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KISS Resources for the Australian Curriculum - Science
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The Structure of the Earth You already know that the Earth has a layered structure.
Inside the Solid EarthScientists have always been interested inearthquakes. By learning about earthquakes it washoped that we might learn to predict them, and soavoid some of the deaths and destruction that theycause.
About 100 years ago, the study of earthquakes (called“Seismology”) became advanced enough thatscientists began studying the way that earthquakeshockwaves travel through the Earth.
From this, it became clear that the solid Earth is nottotally solid, and has a layer structure, as shown.
Later, it was discovered that the outer layer is not aone-piece “shell”, but is broken up into a dozen or so“plates” which slowly slide around on the layersunderneath. As they slide, the plates move apart, orcollide, creating earthquakes, mountain ranges, theocean basins and even the continents themselves.
Crust The crust is avery thin layerof low-density
rock.
Mantle The mantle
is a verythick layerof dense
rock.
Inner Core In the centre is a large ball ofsolid iron & nickel. It is very
hot, but huge pressurescause it to be solid.
Outer Core The outer core is hot
liquid. It is largely a mixtureof the metals iron &
nickel.
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The LithosphereAlthough the Crust and Mantle are separate layers and have different density and composition, the boundary between them is not as simple and clear cut
as the previous diagram suggests.
Attached to the bottom of the crust is a layer of mantlerock which has “welded” itself to the crust rocks above.
This 2-part layer is called the lithosphere.
The thickness of thelithosphere varies.
Under the oceans, it canbe about 5 km thick and
is mostly crust rockswith very little mantlerock attached. Under
the continents thelithosphere is over
100km thick.
100km of rock sounds like a lot, but compared to the6,400 km diameter of the Earth, the lithosphere layer
is an extremely thin shell on the outside.
Below the lithosphere is a “slippery layer”of the mantle.
We now know that the lithosphere“floats” on the main body of the mantle,and is broken up into large pieces calledtectonic plates.
The plates are pushed aroundby huge, relentless forces
caused by heat energyupwelling from
the Earth’s Core.
In this topic you will learnabout the tectonic plates and how they
create and change the continents,oceans and mountain ranges over
hundreds of millions of years.
Lit
ho
sp
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Crust rocks Ocean
Mantle rock stuck to the baseof the crust
Main body of the mantle
Crust & lithosphere under a continent ismuch thicker than under the oceans.
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Seismology Seismology is the study of earthquakes and their shock waves. (Greek, “seismo”= shaking)
EarthquakesEarthquakes are caused by sudden movements inthe Earth’s crust. The sudden release of enormousenergies sends out shock waves which radiate outfrom the “focus” of the ‘quake.
The shock waves are detected and recorded by aseismometer. The photo shows an old-fashionedseismometer recording the vibrations on paper.Modern seismometers use electronic detectors andrecord data digitally for computer analysis.
Seismic WavesThe shock waves arerefracted by different
density rocks, and sometypes of waves cannot
pass through the liquid
Outer Core.
Our understanding of thestructure of the Earth is based on
studying the seismic waves and how they behaveas they pass through the different layers.
There are thousands of seismometers all over theworld, including the ocean floor. Most areautomatic stations sending data to centralcomputers by radio or phone links.
Many are warning systems to alert people topossible volcanic eruptions or tsunami waves inthe oceans.
EarthquakeFocus
Earthquakeshock waves
travel through
the Earth
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A Little History: “Continental Drift”As soon as accurate maps of the World appeared, some people noticed that the shapes of some of the continents fit together like jig-saw pieces. One man took this idea further.
Alfred Wegener (German, 1880-1930)(pron: “vague-ner”)
Wegener was trained in astronomy,but became interested in
Earth Science.
Intrigued by the shapes of thecontinents, he studied the rocks and fossils on either side of the
Atlantic Ocean.
He found many examples of identical, same-ageminerals, fossils and geological features which areon separate continents, but in exactly the locationswhich fit the “jig-saw” idea.
