Marine Environment (Oceanography Geology) PDF

Summary

This document provides an overview of the marine environment, focusing on topics like Earth's internal structure, plate tectonics, seafloor features, and marine sediments. It includes diagrams illustrating these concepts. It is likely lecture/presentation materials.

Full Transcript

MARINE ENVIRONMENT
Oceanography Geology
Sub-topics:

Earth internal structure
Plate tectonic
Seafloor features
Marine sediments
Internal Structure of the
Earth
Internal Structure of the Earth

You will learn about:

- External shape of the Earth
- Internal structure and various layers
- Crust, Mantle, Core
- Discontinuities (e.g. Moho, Gutenberg, Lehmann)
- Evidence of Earth’s interior structure
 Fundamental particles formation

(13.7 BY ago)

Galaxies and Star formation

Solar
System
External shape of the Earth

The earth is not quite
a perfect sphere but
an ‘oblate’ (bun
shaped) ellipsoid close
to that of an ideal
fluid drop rotating at
the same velocity as
the Earth. There is
more mass along the
equatorial diameter
than the polar
diameter.
 External shape of the Earth

Perfect circle
(~43 km shorter) The earth is not quite
a perfect sphere but
an ‘oblate’ (bun
shaped) ellipsoid close
to that of an ideal
fluid drop rotating at
the same velocity as
the Earth. There is
more mass along the
equatorial diameter
than the polar
diameter.
 Earth’s
Interior
Core
▪ dense
▪ Iron and Nickel
Crust
▪ Inner Core - solid
▪ Outer Core -
Upper
Mantle liquid
Mantle
Lower
Mantle ▪ Less dense than core
Outer
Core Inner ▪ Iron and Magnesium silicates
Core
▪ Mostly solid
▪ Upper mantle is partially
molten
Crust
▪ Outermost layer
▪ Very thin and rigid
▪ Continental – granite
▪ Density = 2.8 g/cm3
▪ Oceanic – basalt
▪ Density = 3.0 g/cm3
 Small
Formation of Earth’s layers
The Earth formed through accretion,
undifferentiated Absorbing planetisimals (lumps of rock
Undifferentiated
bodies and ice? through collisions.
bodies
Earth may be accreted material that
undifferentiated then shell and
separatedthat
material then
shell andseparated
core and reach its present
into
form differentiating
Core before. formation
formation Alternatively, might inside
core growing
have combination theseof
happene
formed cores. previous
planetisimals,
d so thelyEarth’s core
is
Differentiated
Present Earth
bodies with cores

Minarik (2003), Nature
 Internal Structure of the Earth
Mountain
Sediment
Sea
The interior structure of the
Earth is layered in spherical
shells, like an onion. The
interior of Earth is divided
into several layers.
Chemically, Earth can be
divided into 5 layers such as
the crust, upper mantle,
lower mantle, outer core
0
Crust
and inner core.
Mantle
6371
km Core

Earth
 Internal Structure : The
Crust Sediment Basalt
Granite
Sea

Oceanic
crust Continental crust
(5 ~ 10 km) (30~70 km)

The crust is the outermost solid shell of the
Earth, which is chemically distinct from the
underlying mantle. The crusts of Earth have
been generated largely by igneous processes,
and these crusts are richer in incompatible
elements than their respective mantles. The
crust of Earth’s occupies less than 1% volume
and is devided into oceanic and continental
crust.

The outermost shell of a rocky planet is
defined on the basis of its chemistry and
mineralogy.
 The Crust: Explained

Basalt Granite

]
]
Crust

Oceanic crust is a thin part of the earth's crust that underlies the ocean basins. It is
geologically young compared with the continental crust and consists of basaltic rock
overlain by sediments.
Continental crust is a thick part of the earth's crust that forms the large landmasses. It
is generally older and consists of many rock types including granite as a dominant
rock. Below the Earth’s crust lies the mantle. Lithosphere is the rigid outer part of the
earth, consisting of the crust and upper mantle.
 Moho Discontinuity
Sediment
Sea

Lithosphere
(Crust+ upper
mantle)
Moho The boundary between the Earth’s crust and
Discontinuity mantle is called the Moho discontinuity and
Average ~ 35
is defined by a contrast in seismic velocity. It
km below the
crust. separates both the oceanic crust and
continental crust from underlying mantle.
The Moho lies from 5 to 10 km below the
ocean floor and 20 to 90 km beneath the
continents.
A lithosphere is the rigid, outermost shell
and comprises the crust and the portion of
the upper mantle that behaves elastically.
The Moho lies almost entirely within the
lithosphere.
 The Mantle
Sediment
Sea

