Earth Structure and Characteristics
The Core
Outer Core
liquid iron
generates a magnetic field
Inner Core
solid iron
extreme pressure keeps it solid despite high temperatures
The Mantle
Mafic silicate minerals
Temperatures range from 1800°C to 2800°C
Largest layer, makes up over 80% of Earth's volume
Subdivided into zones with different temperatures and compositions
Lower Mantle
hotter but largely rigid due to intense pressure
Upper Mantle
lower temperature and pressure
softer and plastic (asthenosphere)
molten material forms in hotspots
The Crust and Lithosphere
Thin, outermost layer of Earth
Separated from mantle by Moho discontinuity
Composed of varied rocks and minerals
7-40 km thick
Contains continents and ocean basins
Oceanic crust
consists almost entirely of mafic rocks
Continental crust
consists of lower zone of dense mafic rock and upper zone of lighter felsic rock
Lithosphere
outer Earth shell of rigid
brittle rock
including crust and cooler upper part of mantle
ranges in thickness from 60 to 150 km
Lithospheric plates
large pieces of lithospheric shell that can move independently
can separate or collide to create relief features like continents and ocean basins
Continental Rupture and New Ocean Basins
The Power Source for Plate Movements
Radiogenic heating
Convection Currents Theory
Gravity Gliding Theory
The Descending Theory
Continental Rupture and New Ocean Basins
Definition: Continental lithosphere fractures and splits apart
Causes: Tectonic forces uplift a plate of continental lithosphere and pull it apart
Result: Formation of a wide ocean with an axial rift and passive continental margins on either side
Passive continental margins: Where continental lithosphere is joined to oceanic lithosphere with no motion between them
Example: Red Sea - triple junction of three spreading boundaries established by the motion of the Arabian plate pulling away from the African plate
Formation process: Initial formation of a rift valley leads to the sinking of the bottom below sea level and allows seawater to enter
Plate Tectonics
Relief Features Of The Continents
Metamorphic Rocks
Formation
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Definition of Metamorphosis
Metamorphism is a process that changes preexisting rocks into new forms because of increases in temperature, pressure, and chemically active fluids.
Types of Metamorphic Rocks
Foliated: they have formed in an environment with either directed pressure or shear stress.
Not Foilated: they have formed in an environment without directed pressure or relatively near the surface with very little pressure.
Igneous Rocks
Island Arcs and Collision of Oceanic Lithospheric Plates
Continent ruptures to form an ocean basin with axial rift
Two plates move apart and create a new ocean
Plate motions may reverse and the ocean basin may start to close
Fracture produces a subduction boundary
Subduction occurs when fracture happens at a passive continental margin
Subducted oceanic lithosphere plunges downward, and oceanic crust is carried into the mantle
Subducted oceanic crust is altered due to water reaction
Melted altered crust forms magma that rises and erupts on the seafloor
Island arc is formed by new volcanoes that grow and fortify from below
Accretionary wedge of sediments forms from piled-up seafloor sediment in the trench
Example: Aleutian Islands
The Wilson Cycle and Supercontinents
The Wilson Cycle
Stage 1 — Embryonic Ocean Basin
Stage 2 — Young Ocean Basin
Stage 3 — Old Ocean Basin
Stage 4A — The Closing Of The Ocean Basin
Stage 4B — The Rising Of Island Arcs
Stage 5 — Closing Continents
Stage 6 —The Form Of Continental Suture
Supercontinent Cycle
Convergence
Supercontinent Formation
Dispersal
Continent-Continent Collison
Resulted by the ongoing closing of ocean basin
The collision unites two plates
Collision zone is called a continental suture
Ancient sutures marking early collision
Ural Mountains (Europe-Asia)
Appalachian Mountains (Eastern North America)
Caledonian Mountains (Scotland, Norway, Svalbord, Eastern Greenland)
Arc-Continent Collison
Island arc collides with passive continental margin
Island arc is thick and buoyant
Not subducted, but pushed up against the continent
Layers of sediment on continental shelf and slope are affected
Crushed and deformed
Thrust far inland over older continental rocks
Resulting mass of rocks is called an orogen
Formed through the process of orogeny
Continuation of collision leads to formation of new subduction boundary
Another oceanic fracture develops.
Configuration Of The Continent
Earth surface features formed are driven by the lithospheric plates’ movement that slides over the hot viscous asthenosphere.
Configuration of our continents must have changed many times over the history of the earth
Arc-Continent Collision
Relief Features Of The Ocean Basins
Ocean basins are contained in The crust.
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Earth continents and ocean basins were created by the continuous movements of Lithospheric plates in geologic timescales on the surface of the Earth
Ocean basins include a midoceaning ridge with a central axial rift where crust is being pulled apart
The margins of the Pacific Ocean Basin have deep offshore oceanic trenches
In the North Atlantic Ocean, two large tectonic plates are spreading apart and moving away from a central rift.