In 1915, he published a theory of “ContinentalDrift” which proposed that the continents hadonce been joined together and had moved totheir current locations. He put forward a lot ofgeological evidence, but could not suggesthow the continents could move, or what forcemight be pushing them.
His theory was not accepted by manyother scientists.
Wegener died in a snowblizzard while doing climateresearch in Greenland.
Africa
Identicalfossils
Identicalmineraldeposits
SouthAmerica
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New Technologies, New Evidence, New TheoryDuring World War II, sonar was developed for submarine warfare. In the 1950’s it was used
to accurately map the deep ocean floor for the first time. The demand for petroleum led to newtechniques for deep-sea drilling from ships into the rocks under the sea.
Sensitive “magnetometers” could be towed by a ship to map the magnetism in the rocks under the deep oceans. These new technologies led to new discoveries.
Plate Tectonic TheoryDuring the 1950’s through 1970’s a hugeamount was learnt about the crust of theEarth, especially under the deep oceans.
New ocean-floor maps, magnetic data androck samples from deep-sea drilling built up abody of evidence which showed that Wegenerwas right... the continents move!
Additional evidence came from seismologyand studies of volcanoes. Details of theevidence will be presented later in this topic.
This led to a new theory called “Plate Tectonics”.
According tothis theory, thelithosphere isnot a simple“skin” like anegg shell, but isbroken up intoabout a dozenpieces, or “plates”.
The plates slowly move around, sliding on the mantle layerbelow. Adjoining plates must either move apart, or crashtogether, or slide sideways past each other.
These movements cause earthquakes and volcanoes,create mountain ranges and volcanic islands andenlarge or destroy the ocean basins.
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The Structure of a Tectonic PlateMost of the major Tectonic Plates include a thick “block” of a continent plus a thin layer of
lithosphere under an ocean. A few plates (such as the Pacific Plate) have no continent and are entirelymade of lithosphere under an ocean.
ocean
Basin of sedimentaryrock on top of the main
contintental block
Mid-Ocean Ridge where 2 plates are moving apart.
OceanicLithosphere
ContinentalCrust
Solid rock of the Upper Mantle
attached to the base of the crust
Plate movements
“Slippery” layer of mantle
allows plates to slide.
The main body of the Mantle is solid rock, but undertremendous pressure so it can flow like putty. This
allows slow but powerful convection currentsto flow and push the plates around.
Lit
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Up
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an
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Convection Currents inthe Mantle carry heat
from the Core, and causethe plates to move.
Each plate can slide sideways on a “slippery” layer of the Mantle. The movement is caused mainly byhuge, slow convection currents which carry heat out from the Earth’s core. The average rate of
movement is about 5 cm per year, but movements are not slow and steady. Instead, the plate might notmove at all for many years, then suddenly lurch forward by several metres.
It is these sudden movements which cause earthquakes. Plates have many cracks and fissures (faults)around the edges because the whole plate might not move all at once. As different sections lurch
forward, the plate develops many cracks and offsets. Over millions of years, a plate not only movessideways, but can rotate and/or change its shape.
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When Plates Move ApartWhen plates move away from each other, molten rock immediately billows up from underneath to fill the
gap and create a new, thin layer of crust. This is occurring mainly on the floor of the oceans. Hiddendeep underwater there are about 70,000 km of plate boundaries which frequently move (creating many
small earthquakes) and erupt new oceanic crust.
About 250 million years ago, the Americancontinents were joined to Europe and Africa. Asthey have moved apart, the Atlantic Ocean hasgrown wider and wider by “sea-floorspreading”.
The “Mid-Ocean Ridges” are chains of underwatermountains with a central “rift valley” where the plateedges are. In some places, such as Iceland, the eruptionof new crust has built up high enough to reach the oceansurface, forming islands.
SEA-FLOOR SPREADING
As plates move apart, new rock fills thegap, creating a “mid-ocean ridge”
Continent
Convection Currents in Mantlepush lithospheric plates apart
Continent
OceanOn this map, plate boundaries are shown in blue and black.The black edges are where plates are moving apart (mostly)
at the Mid-Ocean Ridges.
