Plate Tectonics Theory That Explains How Slow Motions Within the Mantle of the Earth Move

October 27, 2003

Earth as a Planet (Chapter 7)

Global Characteristics
Size
Composition (iron-nickel, iron-sulfur, silicon and oxygen – metal and silicate rocks) - very different from the composition of the Sun
Orbit around the Sun
Temperature range (-50 to 50 deg Celsius, average about 10-15 deg Celsius)
Mass
Density

Earth’s Interior – several distinct layers with different compositions
Crust (the “skin” of the Earth), 0.3 % of the total mass of Earth, density – 3 g/cubic cm
crust under the ocean (55%) – 6 km thick, formed of volcanic rocks (basalt – silicon, oxygen, iron, aluminum, magnesium)
continental crust – (45%) – 20 to 70 km thick, formed of silicates (granite)
Mantle – largest part of the solid Earth – down to a depth of 2900 km. Density, temperature and pressure (more or less solid); Volcanic activities – samples of the mantle
Outer core (liquid) – dense metallic core (iron, nickel, sulfur), diameter 7000 km
Inner core (solid) – diameter 2400 km
Differentiation – separation of the Earth into layers of different densities

- Material in the core is moving - generates magnetic field

- Magnetoshpere – the Earth magnetic field extends about 60 000 km into surrounding space

- Asymmetric

Studying the seismic waves – speed and wavelength bring information about the layers

Plate Tectonics – theory that explains how slow motions within the mantle of the Earth move large segments of the crust, resulting in a drifting of continents and formation of large scale geological features.

Plate tectonics - basic concept to geology
Developed at mid 20th century
“Plate” – large rigid slab of solid rocks; “tectonics” – from the Greek root “to build”; “plate tectonics” – refers to how the Earth’s surface is built of plates
Earth’s crust and upper mantle are divided into about 10 major plates, moving relative to one another, located at the top of the hotter, more mobile material of the mantle
Convection – physical phenomenon that provides the power to move the plates
Explanation of convection

Plates can pull apart (recede)
Rift zones (Mid Atlantic ridge, central African ridge). Most rifts zones – below the ocean; molten rocks (basaltic lava) fill the space between receding plates
60000 km of active rifts have been identified
average rate of separation – 4 cm/yr – means 2 sq km new area added to the Earth each year – new oceanic crust in 100 000 000 years
oceanic crust – the youngest feature of our planet

Plates can burrow under one another
The zone where one plate is forced under another – subduction zone (subducted plate is forced down and partly melted)
the feature formed is called (ocean) trench (deep Japan trench along the coast of Asia)
subduction zones often give rise of thermal vents – earthquakes and volcanoes
Plates can slide alongside
Forming cracks or faults
Not a smooth motion – severe earthquakes
Average Rate – several cm/yr
San Andreas Fault – boundary between the Pacific plate (the coast of California) and the North American plate
Plates can jam together (colliding)
Push against each other under great pressure – recent plates collisions create mountains (Alps and Himalayas – young features)

6. Volcanoes - locations where magma rises to the surface

Along the mid-ocean ridges, along the undersea mountains (formed at plate boundaries)
Above the mantle hot spots, far from the boundaries of the plates
Volcanic mountains (lava flows slow from craters), volcanic plains (lava flows rapidly from a long cracks)

7. The Earth’s atmosphere

8. Structure of the atmosphere

troposphere (0 – 10 km) – air convection all the time – warm air heated by the surface rises and is replaced by descending currents of cooler air - creates clouds and wind , temperature at 10 km - -50 deg Celsius
stratosphere – 10 – 50 km, cold and free of clouds
ozone layer (O3) - absorbs UV light
mesosphere (50 -100 km)
ionosphere

9. Atmospheric composition at the Earth’s surface