Chapters 3638 Review

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Chapters 3638 Review

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Title: Chapters 3638 Review

1
Chapters 36-38 Review
PHYS 2326-36
2
Suggestions

Take time to create your note card
It can be a full sized sheet containing formulas
and constants but no worked problems or problem
solutions
Know what is on the sheet and where
Do not put things you dont know how to use and
dont put too much on there
Organize it and label it
Include your name and turn it in with the test
you will probably want it back for the final

3
Test 5

Test 5 covers Light, lecture notes 30-35 and
chapters 35-38
You are responsible for knowing the contents in
those chapters
If it wasnt discussed in class, it might not be
on the test
If it was discussed in class, it may well be on
the test
The lecture notes include most of what was
discussed in class

4
Chapter 35 Light
PHYS 2326-30
5
Concepts to Know

Speed of Light
Wave Fronts Rays
Reflection
Law of Reflection
Refraction
Index of Refraction
Law of Refraction (Snells Law)
Total Internal Reflection

6
Concepts to Know

Critical Angle
Huygens Principle
Dispersion

7
Speed of Light

Light is very fast
2.998 x 10 8 m/s in a vacuum (3.0E8 )
slower in materials such as air or glass

8
Rays

Can assume light travels in fixed directions in a
straight line when passing through a uniform
medium
This is the ray approximation
Rays are perpendicular to wavefronts
Works well for studying mirrors, lenses, prisms
and optical instruments like telescopes
Light ray paths are reversible

9
Reflection

Like waves traveling along a string hitting a
boundary, light can reflect when hitting a
boundary
Unlike a string, light doesnt have to reflect
back along the same direction
Specular reflection is from a smooth surface like
a mirror or a calm pond
Diffuse reflection occurs from rough surfaces

10
Law of Reflection

Given a smooth surface at a point, there is a
normal to that surface
Reflection occurs so that the angle of the
reflected ray is the same as the angle of the
incoming or incident ray both measured from the
normal

?
?
11
Refraction

When a boundary exists between two different
transparent media, the light ray passing through
the boundary is bent and is said to be refracted,
depending upon the properties of the two media
The relationship for this is eqn 35.3
where ?1 and v 1 are the angle of incidence and
speed of light in the first medium and ?2 and v2
are for the second medium

12
Refraction Reflection

Usually, both occur at a boundary
When going from air to a denser material with a
lower speed of light water, glass refraction
bends the ray towards the normal
When going from denser material to air, the ray
bends away from the normal

N
?1
?1
?2
13

Example of light going through a glass to air
As light travels from one medium to another, the
frequency doesnt change but the wavelength and
velocity change

?2
N
?1
?1
?1
?2
14
Index of Refraction

n defined as c/v the ratio of the speed of
light in a vacuum divided by the speed of light
in the medium

15
Refractive Index

Table 35.1 shows a refractive index for various
materials
A vacuum is 1.00000000
Air is close at 1.000293
Water is just over 1.3
Glass varies around 1.4 to 1.7

16
Huygenss Principle

All points on a given wave are taken as point
sources for the production of spherical secondary
waves called wavelets

17
Dispersion

The index of refraction is not constant with
wavelength
Dispersion is the behavoir where the angle of
refraction changes with wavelength
This creates the rainbow effect of rain droplets
and prisms

18
Total Internal Reflection

Note that a sin function varies from -1 to 1 and
that the typical index of refraction n can vary
from 1.0 to over 2.0.
For a surface boundary between materials 1 and 2,
where material 1 has a greater index of
refraction than material 2, what happens when the
angle ?2 reaches 90 degrees?

n1 sin ?1 n2 sin 90 n2
?1 becomes the critical angle ?c
sin ?1 n2 / n1 (for n1 gt n2) eqn 35.10
As the incident angle ?1 reaches the critical
angle ?c there is total internal reflection going
on as all light is reflected since the refraction
angle cannot exceed 90.