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When Plates CollideThe tectonic plates cover the surface of a sphere. If they are moving apart in some places, then they have to be colliding somewhere else. Exactly what happens in a collision zone depends on what type of lithosphere is involved.
SubductionIf one of the colliding plates is made of oceaniclithosphere it will be pushed down under theother plate and destroyed by being re-meltedinto the Mantle. This is called “Subduction”.
This type of collision is occurring north ofAustralia where the plate under the PacificOcean is being destroyed. The many volcanicislands of the western Pacific have formed inchains along the subduction zones. Deep oceantrenches occur where the plate is bent sharplydownwards.
Each time a plate lurches forward, an earthquakeoccurs. Large under-sea ‘quakes can set off a tsunami,or seismic water wave, in the ocean. The Boxing-Daytsunami of 2004, which killed over 200,000 people, wascaused by a ‘quake in the subduction zone north-westof Australia.
In March 2011, a huge earthquake near the coast ofJapan (where the Pacific Plate is being subducted) setoff a tsunami which devastated parts of Japan andkilled thousands more.
Ocean
Deep oceantrench
Colliding Oceanic Plates
This plate is being forced down
under the other.
“Island Arc” of volcanic islands eruptfrom the seafloor
As the plate is subductedinto the mantle, melting
occurs and bodies of magmarise through the upper plate
and erupt as volcanoes.Upper Mantle
Composite photo of a ficticious tsunami about todestroy a coastal city. Real tsunamis are more like a
“wall of water” rather than a giant surf wave.
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When Plates Collide cont.If one or both colliding plates is/are carrying a continent things happen differently.
The crust rocks in a continent are too thick and too low in density to be subducted.
The South American plate is colliding with the plateunder the eastern Pacific Ocean. There are deepocean trenches just off the coast and a massivemountain range (the Andes) along the western edgeof the continent.
The mountains are formed by the “crumpling” ofthe continent’s crust in the collision. There are alsomany volcanoes and earthquakes.
Deep oceantrench
Oceanic-Continental Collision
Oceanic platesubducted
Mountain Chain with volcanoes
Melting occurs, andbodies of magma rise
through the upper plate anderupt as volcanoes.
Upper Mantle
Continental Plate iscrumpled by the collision,forming a mountain chain.
Mountain BuildingIf both colliding plates carry the thick lithosphereof a continent, neither plate is subducted. Instead,the continents are crumpled by the collision. Thecrumpling effect folds and fractures the crustrocks and pushes them up to form a chain ofmountains.
The Himalaya mountains formed this way as theplate carrying India has collided with Asia. Rockswhich were once under the sea are now 9 km high.
Ocean
Mountain Rangeformed by folding
and faulting
Continent - Continent Collision... NO SUBDUCTION
Upper Mantle
Joint betweencontinents
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Convection Currents in the MantleWe believe that the Earth’s core is very hot due to theenergy released from radioactive decay. It is so hotdown in the core (around 6,000oC) that the iron-nickel metalmixture should be completely molten. However, the immensepressure forces the Inner Core to be solid, despite the heat.
Since the outer core is liquid, convection currents flow in theliquid and carry the heat outwards.
This heat transfers into the mantle rocks. Although these arethought of as “solid” rock, the mantle is really a thick, semi-liquid. The immense heat and pressure forces the rock toflow like putty in huge convection “cells”.
The flow is so slow that it takes many millions of years for theheat to flow from the core to the crust.
These huge, slow-flowing currents hit the base of the lithosphere andflow sideways. The currents drag on the bottom of the tectonic plates causingthem to move. Mantle convection current are the “prime movers”, but there are also other forces acting...
What Makes the Plates Move?Each tectonic plate can be thousands of kilometers long and wide and 100 km thick.
Made of solid rock, each plate weighs billions of billions of tonnes. What forces can make it move?
