Earthquakes.pdf

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Earthquake
by Janine Hilario
& Allen Lauson
 EARTHQUAKE

An earthquake is the shaking of
the Earth's surface caused by the
sudden release of energy in the
Earth's crust. This release of
energy creates seismic waves that
cause the ground to shake.
TYPES OF EARTHQUAKES
BASED ON THEIR CAUSES

1. Tectonic earthquake

2. Volcanic earthquake

3. Man-made earthquake
 TYPES OF EARTHQUAKES
BASED ON THEIR CAUSES
1. Tectonic earthquake

occurs when there is a sudden release of
energy in the Earth's crust due to the
movement of tectonic plates

95% of all earthquakes are tectonic
earthquakes
 TYPES OF EARTHQUAKES
BASED ON THEIR CAUSES
2. Volcanic Earthquake

Volcanic earthquakes are associated with
volcanic activity and are caused by
vibrations generated by the movement of
magma or other fluids within the volcano
 TYPES OF EARTHQUAKES
BASED ON THEIR CAUSES
3. Man-made Earthquake

Also called induced seismicity, can occur
due to human activities such as fluid
extraction and mining.
 TREMOR VS EARTHQUAKE

Tremors are generally regarded as milder
seismic vibrations that occur as a result of
minor stress adjustments within the Earth’s
crust.

The main difference between an earthquake
and a tremor is in their magnitude.
 TECTONIC
EARTHQUAKES
MECHANISM
TECTONIC
PLATES
Tectonic plates are large, rigid pieces of the
Earth's lithosphere (the outer layer of the
Earth consists of upper mantle and crust) that
fit together like a puzzle, covering the entire
planet's surface.

These plates move slowly over the semi-fluid
asthenosphere, which lies beneath them.

Their movement is driven by forces such as
convection currents in the Earth's mantle,
gravity, and the Earth's rotation.
Tectonic plate boundaries are the edges
where two or more tectonic plates meet, and
they are classified based on how the plates
interact.

Over geological time, the movement of the
mantle beneath the plates causes them to
shift, break, and interact, leading to the
creation of faults at their boundaries.
 STRESS AND STRAIN

Stress is the force applied per unit area on a material. It
quantifies how much force is acting on a given area of a
rock or material, causing deformation.

There are three kinds of stress that act on Earth’s rocks:

Tensive Stress - occurs when forces pull apart

Compressive Stress - occurs when forces push together

Shear Stress - occurs when forces slide past each other

Strain is the deformation that results from the applied
stress. It represents the change in shape or size of a
material compared to its original dimensions.
STRESS AND STRAIN
 ELASTIC REBOUND THEORY
The gradual accumulation and release of stress and strain is now referred to as
the "elastic rebound theory" of earthquakes. Most earthquakes are the result of
the sudden elastic rebound of previously stored energy.
FAULTS
A fault is a fracture or zone of
fractures in the Earth's crust
along which there has been
movement of the rock.

Fault is the area directly
above where two tectonic
plates interact.
 TYPES OF FAULTS
1. NORMAL FAULT
This is the most common type of
fault.

It forms when rock above an
inclined fracture plane moves
downward, sliding along the
rock on the other side of the
fracture.

Normal faults are often found
along divergent plate
boundaries.
 TYPES OF FAULTS
2. REVERSE FAULT

The opposite of a normal fault.

A reverse fault forms when the
rocks on the “uphill” side of an
inclined fault plane rise above
the rocks on the other side.

Reverse faults often form along
convergent plate boundaries.
 TYPES OF FAULTS
3. STRIKE-SLIP FAULT

Sometimes referred to as a lateral
fault, this type forms when the
blocks of rock on either side of a
vertical (or nearly vertical) fracture
move past each other.
A visible normal faulting.
Example of reverse faulting.
Example: The San Andreas
Fault is a strike-slip fault that
marks the boundary between
two major tectonic plates: the
Pacific Plate and the North
American Plate
FOCUS AND
EPICENTER
 FOCUS
The point inside the Earth where an
earthquake originates.

Causes seismic waves to
propagate in all directions.

Indicates the point of origin and
releases energy during an
earthquake.
 epicenter
The point on the Earth's surface
directly above the origin of an
earthquake.

Indicates the point of maximum
damage on the Earth's surface.
SEISMIC
WAVES
 SEISMIC WAVES
Seismic waves are the waves of energy
that travel through the Earth as a result
of a sudden release of energy in the
Earth's crust. These waves cause the
ground to shake and are the reason we
feel earthquakes.

Two Types:
Body Waves and Surface Waves
 body waves
Body waves travel through the interior of the Earth and are the first waves to
be detected by seismographs during an earthquake.

Two types:

P (Primary) Waves: Compressional
waves that push and pull the ground
in the direction the wave is traveling.

S (Secondary) Waves:
Shear waves that move the ground
side-to-side, perpendicular to the
direction of wave travel.
 SURFACE WAVES
Surface waves travel along the Earth's surface and cause the most damage during an
earthquake. They travel more slowly than body waves but produce larger ground
movements.

Two types:

Love Waves:
They only move through the Earth's
crust and cause horizontal shearing of
the ground.
Rayleigh Waves:
They cause the ground to move in an
elliptical, rolling motion, with both
vertical and horizontal displacement.
 earthquake
measurement
Magnitude:
Magnitude measures the energy released at the source of the earthquake.
Magnitude is typically measured using seismographs, which record the seismic
waves produced by an earthquake.

Intensity:
Intensity measures the effects of an earthquake at specific locations, assessing
how much shaking is felt and the resulting damage.
It is a qualitative measure and can vary significantly from place to place.
thank you