gt?c
20
Chapter 36 Mirrors and Image Formation
PHYS 2326-31
21
Concepts to Know

Mirrors
Plane, Concave, Convex
Sign Conventions
Object Distance
Image Distance
Focal Length
Magnification

22
Concepts to Know

Enlarged, Reduced
Erect, Inverted
Real, Virtual
Reversed (Perverted)
Converging, Diverging
Aberration
Principle Rays

23
Definitions

Plane surface one that is flat
Concave surface, one that is curved inward at the
center
Convex surface, one that is curved outward

Eye
Plane
Concave
Convex
24
Objects Images

Image from a Plane Mirror
p object to surface, q surface to image
h object height, h image height
Magnification M 1 for flat mirror

p
q
h
h
?
Object
?
Image
25
Images

Virtual Image - no light reaches image
Real Image - light rays reach image
Erect or Upright Image directions unchanged
(object up is same direction as image up)
Inverted Image directions opposite (object up
is image down)
Reversed Image left seems right

26
Spherical Mirrors

Parameters of a spherical mirror
Principal axis line through C and V where V is
the center of the mirror
C Center of Curvature center of sphere or
circle (2 dimensions)
R Radius of Curvature
F Focal point
Radius lines are always
normal to surface
of circles and spheres

V
R
C
principal axis
F
Concave
27

Given an object to the left of C, by the law of
reflection, ? ?, light rays will converge at a
point between V and C for rays with small angles
to the principal axis
For larger angles the rays will intersect at
different points creating spherical aberration
See Fig. 36.8

V
C
principal axis
O
I
Concave
28
Image Concave Mirror

Rays through C are normal to surface ?0
Draw rays to V (intersection of surface and
principal axis) ? ? and through C, ?0
Tan ? h/p -h/q, since M h/h, -q/p
Note -h inverted
Image is
smaller
inverted
real
outside point F

Concave
p
R
h
V
?
a
a
h
C
?
F
q
29

since tan a -h/(R-q) h/(p-R)
h/h -(R-q)/(p-R) eqn 36.3
1/p 1/q 2/R eqn 36.4 MIRROR EQN
For a very distant object where p-gt infinity, 1/p
0 so 1/q 2/R
This case it is called the focal point F, where F
2/R eqn 36.5
hence 1/p 1/q 1/f, eqn 36.6, the mirror
equation
The focal point is where rays parallel to the
axis pass through

30
Spherical Convex Mirror

Often called a diverging mirror
Concepts presented are valid for this type of
mirror as well if adhere to the following
procedure
R, F q negative
p, h h positive

R
C
V
principal axis
F
p
q
31
Procedure

Front side of mirror where light waves
originate and move towards the mirror
Back side is the other side

32
Mirror Sign ConventionsTable 36.1
33
Ray Trace Example 1

Object outside focal point
Image inverted and smaller
Rays drawn through C, and parallel to principal
axis and through F

V
C
F
34
Ray Trace Example 2

Object is inside the focal point F
Image is virtual, upright and magnified

V
C
F
35
Ray Trace Example 3

Convex mirror
Image is virtual, reduced and upright

R
C
V
F
p
q
36
Ray Tracing

Principal axis goes through C, center of
curvature so is perpendicular to the surface at
V. Bottom of object.
Ray 1 top of object parallel to principal axis
goes through Focal point or reflects away from
focal point for convex mirror
Ray 2 top of object through focal point
reflects parallel to axis where it intersects
mirror
Ray 3 top of object through Center of curvature,
reflects back on self

37
Example Problem 1

Given object of height 1 cm located 30cm in front
of a concave mirror of focal length 10 cm, what
is a) radius of curvature? b) Location of image?
c) Real/virtual image? d) Magnification? e)
Enlarged? f) Image height? g) upright/inverted?