Lithosphere
Inner Core
Mantle Convection Cells
Convection Currentsinside the Earth
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Forces Acting on the Plates cont.Other forces move the plates as well as the convection currents.
“Convection Drag”As the convection currents reach the top of the mantle they flow
sideways before cooling and descending again. Friction pulls on the plates,dragging them sideways.
“Ridge Push” Gravitational Sliding
When new crust material forms atthe mid-ocean ridge it is only a
relatively thin layer of crust rock.As the plate moves outwards
from the ridge it becomes thickerbecause upper mantle rock
solidifies onto the base to formcomplete “lithosphere”.
Its density increases, so theplate sinks lower into theunderlying mantle. This
causes the plate to slope like adinner plate on a tilted table...
gravity exerts a force which makesit slide sideways across the“slippery layer” underneath.
The “tilting” of plates is afact... the sea floor at a
Mid-Ocean Ridge can beseveral kilometres higher(closer to the sea surface)than the sea floor 500km
away from the ridge.
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Convection Currents
ocean
Mid-ocean ridge at aspreading boundary.
Volcanic islands & deep ocean trenchat a collision (subduction) zone.
Crust Rock
Upper-Mantle rock sticks to base of the plate to form Lithosphere.
Plate movementPlate movement
Plate movement
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“Slab Pull” At a subduction zone, the descending plate is sinking into the mantle because of its highdensity. As it descends, it pulls the rest of the plate behind it. It is probably the increaseddensity of an old oceanic plate which first fractures it and creates a new subduction zone.
Density increases because mantle rock keeps solidifying onto the base of the plate. By thetime an oceanic plate is “old” (about 200my) it may be too dense to stay “afloat” any longer.
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The Evidence for Moving PlatesThe Tectonic Plate Theory explains many things such as earthquakes & volcanoes,
mountain ranges, island chains & deep ocean trenches. But is it really true? We believe it is true because there is a huge body of evidence to say so. Some evidence was noted by
Alfred Wegener almost 100 years ago, but a lot was only discovered after the 1950’s when newtechnologies allowed us to study the ocean floor, accurately measure the age of rocks and so on.
The Shape of the Continents
The continents of the Earth are like jig-saw puzzlepieces... they fit together quite well, especially alongthe lines of the “continental shelf” rather than theactual coastline.
The continental shelf is the true edge of eachcontinent. In most cases it is under water today, buthas been mapped using sonar.
When the continents are fitted together along theircontinental shelf margins, the fit is almost perfect.
This cannot be just coincidence! It strongly suggeststhat the modern continents were once joinedtogether.
Modern coastlines
Edge of continental
shelf
THE ANCIENT SOUTHERN CONTINENTGONDWANA
Africa
South America
India
Aus
tral
iaAntarctica
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Alfred Wegener discovered some of this evidenceand used it to support his“Continental Drift” idea. Since histime, many more discoveries havebeen made of this same type ofevidence.
FossilsThere are many examples of fossilplants and animals that are foundon separate continents. These wereland plants, or freshwater animalswhich could not have crossed anocean.
The fossils are the same age, andidentical specimens are found across (for example)Africa, South America, India, Australia and Antarctica.They must have evolved and lived right across anancient continent. The moving plates laterseparated the fossil deposits.
Geological EvidenceThere are many examples ofrock layers and mineral depositson different continents whichare identical and are in locationswhich fit the “jig-saw” pattern.
Wegener noted evidence of theeroded “stump” of an ancientmountain range which is presentin South America and Africa.
Scientists have even foundscratch marks on rocks causedby ancient glaciers whichgouged the rocks. The pattern of
the scratches line up perfectly across what arenow different continents. Of course, when theglaciers were doing the scratching, the continentswere joined together.
Africa
Identicalfossils
Identicalmineraldeposits
SouthAmerica
AncientMountain
Range
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Evidence From the Ocean FloorWhen scientists began mapping the ocean floor with sonar, they quickly discovered that
there is a “Mid-Ocean Ridge” of underwater mountains running for 70,000 km through the world’soceans. New deep-water drilling equipment allowed rock samples to be collected, and new methods
involving radio-activity allowed the age of rocks and sediments to be measured. New magnetic equipment allowed the magnetism in the rocks to be measured accurately.
