INTERIOR OF THE EARTH.pdf

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Interior of the Earth

Rizalino F. Duoma
T3
Interior of the Earth

This module will
help you visualize
and understand the
composition and
structure of the
Earth’s interior.
Rizalino F. Duoma
T3
 Key Questions
1. How do the structure and composition
of the Earth cause geologic activities and
physical changes?

2. What are the possible causes of the
lithospheric plate movements?

3. What proves the movement of the
tectonic plates?
 Key Questions
The Earth is made up of three layers: the
crust, the mantle, and the core.

The study of these layers is mostly done in
the Earth’s crust since mechanical probes
are impossible due to the tremendous heat
and very high pressure underneath the
Earth’s surface.
 Key Questions
Activity No. 1
Objectives:
Define seismic waves scientifically.
Differentiate the different types of
seismic waves.
Recognize the importance of seismic
waves in the study of the Earth’s
interior.
 Key Questions

Construct your own
organizer that shows
necessary information and
summarizes the concept
about seismic waves.
 Key Questions
1. Differentiate surface waves from
body waves.

2. Which type of waves do you
think were useful to seismologists
in their study of the Earth’s
interior? Explain your answer.
 What are seismic waves?
1. Earthquake is a vibration of the
Earth produced by the rapid
release of energy.

2. This energy radiates in all
directions from the focus in the
form of waves called seismic
waves.
What are seismic waves?
 Types of Seismic Wave

1.Surface waves

2.Body Waves
 Surface Waves
Can only travel through the
surface of the Earth
arrive after the main P and S
waves
2 Types of Surface Waves
1.Love Waves
2.Rayleigh Waves
 Love Wave
Named after A.E.H. Love, a
British mathematician who
worked out the mathematical
model for this kind of wave in
1911.
 Love Wave
faster than Rayleigh wave
it moves the ground in a
side-to-side horizontal
motion, like that of a snake’s
causing the ground to twist
 Love Wave
cause the most damage to
structures during an
earthquake.
Love Wave
 Rayleigh Wave
named after John William
Strutt, Lord Rayleigh,
who mathematically
predicted the existence of
this kind of wave in 1885
 Rayleigh Wave
wave rolls along the ground just
like a wave rolls across a lake or
an ocean
up and down or side-to-side
similar to the direction of the
wave’s movement
shaking felt from an earthquake
Rayleigh Wave
 Body waves
can travel through the
Earth’s inner layers
they are used by scientists to
study the Earth’s interior
higher frequency than the
surface waves
 Body waves
2 types
P-Waves (Primary waves)

S-waves (Secondary waves)
 P-waves (Primary)
is a pulse energy that travels
quickly through the Earth
and through liquids
travels faster than the S-
wave
it reaches a detector first
 P-waves (Primary)
compressional waves, travel by
particles vibrating parallel to
the direction the wave travel
move backward and forward as
they are compressed and
expanded
 S-waves (Secondary/Shear)
pulse energy that travels
slower than a P-wave
through Earth and solids
 S-waves (Secondary/Shear)
Move as shear or transverse
waves, and force the ground to
sway from side to side, in
rolling motion that shakes the
ground back and forth
perpendicular to the direction
of the waves
 S-waves (Secondary/Shear)
cannot travel through any
liquid medium led seismologists
to conclude that the outer core
is liquid
Seismic Waves movement
 Cross section of the Earth as
seismic waves travel through it
 Cross section of the Earth as
seismic waves travel through it
Longitudinal waves travel through
both solids and liquids.

Transverse waves travel through solids only.
 Cross section of the Earth as
seismic waves travel through it
 Cross section of the Earth as
seismic waves travel through it
P-waves are detected on the other
side of the Earth opposite the
focus.

A shadow zone from 103° to 142°
exists from P-waves
 Cross section of the Earth as
seismic waves travel through it
P-waves are detected on the other
side of the Earth opposite the
focus.