38
V
C

h 1cm, p 30cm, f10cm
f R/2, 1/p 1/q 1/f
M -h/h, M -q/p
R 2f 20cm
q 1/(1/f 1/p) 15cm
Real
M -q/p -15/30 -0.5
Reduced
M-h/h , -0.5 -0.5cm/1cm
Inverted

F
39
Chapter 36 Refractive Surfaces and Lenses
PHYS 2326-32
40
Concepts to Know

Spherical Refracting Surfaces
Thin Lenses

41
Definitions

Plane surface one that is flat
Concave surface, one that is curved inward at the
center
Convex surface, one that is curved outward

Eye
Plane
Concave
Convex
42
Differences From Mirror

Light goes through
There are effects from the index of refraction
Sign Conventions must change

43
Plane Surface Boundary
p
q

For a plane mirror
pq and M 1
What about for a fish tank?

h
?
Object
?
Image
44
Plane Refraction

Unlike the mirror
viewing into another
index of refraction
medium is affected
even by a flat plane

q
n1.30
n1.00
Object
p
45
Refraction

Fig. 36.17 shows a spherical boundary between two
media of different indices of refraction
Using Snells law and the small angle
approximation one can achieve eqn 36.8

?2
?1
n2
n1
?1
d
a
?
ß
I
C
O
R
p
q
46
Refracting Surface

Eqn 36.8 provides the result of the geometric
derivation from Fig. 36.17
Notice that the image distance depends upon the
object distance, Radius of curvature and the
index of refraction for each media
Note too, that if R becomes infinite we have a
flat plane surface and (n2-n1)/R becomes 0 so
q -(n2/n1)p eqn 36.9

47
Lenses

Lenses have 2 surfaces, not just one
A lens may have a concave, convex, or plane
surface referred to as plano when being
described
A lens is converging or diverging
Converging lens types include biconvex,
concave-convex, and plano-convex
Diverging lens types include biconcave,
convex-concave, and plano-concave

48
Refracting Surface Sign Conventions
49
Lens

Eqn 36.10 starts with eqn 36.8 and assumes n1
1.00 and n2 n for surface 1
Eqn 36.11 is for surface 2 and differs because
the light is going from inside the material out
to the air, n1 n and n2 1.00 for surface 2
The image formed by surface 1 becomes the object
for surface 2

50
Thin Lens Equation

Note that p2 -q1 t and p2 will be positive
by the sign convention because q1 has a negative
value
if t is very small, p2 -q1 (for both real or
virtual image)

R1
R2
n1
I
O
t
C1
p
q1
p2
51
Thin Lenses

Eqn 36.11 becomes Eqn 36.15, The Lens Makers
Equation

52
Lens Makers Equation

Can be used to determine R1 and R2 for a lens
given a desired focal length and an index of
refraction
If given the index of refraction and radii of
curvature (R1 and R2), one can find the focal
length
If assume n is the ratio of the index of
refraction between the lens and what it is
immersed in other than air the eqn can be used

53
Image Magnification

M h/h -q/p which is the same as for
mirrors.
When M is positive, image is upright and on the
same side of the lens as the objec
When M is negative, the image is inverted and on
the opposite side of the lens

54
Thin Lens Equation

Eqn 36.15, the lens makers equation can be used
with 36.14 to create 36.16, a thin lens equation
exactly like that of mirrors.
Note that focal points are the same distance on
both sides of the lens
Also, a converging lens is thicker in the middle
while a diverging lens is thinner in the middle

55
Table 36.3
56
Ray Tracing for Converging Lens

Ray 1 parallel to principal axis refracted
through focal point on back side of lens
Ray 2 draw through lens center continues straight
line
Ray 3 through focal point on front side or as if
coming from focal point (if inside f) and
emerging parallel to principal axis

57
Ray Tracing for Diverging Lens

Ray 1 drawn parallel to principal axis, emerges
away from the focal point on the front side
Ray 2 drawn through lens center in straight line
Ray 3 drawn towards backside focal point emerges
parallel

58
Example Problem 1

A thin double concave lens has a radius of 10cm
on both sides and made from glass with an index
of refraction 1.5. A light bulb 2cm tall is
located 50cm in front of the lens along the
principal axis. a) What is the focal length of
the lens? Converging or diverging? b) Where is
the bulb image? c) What is the image height?
Enlarged or reduced? Erect or inverted?