The picture which emerged was clear evidence for the moving plates.
The “residual magnetism” in the rocks (whichwas aligned as the rock hardened from moltenlava) shows a symmetry on either side of thecentral ridge. Each matching band of magnetismrepresents a line of new rock formed as the crustplates moved apart.
Later, these bands were split and separated byeven newer rock injected in the middle as thecrust plates continued to be pushed apart.
While some rocks on the continents are billions ofyears old, the rocks of the oceanic crust are allrelatively young. This is because oceanic crust iscreated where plates move apart, and thendestroyed again by subduction within a fewhundred million years. There is no really ancientrock under the oceans.
Mid-Ocean RidgesThe rocks of the parallel ridges are youngest in themiddle and get progressively older as you moveoutward. The sediments which settle on top of therock are thinnest at the mid-ocean ridge and getthicker as you move away from it.
Mantle ConvectionCurrents push plates apart.
Central Rift
Symmetrical patterns of magnetismon either side of the central rift.
Parallel undersea ridges
New molten rock fills the rift
YoungestrocksOlder
rocks
Olderrocks
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Supercontinent PangaeaThe evidence indicatesthat 200 million yearsago, all the continentswere joined together inone “supercontinent”called Pangaea, whichmeans “whole Earth”.
About 180 million yearsago, Pangaea split into
2 parts as shown.
Later, North Americaseparated from Europe,
creating the AtlanticOcean as it moved
away.
In the south, the ancient continent we callGondwana also began breaking up. Until 45million years ago Australia was still joined toAntarctica. Today Australia is slowly moving north.
Asia
Antarctica
India
Oz
Europe
Africa
Greenland
NthAmerica
SthAmerica
Super-ContinentPangaea
Asia
India
Oz
Europe
Africa
NthAmerica
SthAmerica
Pangaeabreaks up
Laurasia
GondwanaThe breakup of
GONDWANA
Africa
South America
India
Australia
Antarctica
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If all the tectonic plates keep moving the waythey are now (no guarantees!) we can predictwhat the world might look like in 100 millionyears time:
Africa will join completely onto Europe,destroying the Mediterranean Sea.
The eastern one-third of Africa will split-off toform a separate continent.
North America will connect to Asia and thenorth Pacific Ocean will shrink.
Equator
Indonesian islands becomemountainous land bridge
connecting Australia to Asia
Eventually, all the continents may collide and join together to form a new “supercontinent” likePangaea, but with all the parts in different places. The new supercontinent might later crack up into new
fragments.This cycle has occurred over and over in the past. Western Australia was once joined toCanada in a previous supercontinent long before Pangaea was formed.
Japanjoined to
Asianmainland
NorthAmericajoined to
Asia
part of Africa
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Earth”). The rest of theEarth was covered witha global ocean called
Panthalassa (= “whole ocean”).
But how did Pangaea form in the first place?
It is thought that Pangaea formed from thecollisions of previously separate continents. Thoseprevious continents were totally different to themodern ones.
Those pre-Pangaea continents are thought to havecome from the breakup of another previoussupercontinent, and so on... a continuous cycle offorming and breaking up of supercontinents... a“supercycle” of Plate Tectonics.
EVOLUTION OF THE CONTINENTSSupercontinent
New Supercontinent forms
Supercontinent splits apart. Sea-floor spreadingcreates new oceans as continents move apart.
Eventually, continents approach each otheragain... possibly on the other side of the world.
Subduction shrinks the old, previous oceans,until the continents collide.
Oceanic Lithosphere
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B
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C
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Asia
Antarctica
India
Oz
Europe
Africa
Greenland
NthAmerica
SthAmerica
Super-ContinentPangaea
The entire “supercycle” is thought to takeapproximately 400-500my and has major impactson global climate.
