Week 8 Electromagnetic Waves PDF

Summary

This document provides an overview of electromagnetic waves, covering their discovery, properties, types, and applications. It explains concepts like propagation, spectrum, and the different types of electromagnetic radiation, including radio waves, infrared, and visible light. It also discusses the properties of each type of wave, such as energy, frequency, and wavelength.

Full Transcript

WEEK 8

ELECTROMAGNETIC
WAVES
 DISCOVERY
 PROPERTIES
 Types of Electromagnetic
Radiation
TERMINOLOGIES
Propagation - The act or process of propagating, especially the
process by which a disturbance, such as the motion of
electromagnetic or sound waves, is transmitted through a medium
such as air or water.
Spectrum - the arrangement according to the wavelength of visible,
ultraviolet, and infrared light.
Electromagnetic radiation - the flow of energy at the universal
speed of light through free space or through a material medium in the
form of the electric and magnetic fields that make up electromagnetic
waves.
Discovery of
Electromagnetic Waves
JAMES CLERCK MAXWELL

His discovery is first
commented on.
Maxwell had proved that
light was an
electromagnetic wave. In
1865 Maxwell wrote down
an equation to describe
these electromagnetic
waves
HEINRICH HERTZ
Heinrich Hertz
demonstrated the
generation and detection
of radio waves in 1887,
eight years after
Maxwell’s death.
Hertz also showed that
these waves travel at
the speed of light (as
predicted by Maxwell).
PROPERTIES of
ELECTROMAGNETIC WAVE
1. Transverse waves
Both fields are perpendicular to
the propagation direction

2. Light is an Electromagnetic 4. Electromagnetic waves carry
wave energy and momentum
An electromagnetic wave, although it
The value of the speed of light is
carries no mass, does carry energy. It
3 × 108 m/s is also the value of an
also has momentum and can exert
electromagnetic wave.
pressure (known as radiation pressure).
3. Can travel through a vacuum 5. They obey the equation c = fλ.
Because of the existence of Here, f is the frequency in Hertz and λ is
electric and magnetic fields in a the wavelength meters. The product of
vacuum wavelength and frequency is equal to a
constant c, the speed of light which is
equal to 3 × 108 m/s.
 DESCRIBING
ELECTROMAGNETIC
ENERGY
 The terms light, electromagnetic waves and radiation
all refer to the same physical phenomenon:
Electromagnetic energy
This energy can be described by
1. Frequency – measured in Hertz (Hz); radio waves and
microwaves
2. Wavelength – measured in wavelength (meters);
infrared rays and visible light
3. Energy – measured in electron Volts (eV) ; x-rays and
gamma rays
 TYPES of
ELECTROMAGNETIC
RADIATION
ELECTROMAGNETIC RADIATION
the flow of energy at the universal speed of light through free space or a
material medium in the form of the electric and magnetic fields that make up
electromagnetic waves.
RADIO WAVES
Radio waves are at the
lowest range of the EM
spectrum.
Radio is used primarily for
communications including
voice, data, and
entertainment media.
MICROWAVES
Microwaves fall in the
range of the EM
spectrum between radio
and IR.
used for high-bandwidth
communications, radar,
and as a heat source for
microwave ovens and
industrial applications.
INFRARED
RADIATION (IR)
Infrared is in the range of the
EM spectrum between
microwaves and visible light.
IR light is invisible to human
eyes, but we can feel it as
heat if the intensity is
sufficient.
Commonly used as heat
sensors
VISIBLE LIGHT
Visible light is found in
the middle of the EM
spectrum, between IR
and UV.
defined as the
wavelengths that are
visible to most human
eyes..
ULTRAVIOLET
Ultraviolet light is in the range
of the EM spectrum between
visible light and X-rays.
UV light is a component of
sunlight; however, it is
invisible to the human eye. It
has numerous medical and
industrial applications, but it
can damage living tissue.
X-RAYS
X-rays are roughly classified into two
types: soft X-rays and hard X-rays.
Soft X-rays comprise the range of the
EM spectrum between UV and gamma
rays. Hard X-rays occupy the same
region of the EM spectrum as gamma
rays.
The only difference between them is
their source: X-rays are produced by
accelerating electrons, while gamma
rays are produced by atomic nuclei.
GAMMA RAYS
Gamma rays are in the range of
the spectrum above soft X-rays.
Gamma radiation causes damage
to living tissue, which makes it
useful for killing cancer cells when
applied in carefully measured
doses to small regions.
Uncontrolled exposure, though, is
extremely dangerous to humans