Equations
1/f (n-1)(1/R1 1/R2)
1/p 1/q 1/f
M -q/p h/h
a) f? 1/f (1.5-1)(1/(-10) 1/(10))-0.5(2/10)
f -10cm (diverging)
b) 1/50cm 1/q 1/(-10), q -12.5cm
on front side and it is virtual
c) m -12.5/50 0.5cm reduced, erect

60
Problem 36.33

36.33 An object located at 20cm to left of a
diverging lens with focal length f -32.0cm.
Determine a) the location and b) the
magnification of the image. c) Construct a ray
diagram

The problem provides p object distance and f
focal length
Can use thin lens eqn to solve for q image
distance
Can then use magnification definition to
determine the magnification
Ray tracing for a diverging lens

62
Ray Tracing for Diverging Lens

Ray 1 drawn parallel to principal axis, emerges
away from the focal point on the front side
Ray 2 drawn through lens center in straight line
Ray 3 drawn towards backside focal point emerges
parallel

63
Chapter 36 Optical Instruments
PHYS 2326-33
64
Concepts to Know

f-number
Fresnel Lens
Eye
Magnifier
Microscope
Telescope
Aberrations

65
Combination of Thin Lenses

Image formed by first lens must be located as if
the second lens is not present
A ray diagram is drawn for the second lens using
the image of the first lens as the object of the
second
The second image is the image of the system
If the first image is behind the second lens, it
is virtual and has p2 for its location
Magnification is a product of the individual
magnifications M M1M2

66
Two Thin Lenses in Contact

Given 2 thin lenses in contact with each other of
focal lengths f1 and f2, this compound lens has a
focal length
1/f 1/f1 1/f2 Eqn 36.19

67
Lens Aberrations

Our equations make assumptions like small angles
to the axis, that lenses are thin and even that
the index of refraction is uniform at all
wavelengths.
Ray tracing permits precise analysis using
Snells law.
There are two common abberrations
spherical aberration
chromatic aberration

68
Spherical Aberration

Caused by parallel rays coming in further away
from the principal axis and intersect the
principal axis after refraction at different
points than rays closer in
Parabolic mirrors and lenses are better but are
much harder to make
Parabolic mirrors are common in telescopes
Cameras use adjustable apertures to control the
amount of light and to reduce spherical aberration

69
Chromatic Aberration

Chromatic aberration is related to dispersion and
is caused by differences in the index of
refraction for different wavelength. Shorter
wavelengths like violet may refract more than
red, changing the focal point inward
Solutions to this are the use of more exotic
lenses such as achromatic or apochromatic which
are composed of two or even three different
materials, some are more exotic than plain glass.

70
Cameras Eyes

Cameras and eyes are quite similar
Both have a lens and an aperture (usually
adjustable to control incoming light)
Both have a light sensitive medium at the back
which captures the image
Eyes tend to have a spherical sensing area which
permits superior results with simpler optics
Cameras tend to have a flat sensing area
Both must create a real image on the sensor

71
Aperture

Some optical systems, like most cameras have an
adjustable aperture
All optical systems have an aperture
Aperture is f/D where f is the focal length and D
is the diameter
Apertures are called f-numbers
Aperture is related to the amount of light that
is permitted to enter which is proportional to D2

f-number is defined by f/D Eqn 36.20
Intensity I is proportional to 1/f-number2
A telescope usually doesnt have an adjustable
aperture but rather D is the diameter of the main
lens or the main mirror.
The lower the f/number, the faster the lens and
often the more expensive it is for a certain
quality grade

73
Simple Magnifier

Even with a magnifying glass, the size of the
object viewed by the eye depends upon the angle ?
subtended by the object
A converging lens (or magnifying glass) may be
used to increase the apparent size of an object
as seen by the eye.
This is an angular magnification m ?/?o
Assuming ones vision permits 25cm as the closest
distance, eqn 36.24 mmax 1 25cm/f is the
maximum magnification possible and mmin 25cm/f
is the lowest for a magnifier