Since the sea floor lithosphere is totally destroyedin each supercycle, any evidence of previouscycles (before Pangaea) must be found in thecontinental plates...
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CratonsA “craton” is a mass of continental rock which is ancient & stable. A craton rarely seems to be broken upby tectonic movements, probably because it is too thick. It is a chunk of lithosphere which has survivedmany “supercycles” and been part of many “supercontinents”, but still manages to stay in one piece. Theoriginal rocks have been folded, faulted & undergone metamorphic changes. Younger sedimentarydeposits may have formed on top, eroded away & deposited again.
The point is that a craton is a surviving chunk of an ancient continent & a clue to the past. Australiacontains some of the oldest cratons on Earth. The oldest were already “cratonised” (i.e. had alreadybecome ancient & stable) by 2,500 million years ago. They have been through many continentalsupercycles, although we have little knowledge of events more than 2 cycles back.
Tectonic History of Australia
The diagram showsthe most ancientpart of Australia thatwe know about. The Pilbara andYilgarn Cratons werealready ancientwhen they joinedtogether about 2,300 mya, possibly as part of theformation of a new supercontinent.
Over the following billion years, several youngercratons were added to the east to make a larger,stable continental mass. Presumably, theseadditions occurred during successive periods ofcollisions to form new supercontinents.
Outline ofmodern
coastline.
EasternAustraliadid notexist.
PilbaraCraton
YilgarnCraton
An
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Su
perc
on
tin
en
t?
We know that Australia’scratons were once connectedto similar cratons found todayin Canada.
The supercontinent prior to Pangaea, “Rodinia”, isthought to have formed before 700 mya. It beganto break up again about 600 mya, but theAustralian cratons remained together.
As supercontinent “Rodinia”broke up, the area that is nowthe eastern states of QLD,NSW, Vic and Tassie became acollision zone...
CONTINUED next slide...
700 mya
EasternAust.
did notexist
Evolution of the Australian Continent1,700 mya
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By 500mya, the great supercontinent “Rodinia” hadbroken apart, and bits were on the move. Thesection carrying the Australian cratons wascolliding with another plate, so that a subductionzone formed.
By 400mya, volcanic island arcs erupted from thesea floor. Huge amounts of sediments weredeposited in the shallowing sea, from erosion of thecontinent and islands.
Sea levels were higher than today, so many areas ofthe continent (including much of the ancientcratons) were under shallow seas.
The sedimentary deposits of eastern Australiaincluded the great coal seams of QLD, NSW &Victoria, and the great “Hawkesbury” sandstonedeposits around Sydney.
Subductionzone &
volcanicislands
Vast sedimentarydeposits
PlateMovements
Later, a “fold and thrust belt” developed, in severalseparate phases... and the Great Dividing Rangewas created. In places, such as the New Englandarea of NSW, huge masses of granite were injectedinto the crust, further building the easterncontinent.
By 250mya, theclimate had cooled,and sea levelsfell. For the firsttime, most ofmodernAustraliabecame dry land.
But this was not the modern islandcontinent. By this time a new supercontinent hadformed and Australia was just one corner of“Pangaea”.
Later, Pangaea broke apart. Later still, the southernportion “Gondwana” split up as described earlier.
For the past 200 million years or so, Australia hasbeen a very quiet place tectonically. The maingeological process operating has been erosion, soour land is broad and flat. Sediment washed fromthe mountains has formed the coastal plains wheremost Australians live.
Great DividingRange formed.
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Tectonic Australia TodayAustralia seems to be a very quiet place in terms of tectonic activity.
We have no volcanoes and only a few, mostly small, earthquakes. Why?
The Australian PlateThe diagram shows the approximate positionof the “Australian Plate” and its neighbours.The arrows show the plate movements.
IndonesiaMany active volcanoes and earthquakes arecommon. On Boxing Day 2004, an under-sea‘quake set off a tsunami which killed anestimated 200,000 people. Subduction Zone.
