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Transcript 
Lecture 20



Electromagnetic Waves
Nature of Light
Reflection and Refraction
Fig. 22-CO, p.726
Electromagnetic Waves
are Transverse Waves


The E and B fields are
perpendicular to
each other
Both fields are
perpendicular to the
direction of motion

Therefore, em
waves are
transverse waves
Properties of EM Waves


Electromagnetic waves are transverse
waves
Electromagnetic waves travel at the
speed of light
c

1
 o o
Because em waves travel at a speed that is
precisely the speed of light, light is an
electromagnetic wave
Properties of EM Waves, 2

The ratio of the electric field to the
magnetic field is equal to the speed of
light
E
c
B

Electromagnetic waves carry energy as
they travel through space, and this
energy can be transferred to objects
placed in their path
Properties of EM Waves, 3

Energy carried by em waves is
shared equally by the electric and
magnetic fields
Average power per unit area 
2
2
Emax Bmax
Emax
c Bmax
I 


2o
2oc
2o
Properties of EM Waves,
final

Electromagnetic waves transport
linear momentum as well as
energy



For complete absorption of energy U,
p=U/c
For complete reflection of energy U,
p=(2U)/c
Radiation pressures can be
determined experimentally
Determining Radiation
Pressure



This is an apparatus
for measuring
radiation pressure
In practice, the
system is contained
in a vacuum
The pressure is
determined by the
angle at which
equilibrium occurs
The Spectrum of EM
Waves

Forms of electromagnetic waves
exist that are distinguished by
their frequencies and wavelengths



c = ƒλ
Wavelengths for visible light range
from 400 nm to 700 nm
There is no sharp division between
one kind of em wave and the next
The EM
Spectrum



Note the overlap
between types of
waves
Visible light is a
small portion of
the spectrum
Types are
distinguished by
frequency or
wavelength
Notes on The EM
Spectrum

Radio Waves


Used in radio and television
communication systems
Microwaves



Wavelengths from about 1 mm to 30
cm
Well suited for radar systems
Microwave ovens are an application
Notes on the EM
Spectrum, 2

Infrared waves




Incorrectly called “heat waves”
Produced by hot objects and
molecules
Readily absorbed by most materials
Visible light


Part of the spectrum detected by the
human eye
Most sensitive at about 560 nm
(yellow-green)
Notes on the EM
Spectrum, 3

Ultraviolet light




Covers about 400 nm to 0.6 nm
Sun is an important source of uv light
Most uv light from the sun is absorbed in
the stratosphere by ozone
X-rays


Most common source is acceleration of
high-energy electrons striking a metal
target
Used as a diagnostic tool in medicine
Notes on the EM
Spectrum, final

Gamma rays



Emitted by radioactive nuclei
Highly penetrating and cause serious
damage when absorbed by living
tissue
Looking at objects in different
portions of the spectrum can
produce different information
Fig. 21-CO, p.693
Radio
Fig. 21-23d, p.717
X-ray
Fig. 21-23a, p.717
optical
Fig. 21-23b, p.717
Infra-red
Fig. 21-23c, p.717
A Brief History of Light

1000 AD


Newton


It was proposed that light consisted of tiny
particles
Used this particle model to explain
reflection and refraction
Huygens


1678
Explained many properties of light by
proposing light was wave-like
A Brief History of Light,
cont

Young



1801
Strong support for wave theory by
showing interference
Maxwell


1865
Electromagnetic waves travel at the
speed of light
A Brief History of Light,
final

Planck

EM radiation is quantized



Implies particles
Explained light spectrum emitted by
hot objects
Einstein


Particle nature of light
Explained the photoelectric effect
The Particle Nature of
Light


“Particles” of light are called photons
Each photon has a particular energy


E=hƒ
h is Planck’s constant


h = 6.63 x 10-34 J s
Encompasses both natures of light


Interacts like a particle
Has a given frequency like a wave
Dual Nature of Light

Experiments can be devised that
will display either the wave nature
or the particle nature of light


In some experiments light acts as a
wave and in others it acts as a
particle
Nature prevents testing both
qualities at the same time
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