The mantle is a layer inside the
Earth and lies between the outer
Lithosphere core and the crust above. Earth's
mantle is a silicate shell with an
average thickness of 2,800 km.
Asthenosphere
The mantle makes up about 84%
of Earth's volume. It is
predominantly solid but in
geological time it behaves as a
viscous fluid. Earth’s mantle is
chemically divided into two
layers; upper mantle and lower
mantle.
 Lithosphere and Asthenosphere
Sediment
Sea

Lithosphere The lithosphere is the rigid outer
70~150 km part of the earth, consisting of the
of crust and a part of the upper
mantle.
Asthenosphere
The asthenosphere is highly
150 ~700 km
viscous, mechanically weak and
deforming region of the upper
mantle of the Earth. It is the upper
layer of the earth's mantle and
below the lithosphere.
 Gutenberg Discontinuity
Sea
Sediment Gutenberg discontinuity represents
the core-mantle of the Earth
boundary (CMB)and lies between
Lithosphere
the mantle, the lower iron-nickel
liquid and outer core.
This boundary is located at
Asthenosphere
approximately 2880 km depth
beneath the Earth's surface. The
boundary is observed via the
Gutenberg discontinuity in seismic wave
Discontinuity velocities at that depth. At this
depth, primary seismic waves (P
waves) decrease in velocity
while secondary seismic waves
(S waves) disappear completely.
 The Core
Sediment
Sea
The outer core of the Earth is a
liquid layer about 2,300 km
thick and composed of iron and
nickel that lies above Earth's
solid inner core and below its
mantle. Its outer boundary lies
2,880 km beneath Earth's
surface. The transition between
the inner core and outer core is
located approximately 5,155 km
beneath the Earth's surface.
The inner core the Earth's
innermost and it is ball
primarily is with a
radius of about
part 1220 km. It is
believed toa consist primarily of
an iron–nickel alloy.
6371 km solid
Outer Core and Earth’s magnetic field

The Earth has a magnetic
field and acts as a giant
bar magnet.
Scientists believe that the
outer movements Earth’s
liquid core create Earth’s
magnetic field. It is the
earth’s field magnetic that
protects us from the
harmful effects of solar
winds.
 Lehmann Discontinuity
Sediment
Sea

Lithosphere
The Lehmann discontinuity
Asthenosphere is abrupt increase of P-wave
and S-wave velocitiesand
separates the liquid outer
Lehmann core from the solid inner
Discontinuity core.

6371 km
 Density (ρ) of the Earth’s layers
Sediment
Sea
ρ ~ 2.7 g/cm3

ρ ~ 3.3 g/cm3
Lithosphere ρ ~ 3 g/cm3

Asthenosphere

ρ ~ 5.5 g/cm3

ρ ~ 9.5 g/cm3

ρ ~ 11.5 g/cm3

The density (ρ) increases from about 2.7
ρ ~ 12 g/cm3 g/cm3 in the upper crust and reaches about
6371 km
12 g/cm3 to the inner core of the Earth.
 Behavior of the Earth’s layers
Sediment
Sea
SIMA is the name for the lower layer of the
SiAl Earth's crust which is made of rocks rich
Rigid
in magnesium silicate minerals.
Typically when the sima comes to the
Lithosphere
surface it is basalt and is the lowest layer of
the crust. Because the ocean floors are
mainly sima, it is also sometimes called the
Asthenosphere
'oceanic crust'.
The name 'sima' was taken from the first
two letters of silica and of magnesium.
Rigid/Solid Comparable is the name 'sial' which is the
name for the upper layer of the Earth's
continental crust, rocks rich in silicates and
aluminium minerals. As these elements are
less dense than the majority of the earth's
Liquid
(Ni & Fe)
elements, they tend to be concentrated in
the upper layer of the crust.
Core is rich in nickel (Ni) and iron (Fe)
Solid contents.
(Fe, Ni & S)

6371 km
 Seismic waves through the Earth
P Waves 6.0 km/sec

S Waves 3.5 km/sec

How do we know the structure of the earth? Seismology is the scientific study of
earthquakes and the propagation of elastic waves (Primary (P) and Secondary (S) waves)
through the Earth’s layers.
 6.0 km/sec 2.5 km/sec

3.0 km/sec
3.5 km/sec

A seismic wave is a wave that travels through the Earth, often as the
result of an earthquake or explosion. Differences in density and other
physical properties affect the velocity of seismic waves.
Isostasy
Isostasy is the state of gravitational
equilibrium between Earth's crust
and mantle.
Balance of adjacent rocks of brittle
crust that float on the plastic
mantle.
For example wood blocks float in
water with most of their mass
submerged.
Crustal blocks “float” on mantle in
a similar way. The thicker the block
the deeper it extends into the
mantle.
Oceanic crust (e.g. dominantly
basalt) is heavier, denser but less
in thickness than the continental
crust (e.g. mostly granite).
Convection Currents