74
Compound Microscope

A compound microscope consists of an objective
lens near the sample being observed an an
eyepiece
The objective has a very short focal length lt 1cm
and the eyepiece with f a few cm
These lenses are placed at a distance L greater
than the focal lengths of the lenses
The object is placed just outside the focal point
of the objective

75
Microscope Magnification

Overall magnification is M Mome where Mo is the
lateral magnification of the objective and me is
the angular magnification of the eyepiece
M -L/fo (25/fe) the sign indicates an
inversion

76
Telescope

Eqn 36.27 is shown in section 36.10 along with
the approximations and derivation
m ?/?o - fo/fe ratio of the focal length of
the objective divided by that of the eyepeice
The two common types are reflectors and
refractors with mirrors or lenses for the
objective
The largest reflectors are 10 meters in diameter
while the largest refractor is about 1meter.

77
Chapter 37 Interference
PHYS 2326-34
78
Concepts to Know

Interference
Principle of Superposition
Monochromatic Light
Coherent Light
Antinodal Curves (Constructive Interference)
Nodal Curves (Destructive Interference)
Interference Fringes
Phase Shift (Reflection off Slow Medium)
Thin Films

79
Inteference

Like sound waves, light waves can produce
interference
Nodes exist where there are minima (dark areas)
from destructive interference
Antinodes exist where there are bright areas from
constructive interference

80
Monochromatic Light

Monochromatic light simply means one color
which is 1 frequency or wavelength
Lasers produce monochromatic light very well
Sodium vapor lights do a fair job although they
are producing bichromatic light but there are a
variety of arc lamps which are monochromatic
Lightbulbs produce a wide range of wavelengths

81
Coherent Light

Coherent light refers to light having a
consistent phase between sources.
From our study of sound, we determined that
phasing between PA system speakers could have
negative effects on ones hearing at some
locations
In order to see interference effects we must have
consistent phase.

82
Conditions for Interference

Sources must be coherent have a constant phase
Sources must be monochromatic, a single wavelength

83
Youngs Double-Slit Experiment

Performed by Thomas Young in 1800
It showed Huygenss principle of subdividing wave
fronts into new wavelets or wave fronts to be
correct

S1 and S2 are narrow slits separated by distance
d. Distance d is the difference in path lengths
r1 and r2 and ? is the angle from the normal at
the slit center line and y is the offset distance
at the screen
When d is a multiple of wavelength there is
constructive interference

r1
y
S1
r2
?
d
S2
d
L
85

d sin ?bright m?
d sin ?dark (m ½) ?
since tan ? y/L
ybright L tan ?bright
ydark L tan ?dark
for small angles where ? sin ?
ybright L (m ? /d)

86
Phase Shift from Reflection

Section 37.5 refers to Lloyds mirror where our
two sources are one source plus a reflected image
of the source
When an electromagnetic wave is reflected from
the interface to a medium with a higher index of
refraction than the one in which it is traveling,
it undergoes a 180 degree phase reversal.

When a reflection occurs at a surface where the
index of refraction is less than that of the
medium the wave is traveling in, there is NO
phase reversal at the reflection
This corresponds to a ½ wavelength displacement
shift or a ½ integer shift

88
Thin Films

Thin films such as oil on water or soap bubble
surfaces exhibit interference effects by showing
varied colors when white light is incident on the
films.
This occurs because the reflection from the top
surface has a 180 degree phase shift and the
second surface at some distance t does not have
this phase shift and the total effective path
difference becomes a multiple of certain
wavelengths
2t (m1/2)?n where ?n ? /n (index of
refraction)
2nt (m1/2) ? for constructive interference and
2nt m ? for destructive interference (eqn
37.15-17)

