Studied by 31 peopleTags & Description
differences between continental drift hypothesis and plate tectonic theory
Continental Drift
Continents move independent of oceanic crust, even plough through oceanic crust
no known why/how
Plate Tectonic
Tectonic plates with continents and ocean crust move as one slab across asthenosphere
driving mechanism: convection including mantle plumes, slab pull & ridge push
similarities between continental drift hypothesis and plate tectonic theory
plates move around
pangea happened
tell you that the earth’s surface changes and moves
number of tectonic plates
7 big (definite) + 13 small = roughly 20
Mid-ocean Ridge
form at divergent plate boundaries
form as result of seafloor spreading
warm mantle rises and fills in the separated part between divergent boundaries
Pole Reversal
when the magnetic north pole switches from being at the geographical south pole to being at the geographical north pole, or the opposite
Frederick Vine and Drummond Matthew
scientists that interpreted the data that showed bands of equal with and polarity as products of steady creation of new ocean crust over geologic time
Reverse Polarity
when the magnetic north pole is geographical south pole
Normal Polarity
when the magnetic north pole is geographical north pole
Paleomagnetism
Earth is a giant magnet with a magnetic field and poles
Every 200-300k years magnetic poles of Earth reverse places
Today we are at Normal Polarity but when the South pole is the magnetic pole, it’s called Reversed Polarity
evidence that supports seafloor spreading
bands of equal width and polarity
mid ocean ridges
age of ocean floor
Basalt
makes up oceanic crust
denser than continental crust
Granite
makes up continental curst
less dense than oceanic crust
Peridotite
makes up mantle
denser than continental AND oceanic crust
Collisional Mountain Range
result of convergent cc boundary
Continental Volcanic Arc
formed from formation of mountain ranges on the continental crust side due to convergent O-C boundaries
Convergent Boundary
→←
when plates move together
Divergent Boundary
←→
plates move apart
Place where new crust is created at rift valleys or mid-ocean ridges
Mild volcanic eruptions and shallow earthquakes
Transform Boundary
↑↓
tectonic plates move horizontally past each other
Earthquakes (shallow)
No up or down motion
No volcanism
No subduction
O-C convergent boundary
Oceanic crust subducts and pushes continental crust upward
forms mountain ranges on continental crust side (continental volcanic arcs)
forms trench in the ocean floor where subduction begins
explosive volcanoes and earthquakes (shallow and deep)
C-C convergent boundary
Overriding of one continental plate over another
Formation of collisional mountain ranges
Earthquakes are common (shallow and deep)
No volcanoes
No subduction of continental crust here
O-O convergent boundary
older oceanic crust is usually more dense and subducts
forms of a volcanic island arc
Formation of trench in the ocean floor where subduction begins
explosive volcanoes and earthquakes (shallow and deep)
Lithosphere
mechanical layer of earth
crust and the upper part of the mantle
rigid, brittle, elastically (snaps)
solid
Asthenosphere
mechanical layer of earth
upper part of the mantle
between lithosphere and mesosphere
has plasticity (flows)
solid
Mesosphere
mechanical layer of earth
part of mantel below asthenosphere and above outer core
peridotite
solid but flows slowly
Outer Core
mechanical layer of earth
below mesosphere, above inner core
liquid
Inner Core
mechanical layer of earth
most inner layer, below outer core
solid
Crust
Compositional layer of earth
oceanic and continental
thin, solid, brittle
outermost layer
oceanic and continental
basalt and granite
Core
Compositional layer of earth
iron nickel alloy
inner and outer
innermost layer
densest and hottest layer
Mantle
Compositional layer of earth
solid but has plasticity,
upper and lower
between core and crust,
has convection currents
peridotite
Moho
a discontinuity where seismic waves accelerate
boundary between the crust and mantel
thicker under continents
moho full name
Mohorovičić Discontinuity
discontinuity
where seismic waved change velocity
Pillow Basalt
when basaltic lava erupts underwater and cools quickly to form round bulges
Ridge push
gravity driven force that results from elevated position on oceanic ridge
slabs of lithosphere slide down flanks of ridge
less common than slab pull
Slab pull
subduction of oceanic lithosphere into asthenosphere
Hot Spots
rising plume of hot mantle
plumes stay, plates move, volcanic island chains created
reason why some volcanos are not on plate boundaries
located randomly in mantle
Tectonic Plate
pieces of rigid solid lithosphere that move around on top of the asthenosphere
Harry Hess
navy admiral turned seafloor-studying geologist
gained interest and questions about young oceanic crust and lack of sediment on seafloor from navy travels
published seafloor spreading hypothesis with Tharp’s + Heezen’s research
revived interest in Wegner’s pangea
Alfred Wegener
german meteorologist and interdisciplinary scientist
wrote origins of continents and oceans
proposed pangea
made continental drift hypothesis
Marie Tharp and Bruce Heezen
mapped the seafloor using new sonar technology
found that seafloor was not flat
found that a huge mountain ranged runs through middle of atlantic
Sonar
technology that uses sound waves to measure depth. one measures how long it takes them to bounce back
Rift Valley
result of divergent plate boundary
second stage of rifting (before formation of new ocean)
often forms large deep lakes
Seafloor Spreading
As the plates move away from each other, asthenosphere rises to surface and melts (lower pressure). Once it cools, new ocean crust is created.