A shadow zone from 103° to 142°
exists from P-waves
 Cross section of the Earth as
seismic waves travel through it
Since P-waves are detected until
103°, disappear from 103° to
142°, then reappear again,
something inside the Earth must
be bending the P-wave
 Remember
existence of a shadow zone,
according to German seismologist
Beno Gutenberg (ɡuː t ən bɛʁk), could
only be explained if the Earth
contained a core composed of a
material different from that of the
mantle causing the bending of the P-
waves
 Remember
To honor him, mantle–core boundary
is called Gutenberg discontinuity
 Remember
From the epicenter, S-waves are
detected until 103°, from that
point, S- waves are no longer
detected
S-waves do not travel all
throughout the Earth’s body
 Remember
knowing the properties and
characteristics of S-waves (that it
cannot travel through liquids), and
with the idea that P-waves are bent
to some degree, this portion must
be made of liquid, thus THE
OUTER CORE
 Remember
1936, the innermost layer of the
Earth was predicted by Inge
Lehmann, a Danish seismologist
discovered a new region of seismic
reflection within the core
Earth has a core within a core
 Remember
the outer part of the core is liquid
based from the production of an S
wave shadow and the inner part
must be solid with a different density
than the rest of the surrounding
material
 OUR HOME PLANET, EARTH
Our Earth is about
average among the
planets in the Solar
System, in many
respects:
OUR HOME PLANET, EARTH

Our Earth is
about average
among the
planets in the
Solar System, in
many respects:
OUR HOME PLANET, EARTH
largest and most
massive of the
four terrestrial
planets, but
smaller and less
massive than the
four giant, or
Jovian, planets
OUR HOME PLANET, EARTH
third in distance
from the Sun
among the four
terrestrial planets
OUR HOME PLANET, EARTH
has a moderately
dense atmosphere;
90 times less
dense than that of
Venus but 100
times denser than
that of Mars
OUR HOME PLANET, EARTH
OUR HOME PLANET, EARTH
Geology -the study of
the structure, history,
and activity of the
solid Earth, including
its interactions with
the atmosphere,
hydrosphere,
cryosphere, and
biosphere
The Composition of the Earth’s Interior
The Composition of the Earth’s Interior
The Composition of the Earth’s Interior
The Composition of the Earth’s Interior
The Composition of the Earth’s Interior
The Composition of the Earth’s Interior
The Composition of the Earth’s Interior
thinnest and the outermost
layer of the Earth that
extends from the surface to
about 32 kilometers below
Continental
Oceanic
The Composition of the Earth’s Interior
The Composition of the Earth’s Interior
mainly made up of silicon,
oxygen, aluminum, calcium,
sodium, and potassium
mostly 35-40 kilometers
found under land masses
made of less dense rocks
such as granite
The Composition of the Earth’s Interior
oceanic crust is around 7-10
kilometers thick which its average
thickness is 8 kilometers.
found under the ocean floor
made of dense rocks such as
basalt
heavier than the continental
crust.
The Composition of the Earth’s Interior
oceanic crust is around 7-10
kilometers thick which its average
thickness is 8 kilometers.
found under the ocean floor
made of dense rocks such as
basalt
heavier than the continental
crust.
The Composition of the Earth’s Interior
GRANITE -crystalline
igneous rock
composed primarily of
quartz and feldspar.
forms from slowly
cooling magma that is
subjected to extreme
pressures deep
beneath the earth's.
The Composition of the Earth’s Interior
BASALT -volcanic rock
forms from lava flows along
mid-ocean ridges and also in
igneous intrusions such as
dikes and sills.
Columnar jointing, pictured
here at Devil's Tower,
Wyoming, occurs when
molten basalt cracks as it
cools, producing separate,
polygonal fractures on the
surface of the rock.
The Composition of the Earth’s Interior
The Composition of the Earth’s Interior
While studying the speed of
earthquake waves, Croatian
geophysicist Andrija Mohorovičić
discovers a boundary between
Earth's crust and mantle, which
becomes known as the Mohorovičić,
or Moho, Discontinuity.