Southern Ocean FloorMapping of the ocean floor reveals a Mid-Ocean Ridge with many small earthquakes.Sea-Floor Spreading is pushing Australia andAntarctica further apart.
Pacific Island ChainsLook at a map of this region. There are manyDeep Ocean Trenches and hundreds ofVolcanic Islands. Another Subduction Zone.
New ZealandThey aren’t called the “Shakey Isles” for nothing!Many earthquakes and active volcanoes. NZ sits onthe edge of our plate where it slides sideways pastthe Pacific Plate.
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AustralianPlate
Antarctic Plate
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Eurasian Plate
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AustraliaWe are surrounded by tectonic activity, but weexperience almost none. That’s because we arein the quiet centre of our tectonic plate. All theexciting, but dangerous and violent thingshappen at the edges where 2 plates meet.
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Impacts of Tectonic EventsWhat effects do the movements of Tectonic Plates have on people & on the Earth itself?
Effects of Volcanoes on Earth Climate
Volcanic Eruptions release huge quantities ofgases, ash and dust. Mostof the solid particles fallquickly and blanket thesurrounding area, butsome fine particles can beinjected into the highatmosphere and remainthere for years.
These fine particles reflectlight & heat from the Sun.This has a cooling effect which can last for years.
Volcanoes release a lot of acidic gases such assulfur dioxide. This can cause “acid rain” whichdamages ecosystems.
CO2 and GreenhouseAlthough fine dust particles can have ashort-term cooling effect, the longer-termeffect of volcanoes can be the opposite.
Volcanic eruptions release huge amountsof CO2 gas. This is a “greenhouse gas”which traps heat which would otherwiseradiate back into space. This has theeffect of raising global temperatures.
One volcano has little impact, but therehave been times in the Earth’s historywhen widespread activity caused major
climate changes. We believe that, about 250million years ago, 95% of all life on Earth becameextinct. The cause seems to have been suddenclimate changes due to huge volcanic eruptionswhich first cooled, then heated the Earth.
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Earthquakes & PeopleIn a severe earthquake the ground heaves so thatyou cannot stand upright. However, this groundmotion is not the main hazard to people. The bigkillers in any earthquake are collapsing structures,fires & tsunamis.
When major earthquakes hit large cities, the deathtoll can be enormous. Most casualties result fromcollapsing buildings. Multi-storey apartment blockscan “concertina” downwards: each floor is a block ofconcrete which can fall onto the next in a downward“domino effect”.
Knowing the danger, many people rush out into thestreets and are then showered with falling roof tilesand broken glass from buildings that have notcollapsed, but are shaking violently.
As the ground moves, pipes carrying water, power &gas are ruptured. Fires break out, & broken watermains make it difficult to fight the blaze. In the greatSan Francisco earthquake of 1906 large areas of thecity survived the ‘quake but were destroyed byuncontrollable fires.
San Francisco 1906. Massive ‘quake, then fire.
In hilly or mountainous areas, earthquakes cantrigger landslides which can bury entire villages.
When the earthquake occurs under the sea, thecrust movements can cause destructive waterwaves called “tsunamis”. In recent years therehave been 2 major tsunamis in the Asian region.
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Rescue choppers over Sendai, Japan 2011.The smoke is from a damaged oil refinery.
Note the fields & suburbs flooded with sea water.
Indonesia, Boxing Day 2004A massive undersea earthquake in the subductionzone near Sumatra, Indonesia set off a tsunami whichkilled about 200,000 people in Indonesia, Thailand,Malaysia, Sri Lanka and other nations around theIndian Ocean.
In many placesthere was no
warning before awall of water
wiped out entiretowns, beach
resorts and ruralfarming
communities.
Japan, March 2011One of the largest earthquakes ever recordedoccurred in the subduction zone just off the Japaneseeast coast. There was considerable earthquakedamage, then within an hour a 30m tsunami washedup to 10km inland.
A tourist took this photo as the 2004 Asian Tsunami hit thecoast of Thailand. Moments later, most of these people died.
