
Plate Boundaries — Divergent Boundaries


ocean ridges.

Typical spreading rates are ~5 cm/year,
however, range from 2 to 20 cm/year.

Red Sea and Gulf of California — new
spreading ridges developing


Plate Boundaries — Divergent Boundaries


Continental crust can begin to rift from upward movement of hot rock from
mantle.
Uplift results in extension that stretches the crust.



Plate Boundaries — Divergent Boundaries


Extension of the crust is accompanied by episodes of faulting and
volcanism.
This results in rift valley like the East African Rift Valleys.



Plate Boundaries — Divergent Boundaries


As the spreading continues, the rift valley will widen and deepen,
extending out to the sea.
The valley then becomes a narrow linear sea — Red Sea, Gulf of
California.



Plate Boundaries — Divergent Boundaries


The rifting will continue until a full blown ridge system is created forming a
large ocean basin --— ex. Atlantic Ocean.


Convergent Boundaries — Ocean-Continent Collisions


Denser oceanic crust is subducted — trench, accretionary wedge,
volcanism.
Examples: Andes, Cascade Range


Sierra Nevada represents an inactive continental arc.




Convergent Boundaries — Ocean-Ocean Collisions

Similar to ocean-continent collision except that volcanoes can form
islands — volcanic island arc.
Ex. Aleutian Islands, Mariana, Tonga Islands.




Convergent Boundaries — Continent-Continent Collisions


Usually preceded by subduction until continents smash into one
another.
Results in thicken of crust and jumbled mess of many rock types
superimposed on one another.
Example: Himalayan Mtns.




Himilayan mountains as an example of continent-continent collision




Transform Plate Boundaries

Characterized by strike-slip motion — two plates grind past one another.
Example: California


Transform Plate Boundaries

Most transform boundaries occur in association with mid-ocean ridge
systems — forming fracture zones which include the transform fault and
their inactive extensions into the plate interior.
These transform fault occur about every 100 km along a ridge and offset

the ridge crest.

Plate Tectonics and Earthquakes

Most earthquakes are coincident with plate boundaries — due to
movement along boundaries.
Divergent and transform boundaries usually result in shallow earthquakes.




Plate Tectonics and Earthquakes


Subduction zones
result in a range of
depths of
earthquakes —
Benioff zone.


Hotspots

Most volcanic activity is associated with plate boundaries — MOR,
subduction, etc.
Some "intraplate" volcanoes are the result of a plate moving across a
mantle hot spot.