Convection currents are caused by
the hot material at the deepest part
of the mantle rising, then cooling
and sinking again, repeating this
cycle over and over.
It is like hot water in a pan that
has convection

currents move in
liquid. the
When
currents the flow in
the
asthenosphere convecti
on move also
they
the crust.
Exercise: Internal Structure of the
Earth
Exercise: Internal Structure of the
Earth
12
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11
2
10
3
9

4

8
5

7

6
 Plate Tectonics

You will learn about;
- Plate tectonics
- Seafloor spreading and continental drift
- Minor, minor and micro plates
- Sunda Plate
-Types of plate boundaries
- Distribution of volcanoes and earthquake
 What is plate tectonics?
Plate tectonics (Greek word meaning pertaining to building) is a
scientific theory that describes the large-scale motion of Earth's
lithosphere. It builds on the concept of continental drift and
seafloor spreading.

The Earth’s crust and upper
mantle (lithosphere) are
broken into sections called
plates. Plates move around
on top of the mantle like
rafts. Pate-tectonic theory
was accepted after seafloor
spreading was validated in
the late 1950s.
 Earth’s internal layers: Lithosphere
Sea

Lithosphere
(Crust+
upper Tectonic plates are
mantle) Earth's crust piece
uppermost
and
mantle, together sreferred to
of as
the lithosphere. The plates
consist of two principal types of
material: oceanic crust (called
sima from silicon and
magnesium) and continental
crust (sial from silicon and
aluminium). The lithosphere is
the rigid outer part of the
earth, consisting of the of crust
and a part of the upper mantle.
The crust is the outermost solid
shell of the Earth.
 WHO?

Alfred Lothar Wegener
1880-1930 | Berlin, Germany | Meteorologist & Polar researcher |
http://www.famousscientists.org/alfred-wegener/

UNIVERSITI MALAYSIA TERENGGANU
 WHO THOUGHT OF IT?
Wegener’s theory hypothesized that the continents
were able to push through the rock of the seafloor to
their present position
1960 Scientific discoveries
about seafloor spreading
combined with earlier
theories of continental drift,
led to theory of plate
tectonics
1950 Theory finally accepted

PANGEA - Evidence
suggests that the
continents were once
joined into a single
1915 Fossils from different continents, now far apart, are continent
mostly the same. The coastline of Africa & South America look
like they are supposed to fit together.
 CONTINENTAL DRIFT

Permian Triassic
250 mya 200 mya

Cretaceous Present day
65 mya 65 mya
UNIVERSITI MALAYSIA TERENGGANU
FOSSIL EVIDENCE

UNIVERSITI MALAYSIA TERENGGANU
 EARTH’S MAGNETIC POLES
Some minerals have magnetic
properties, in molten rock the
magnetic properties line up in
relation to Earth’s magnetic poles.
When the rocks harden, a
permanent record of the Earth’s
magnetic poles are revealed.
Scientists discovered that on each
side of the midocean ridges there
were magnetic stripes.
The stripes showed that at several
times in Earth’s history, the
magnetic poles have reversed. The
stripes matched up on each side of
the midocean ridge. This discovery
added more evidence to support
ocean-floor spreading.

UNIVERSITI MALAYSIA TERENGGANU
EARTH’S MAGNETIC POLES

UNIVERSITI MALAYSIA TERENGGANU
 What is continental drift?
Continental drift is the movement of the Earth's continents relative to
each other, thus appearing to "drift" across the ocean bed. A continent is
one of several very large landmasses on Earth. There are up to seven
regions commonly regarded as continents. Convection currents in Earth’s
mantle drag along tectonic plates.
 Seafloor Spreading
Seafloor spreading is a process that occurs at mid-ocean ridges, where new oceanic
crust is formed through volcanic activity and then gradually moves away from the
ridge. Seafloor spreading helps explain continental drift in the theory of plate
tectonics.

Age of Oceanic
Lithosphere
 Seafloor spreading:
Example

Atlantic Ocean

Pacific Ocean

Transform Faults

Indian Ocean
 How many major plates are there?
Seven major plates (area > 10 million km 2): Pacific North
American
Plate, Plate, Eurasian Plate, African Plate , Antarctic Plate,
Indo-
Australian Plate, and South American Plate.

North Eurasia
American n Plate
Plate

African
Pacific Plate Plate

South
American Indo-
Plate Australia
n Plate

Antarctic
Plate
 How many minor plates are there?
More than nine minor plates (area 1 million km2 ): Nazca Plate, Philippine Sea
Plate, Arabian Plate, Caribbean Plate, Cocos Plate, Caroline Plate, Scotia Plate, Burma
Plate, and New Hebrides Plate

JDF Plate

Caribbean Indian
Plate Plate

Scotia Plate
 How many micro-plates are there?
There are about 60 micro-plates (area