About 15,000 people died. This death toll wasconsidered to be relatively low due to Japanhaving excellent building codes, warning systems,tsunami defences and emergency refuges.
Despite all defences, the tsunami damaged theFukushima Nuclear Power Plant. This led to a laterexplosion and leakage of radioactivity from thereactors.
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Sea-Floor SpreadingWhere plates move apart, newcrust is created at the mid-ocean ridges. This widens theocean basins.
200 million years ago, theAtlantic Ocean did not existbecause North America wasjoined to Europe. As thelithosphere fractured intoseparate plates which movedapart, the Atlantic Ocean was created, and is still growing wider.
Subduction destroys oceanic lithosphere and shrinks oceans.Near subduction zones, volcanic islands grow from the oceanfloor. The Pacific Ocean is shrinking as Nth America approachesAsia.
Mountain BuildingMountain chains are formedwhere plates collide. Thecrust is buckled, folded andfaulted. Earthquakes thrustthe crust upwards to formthe great mountain chains ofthe world. Erosion thenforms valleys and plains. Allour landscapes result.
MetamorphismThe high temperatures andpressures caused by tectonicforces changes the rocksthemselves. Shale turns to slate,and limestone becomes marble.
These rocks formed under the sea, butare now 4km above sea level.
Impacts of Tectonic Events (cont.)
Effects on World GeographyOver hundreds of millions of years, the moving plates totally change the size and arrangements of the
continents and the oceans. As the oceans change, so do the ocean currents. This has major impacts onthe Earth’s climate and on plants & animals and their ecosystems.
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Effects on Living ThingsWe tend to think that earthquakes and volcanic eruptions always cause destruction of ecosystems
and death of living things. However, there is a positive side as well.
Mass Extinctions
At a local level, a tsunami candestroy coral reefs or coastalmangrove ecosystems. A volcanocan destroy forests, or bury entireecosystems under hot ash.Locally, the living communitiescan be devasted.
It can also be global. It wasalready mentioned that volcanic activityalmost completely wiped out life on Earthby causing huge climate changes about250mya.
However, we know from the fossil recordthat after every mass extinction, lifealways “bounces back” with greatervariety and numbers than before.
New HabitatsTectonic events create newplaces to live. For example,coral reefs thrive aroundvolcanic islands created bysubduction zones. Many newspecies evolve on the islandsthemselves.
Mountain ranges and the rivers,valleys and plains that formfrom them, all become habitats
for living things. Recycling ChemicalsAncient farmers knew that volcanoes create fertile soil. Aneruption can destroy, but fresh lava brings minerals whichfertilise the soil.
Globally, plate tectonics is essential for cycling vitalchemicals, such as carbon, calcium and phosphorus.Scientists now realise that without tectonic activity, theEarth’s biosphere could not evolve and thrive as it has done.
Forest flattenedby blast
Valley buried in ashand mud-flow. (Lahar)
Mt St Helens, USA, erupted in1981 causing destruction
over a wide area.
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As scientists have gathered information aboutancient plate movements and the “continentalsupercycle” they have noticed an interesting generalcorrelation with global climate.
When there is a singlesupercontinent, the worldclimate is colder and drier, withlower sea levels.
This is because volcanic activity isat a minimum (less rifting andsubduction occurring) and CO2levels are low. A reduced greenhouseeffect lowers the average world temperature.
Low temperature means less evaporation, and lowerrainfall. Formation of a permanent ice-cap lowers sealevels for many millions of years. The world becomescold & dry.
SingleSupercontinent
Permanent ice caps atthe poles
When there are many continents split up allover, there must be more rifting andsubduction going on, and so volcanic activityincreases CO2 levels.
The Greenhouse Effect increases globaltemperatures, so there is more evaporationand more rainfall. Unless a continent driftsover a pole it is unlikely thereare ice caps, so sea levelsare higher.
At the moment, we aresomewhere in-betweenthese situations.
There is evidence that ourice-caps are melting. If theymelted completely, sea-levels would rise by60m or more.
Many separatecontinents
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