Endogenic Processes of the Earth PDF

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This document is lecture notes on the Endogenic Processes of the Earth, focusing on topics like plate tectonics and continental drift. The lecture notes outline several theories and evidence related to Earth's processes and structure.

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Endogenic Processes of
the Earth
Course Outcome 5
GEO01 – Earth Science

Materials Prepared by: Ryo Jerome C. Tuzon, LPT
Video Lecture Prepared by: Perseval S. Pineda, LPT
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Plate Tectonics: The
Unifying Theory
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Plate Tectonics
Plate Tectonics – Earth’s
surface is composed of a few
large, thick plates that move
slowly and change in size
Plate boundaries – plates
move away, toward, or past
each other through intense
geologic activity
Developed from the Source: W. Hamilton, U.S.

continental drift and seafloor Geological Survey

spreading hypotheses
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The Major Plates of the World
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The Early Case for
Continental Drift
Puzzle-piece fit of coastlines of Africa
and South America has long been
known
Alfred Wegener – noted South
America, Africa, India, Antarctica, and
Australia have almost identical late
Paleozoic rocks and fossils in early
1900s
Glossopteris (plant), Lystrosaurus
and Cynognathus (animals) fossils
found on all five continents.
Mesosaurus (reptile) fossils found in
Brazil and South Africa only.
Source: C.R. Scotese
(www.scotese.com)
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Pangaea
Pangaea – supercontinent proposed by
Wegener
Laurasia - northern supercontinent
Source: Arthur Holmes, Principles of
Physical Geology, 2nd ed., Ronald Press,
containing North America and Asia
1965. (excluding India)
Gondwanaland - southern supercontinent
containing South America, Africa, India,
Antarctica, and Australia
Late Paleozoic:
Glaciation patterns were evident on the
southern continents (Gondwanaland)
Coal beds deposited in the northern
continents from swampy, probably warm
environments (Laurasia)
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Paleoclimate Belts and
Polar Wandering
Paleoclimate belts – suggested polar
wandering as potential evidence for
continental drift.
Polar Wandering – the apparent movement
of the poles
The evidence for this can be explained in three
ways:
1) The continents remained motionless and the
poles actually moved (polar wandering).
2) The poles did not move and the continents
moved (continental drift).
3) Both occurred.
Source: A. Wegener, The Origins of Continents and Oceans (19 28),
Dover Publications, 19 68
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Skepticism About Continental Drift
Skepticism About Continental Drift
Land Bridges – could explain the distribution
of land-dwelling reptiles on scattered
continents
Winds or Oceans currents – could explain
distribution of fossil plants on separate
continents
Polar Wandering – could be explained by
moving poles rather than moving continents
Mechanism – Wegener’s proposed mechanism was not accepted by most
geologists in the northern hemisphere
His idea that the continents plowed through the oceans propelled by
centrifugal forces from the Earth’s rotation and gravitational forces that
cause the tides were proven to be insufficient.
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The Revival of Continental
Drift
Paleomagnetism – the study of ancient
magnetic fields
The mineral magnetite becomes
magnetized in cooling lava once its
temperature drops below the Curie Point.
Uses mineral magnetic properties to
determine direction and distance to the
magnetic pole when rocks formed.
Steeper dip angles indicate rocks formed
closer to the magnetic poles.
Rocks with increasing age point to pole
locations increasingly far from present
magnetic pole positions.
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Evidence from
Paleomagnetism
Apparent polar wander curves
for different continents suggest
real movement relative to one
another.
Permian rocks in every continent
show a different pole position
which seems highly unlikely.
By reconstructing their locations to
form Pangaea, the polar wandering
paths are nearly identical
indicating that the continents were
once joined together.
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Geologic Evidence for Continental
Drift
Fitting of Continents:
Redefined the edge of each continent as the middle
of the continental slope greatly improved the fit
Isotopic ages, glacial striations, rock types, structure
and sequence match
History of Continental Positions:
Rock matches show when the continents were
together
Paleomagnetic data indicate the direction and rate
of movement
Pangaea split apart 200 million years ago but the
continents have been in motion for much longer (2
to 4 billion years)
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Seafloor
Spreading
Seafloor spreading – the
concept that the sea floor is
moving like a conveyor belt away
from the crest of the mid-oceanic
ridge until it disappears by
plunging beneath a continent or
island arc. Proposed in 1962 by
Harry Hess
Hess’s Driving Force
Deep Mantle Convection –
circulation pattern driven by
rising of hot material (hot mantle
rock) and/or the sinking of cold
material (oceanic crust) Seafloor_spreading (viddler.com)
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Explanations
The Mid-Oceanic Ridge
Hot mantle rocks rises beneath.
Decompression melting occurs.
Circulation pattern diverges moving rock away from the ridge.
Rift valley forms due to tensional forces at the ridge crest.
Oceanic Trenches
Rock has cooled and become denser.
Crust Sinks beneath a continent or island arc back into the mantle.
Age of the Sea Floor
Overall young age for sea floor rocks (everywhere 500
km.
Typically covered with young
sediments.
Continental slopes – relatively steep
slopes that extend down from the edge
of the continental shelf to the abyssal
plain.
 Submarine Canyons
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Submarine canyons – V-shaped valleys that run across continental
shelves and down continental slopes.
Deliver continental sediments to abyssal fans on deep sea floor.
Turbidity currents – great masses of sediment laden water that
flows down the continental slope.
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Passive Continental Margins
Includes a shelf, slope and rise extending
down to an abyssal plain.
The Continental Rise – gently seaward-
sloping (0.5°) wedges of sediments extending
from base of continental slope to deep sea
floor.
Sediment deposited by turbidity and
contour currents.
End at abyssal plain at depth of about 5
km.
Lie upon oceanic crust.
Abyssal plains – extremely flat regions
beyond the base of the continental rise.
Flattest features on Earth, with slopes