Understanding Plate Tectonics
A2
The History
• Alfred Wegener 1915• First came up with the theory that the
earth’s plates were slowly moving in relation to each other (Continental Drift)
• It was not until the 1960’s and Harry Hess who proposed that it was caused by sea floor spreading at mid ocean ridges
• This was where the modern history of plate tectonics begins
Why do we have tectonic Plates
• The earth has 7 large plates• 7 smaller ones• And dozens of micro plates• The earth’s surface is broken up into
plates because the heat generated in the earth's core by radioactive decay drives convection currents in the outer core and mantle.
• These slowly tear the earth apart and are responsible for movement
• This movement will continue as long as heat is generated at the core
All Major and Minor Plates
How do the move?
• Plates come in two types Oceanic and continental
• Oceanic Plates– Are young, thin and dense.– They are formed on the sea floor spreading at
constructive plate boundary ridges and destroyed at Subduction zones
– Most are under 150 million years old and made of dense Basalt (6-8km thick)
Oceanic Plates
Continental Plates
• Are ancient thick and less dense • They are over 4 billion yrs old and are not
being formed today• They are made of less dense Granite and
are 30-60km thick
Convection
• At the rising limbs of convection cells, heat from the core moves towards the earth’s surface then spreads to either side.
• It is this spreading motion that splits the plates and drags them apart.
• Plates move on a layer between the upper mantle and lithosphere. The asthenosphere acts as a type of lubrication
• The plate motion depends however on two factors:– The weight of the cold plates at the subduction zones pulling
the plate downwards– Gravitational sliding force between ‘High’ and ‘Low’
Trenches
Convection Currents
Layer Physical State
Lithosphere Earth’s Crust)
Solid, rigid
Asthenosphere Solid, plastic, (partially molten approx 4%)
Mantle Solid, plastic
Outer core Liquid
Inner Core Solid (Iron and Nickel)
Convection Currents
Hazards
• Most occur where the plates meet. Boundary Hazards
• There are rare ‘Intra-plate earthquakes’ and ‘Mid-plate volcanic hotspots’
• There many different tectonic ‘settings’ which produce various hazards
SettingsSETTING MOTION HAZARDS EXAMPLE
CONSTRUCTIVE PLATE BOUNDARY
2 Oceanic plates moving apart
Basaltic volcanoes and minor , shallow earthquakes
Mid-Atlantic ridge (Iceland) mostly submerged)
2 continental plates moving apart
Basaltic splatter cone volcanoes
African Rift Valley and Mnt. Niyragongo
DESTRUCTIVE PLATE BOUNDARY
2 oceanic plates in collision
Island arc explosive Andesite eruptions and EQ’s
Soufrierre Hills on Montserrat
2 continental plates in collision
Major, shallow earthquakes along thrust faults
Himalayan orogenic belt
Oceanic and continental plate collision
Explosive, andesitic eruptions and major EQ
Andes mountain chain
TRANSFORM BOUNDARY
Plates sliding past one another
Major shallow earthquakes
San Andreas fault
HOTSPOTS Oceanic Basaltic shield volcanoes, minor earthquakes
Hawaiian Island chain
Continental Colossal Rhyolitic mega-eruptions
Yellowstone ‘supervolcano’ USA
Research Task
• What caused and started the following earthquakes:
• San Francisco 1906• Great Kanto (Tokyo) 1923• Chile 1960• Mexico City 1985• Izmit Turkey 1999• Kashmir 2005
Volcanoes
• Why aren’t they all the same?• We have discussed the reasons for why
not all volcanoes are the same– Basaltic – basic magma– Andesitic – Intermediate– Rhyolitic – Acidic magma
Basaltic
• Very hot iron rich silica poor• Low gas content and very hot runny lava
(Melted ice cream)• Can erupt almost continuously• Not very explosive
Andesitic
• In the middle between rhyolitic and basaltic
• Sticky can take decades or centuries between eruptions
• Can be very explosive
Rhyolitic
• High silica content low temperature and high gas content therefore combustible
• Erupt rarely• Can be devastating
The Richter Scale
• Developed in 1935 to measure magnitude of earthquakes
• Today the Moment Magnitude Scale MMS id more commonly used and is very similar
• Most earthquakes over 6.5 on the Richter scale generate interest as at this magnitude they will cause some, if not significant damage
• However this does not tell the whole story
Earthquake Depth
• Shallow surfaced EQ’s (<70km) intermediate (70-300km) Deep focused (>300km)
• Shallow ones are the most destructive as less energy is lost travelling to the surface
• Especially important in the Benioff Zone of subducting plates
The Benioff Zone
• This is the active seismic zone on a subduction plate
• In a subduction zone the earthquake foci normally plots along a dipping plane at an angle of 33 to 60 degrees and this plane is called a Benioff zone
• It is named after Hugo Benioff, a US seismologist who first described this feature
• The Benioff zone extends to a depth of about 700 km
Physical Nature of the Ground
• If the ground consists of loose sediment then liquefaction can occur
• In high mountain areas such as the Himalayan fold mountains landslides can have devastating effect.
Finally
• After looking at these your research should take into account the ‘Settings’ of the events as this will help you understand the impacts that it has on humans
References
• Leeds University Lecture Notes