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Transcript
DEVIL PHYSICS
THE BADDEST CLASS ON CAMPUS
IB PHYSICS
TSOKOS LESSON 4-9
POLARIZATION
Reading Activity Questions?
IB Assessment Statements
Topic 11.5. Polarization:
11.5.1. Describe what is meant by polarized
light.
11.5.2. Describe polarization by reflection.
11.5.3. State and apply Brewster’s Law.
11.5.4. Explain the terms polarizer and analyzer.
IB Assessment Statements
Topic 11.5. Polarization:
11.5.5. Calculate the intensity of a transmitted
beam of polarized light using Malus’
Law.
11.5.6. Describe what is meant by an optically
active substance.
11.5.7. Describe the use of polarization in the
determination of the concentration of
certain substances.
IB Assessment Statements
Topic 11.5. Polarization:
11.5.8. Outline qualitatively how polarization
may be used in stress analysis.
11.5.9. Outline qualitatively the action of
liquid-crystal displays (LCDs).
11.5.10. Solve problems involving the
polarization of light.
Objectives
 Explain the meaning of the term




polarization
Understand how light can be polarized
State and apply Malus’s law
State and apply Brewster’s law
Understand the terms optical activity
and optically active substances
Objectives
 Outline some applications of polarized
light, including the structure and
operation of liquid crystal displays
Introductory Video:
Polarization of Light
Polarization
 Property of all transverse waves
 Changes in electron energy levels release planepolarized photons
Polarization
 A light wave polarized in the vertical direction
will pass through a vertical slit, but is stopped by
a horizontal slit
Polarization
 The light wave in (a) is polarized to the vertical
plane
 The light wave in (b) is unpolarized
Polarization
 The most common polarizer of light is Polaroid,
a plastic invented by 19-year old Harvard
undergrad, Edwin Land, in 1928
 You may have heard of his Polaroid camera
Polarization
 Polarizers have a molecular structure that only
allows light of a certain orientation to pass thru
 The direction of polarization is usually shown by
a line on the film
Malus’s Law
 Vertically polarized film will let 100% of vertical
waves through and 0% of horizontal waves
 But what about those aligned at angles in
between?
Malus’s Law
 But what about those aligned at angles in
between?
 For an electric field, E0 , only the vertical
component of the field will pass through
E  E0 cos 
Malus’s Law
E  E0 cos 
 The intensity of the light that passes through is
proportional to the square of the field strength,
so,
IE
2
I  I 0 cos 
2
Malus’s Law
I  I 0 cos 
2
cos 45  0.5
2

cos 30  0.75
2

cos 60  0.25
Avg  0.5
2

 The intensity of the
light that passes
through is equal to ½
1
I  I0
2
Polarizers and
Analysers
 The intensity of
unpolarized light
passing through a
polarizer is equal to
½ no matter what
the orientation of
the polarizing film
1
I  I0
2
Polarizers
and
Analysers
 If, however, the light is already polarized, the
intensity of the polarized light passing through a
polarizer will range from 100% (film axis aligned
with light polarization axis) to 0% (film axis
perpendicular to light polarization axis)
Polarization by Reflection
 Light can be partially polarized through
reflection
 When light is reflected off a non-metallic
surface, not all planes of light are reflected
equally
Polarization by Reflection
 Light in the plane of incidence has the least
magnitude
Polarization by Reflection
 Light in a plane perpendicular to the
reflecting surface has the greatest magnitude
Polarization by Reflection
 The degree to which light is polarized parallel
to the reflecting surface depends on the
angle of incidence
Brewster Angle
 Do not confuse with Brewster’s Millions though
Richard Pryor does seem to have an angle on
everything
 Brewster found that the degree to which
reflected light was polarized was dependent on
the angle of incidence and angle of refraction
 He also found that reflected light was 100%
polarized when the angle between reflected
light and refracted light was 90°
Brewster Angle
 Brewster’s Angle (B) is defined as the angle of
incidence which produces a 100% polarized
reflected light
 If angle of incidence is B, angle of reflection is
also B and the angle of refraction will be 90°-B
Brewster Angle
 Brewster’s angle is
dependent on the
refractive indices of
the two media

n1 sin  B  n2 sin 90   B
n1 sin  B  n2 cos B 
n1 cos  B

n2 sin  B
n2 sin  B

 tan  B
n1 cos  B

Brewster Angle
 If the incident ray is in
air with n1 = 1,
n2
 tan  B  n2
n1
Optical Activity
 Normally, two polarizers at right angles to
each other would block all light passing thru
 If certain sugar solutions are placed between
the polarizers, light passes through
 How come?
Optical Activity
 The sugar solution rotates the plane of polarization
as the light passes through
 Rotation of the plane of polarization is called
optical activity
 Materials that show optical activity are called
optically active materials
Optical Activity
 Angle of change is dependent on distance travelled
through the material and light wavelength
 Angle of change can be determined by the angle of
the second polarizer from 90 degrees to the point
where light disappears
Practical Applications
 Stress Analysis – certain
materials will increase in
their optical activity when
subjected to stress
 Degree of increase is
proportional to force applied
 Measuring Solution
Concentrations – the
amount of a certain
solution’s optical activity
will change based on
concentration
Practical Applications
Practical Applications:
Sunglasses
Practical Applications
 Liquid Crystal Displays
 Uses liquid crystals to make displays, hence the name
 When an electric field is applied, the molecules align
with the field to see the desired character
 Apply for field to align molecules to polarizer so as to
blank out the character
 Color made by introducing green, red and blue filters
The Quick and Dirty of
Polarization
Σary Review
 Can you explain the meaning of the term




polarization?
Do you understand how light can be
polarized?
Can you state and apply Malus’s law?
Can you state and apply Brewster’s law?
Do you understand the terms optical
activity and optically active substances?
Σary Review
 Can you outline some applications of
polarized light, including the structure
and operation of liquid crystal displays?
IB Assessment Statements
Topic 11.5. Polarization:
11.5.1. Describe what is meant by polarized
light.
11.5.2. Describe polarization by reflection.
11.5.3. State and apply Brewster’s Law.
11.5.4. Explain the terms polarizer and analyzer.
IB Assessment Statements
Topic 11.5. Polarization:
11.5.5. Calculate the intensity of a transmitted
beam of polarized light using Malus’
Law.
11.5.6. Describe what is meant by an optically
active substance.
11.5.7. Describe the use of polarization in the
determination of the concentration of
certain substances.
IB Assessment Statements
Topic 11.5. Polarization:
11.5.8. Outline qualitatively how polarization
may be used in stress analysis.
11.5.9. Outline qualitatively the action of
liquid-crystal displays (LCDs).
11.5.10. Solve problems involving the
polarization of light.
QUESTIONS?
Homework
#1-21
STOPPED HERE ON MAY 7TH