The continents “grow” apart as new crust forms between them
driven by convection in mantle
why the plates move
convection currents in mantle
Subduction
sinking of lithosphere into the asthenosphere
denser plate pushed under
happens at convergent boundaries
Trench
forms due to subduction
form at O-O and O-C boundaries
Volcanic Island Arc
form at O-O convergent boundaries from the melting of the subducted oceanic lithosphere
Plate Tectonics Theory
Tectonic plates with continents and ocean crust move as one slab across asthenosphere
driving mechanism is convection including mantle plumes, slab pull & ridge push
Evidence: moving plates supported by age of ocean floor, shape of ocean floor, geomagnetic reversals on ocean floor, hotspot chains, locations of earthquakes and volcanoes
Pangea
supercontinent proposed by Wegner that split 200 millions years ago
Continental Drift Hypothesis
Continents move independent of oceanic crust, even plough through oceanic crust
No science based driving mechanism
Evidence: if they used to be together and now they are not… Coastlines matchup, Fossils, Mountain ranges and rocks and glacial evidence
Upwelling
the force of convection that pushes a divergent boundary up and out
Failed rift
when a plate starts to tear apart and for some reason it stops
leaves scar stuck at the beginning of the rifting process
kinds of convergent boundaries
C-C
O-C
O-O
where trenches form
O-C convergent and O-O covergent boundaries
where volcanic island arcs form
O-O convergent boundaries
where continental volcanic arcs form
O-C boundaries
where mid-oceanic ridges form
divergent boundaries
where rift valleys form
divergent boundaries
where narrow seas form
divergent boundaries
where oceans form
divergent boundaries
where collisional mountain ranges form
C-C convergent boundaries
where earthquakes occur
transform, divergent, and all convergent boundaries
where volcanos occur
all convergent boundaries
boundaries that create lithosphere
divergent boundaries
boundaries that destory lithosphere
all convergent boundaries
Compositional layers of earth (in to out)
core, mantle, crust
mechanical layers of earth (in to out)
inner core, outer core, mesosphere, asthenosphere, lithosphere
how fast tectonic plates move
how fast fingernails grow
Wegener’s 4 lines of evidence for the Continental Drift hypothesis
continents fit together like puzzle pieces
fossils match and solves fossil problems
rocks and mountain ranges match
solves paleoclimate problems (glacial striations)
the great weakness of the continental drift hypothesis
there was no explanation/science to why they moved or how
what Harry Hess contributed to our knowledge about plate tectonics
mid-Atlantic Ridge was a spreading center (divergent boundary), a place where two “plates” move apart and it was driven by convection in mantle.
why so little sediment accumulated on the ocean floor
why there are fossils no more than 180 million years in oceanic crust
what Vine and Matthews contributed to our knowledge about plate tectonics
supported Hess’ sea floor spreading by interpreting the magnetic stripes as products of steady creation of new ocean crust over geologic time
what Tharp and Heezen contributed to our knowledge about plate tectonics
they made a map of the depth of the seafloor which found that it was not flat and that there was a mountain range running down the middle of each ocean
5 pieces of evidence for plate tectonics theory
Shape of the Ocean Floor
Age of the Ocean Floor
Locations of Volcanoes and Earthquakes
Hotspots
Paleomagnetism
how the moho was discovered
in 1909, dude realized that velocity of a seismic wave relates to density of material is moves through
he interpreted the acceleration of seismic waves observed within Earth's outer shell as an interior compositional change
acceleration must be caused by a higher density material being present at depth
calculations determined that the oceanic crust and continental crust are underlain by a material which has a density similar to an olivine-rich rock such as peridotite.
slope of O-O convergent boundary
steep
slope of O-C convergent boundary
not steep
steepest sloped convergent boundary
O-O of similar age and densities
how steepness of subducting plate slope of is affected
if the two plates are of similar densities, then the slope will be steeper
Note
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