89
Color Wavelength
500nm
400nm
600nm
700nm
blue
green
red
yellow
cyan
magenta

Primary colors are red green and blue and have a
range of wavelengths for each. Adding any
combination creates other colors. Often called
RGB
Cyan magenta and yellow are combinations of two
primary colors
Wavelengths are shown in nanometers (10-9 meters)
sometimes these are shown in Angstroms which is
10-10

90
Example Problem 1

In a double slit interference experiment, the
slits are 10 micron (10-6 meters) apart and the
screen is 2 meters away. If 500nm wavelength
light is used, find a) the location of the first
dark fringe, b) the location of the 3rd bright
fringe, c) the spacing between fringes, d) the
theoretical number of bright fringes possible.

a) d sin ? (m1/2)?, 1E-5 sin ? (1/2) 5E-7 ?
1.43
y L tan ? 2.0 tan(1.43) 0.05m
b) d sin ? (m)?, 1E-5 sin ? (3) 5E-7
? 8.63
y L tan ? 2.0 tan(8.63) 0.30m
c) d sin ? (1)?, ? 2.86
y 0.10m
d) let maximum ? 90, d sin 90 (m)?, m20.
This is for 1 side and there is a middle fringe
total 41

92
Example Problem 2

What is the minimum thickness of a soap bubble
film with index of refraction 1.33 that would
reflect 650nm most brightly? b) What is the
minimum thickness for an anti-reflecting coating
of index of refraction 1.4 or a glass of index
1.5 which would reflect no green light of
wavelength 550nm? c) what would be the color of
the light that is reflected off the lens

n 1.33, ?o 650nm, ? ?o /n 488nm, ?m 0
m2-m1
m2 2d/ ?, since m1 ½ (due to 180 deg.
inversion not present at m2) our path difference
can be ½ wavelength. Get wavelength inside
material and determine d m2 ?/2 ½ 488 /
2122nm
b) coating n1.4, glass 1.5 at 550nm ? ?o /n
393nm, m1 ½, m2 2d/ ? ½ since both m1 and
m2 reflect from greater index of refraction
mediums ?m ½ m2-m1 m2 ½, m2 1
? 550/1.4 393,
hence m2 1 2d/ ? ½, 2d/ ? 1/2, d ?/4
393/4 98nm
c) green transmitted, blue red reflected,
magenta

94
Chapter 38 Diffraction Polarization
PHYS 2326-35
95
Concepts to Know

Diffraction
Single Slit Diffraction
Multiple Slit Diffraction
Diffraction Grating
Mth order Lines
Grating Spectrometer
Resolution or resolving power
Circular Aperture Diffraction
Polarization

96
Narrow Slits

Like the dual slit, a narrow slit produces a
pattern because each portion of the slit acts as
a source of light waves

5
4
a/2
y
3
?
a
2
a/2
1
(a/2)sin?
D
97

If dark fringes occur at a sin ? m? then
where do light fringes occur?
hint its halfway in between the dark fringes
By geometry tan ? y/D which is valid for large
angles as well as small angles
Using small angle approximation and substituting
for tan ? sin ?,
y Dm ?/a

98
Resolution

Rayleigh criterion is when the central maximum of
one image falls on the first minimum of a second
image, the images are said to be just resolved
for a slit of width a, this is ?min ?/a
assuming wavelength ltlt a, eqn 38.5
for a circular aperture ?min 1.22 ?/D where D
is the diameter

99
Example

for 600nm red light, our TAMUK 16 telescope
(400mm 0.4m) has a resolving power ?min 1.22
?/D (1.22)(6.0E-7)/0.4 0.00000183 radians
0.38 arcseconds
since 2pi radians 360 deg, 1 deg60 arcminutes
and 1 arcminute 60 arcseconds so radians 360
60 60/(2 pi) gives arc seconds
Excellent viewing is essentially never better
than 0.5 arcseconds due to atmospheric
turbulence, this doesnt come into play for
visual work. To get higher resolution, larger
telescopes use adaptive optics to correct for
turbulence in real time. Amateurs sometimes
either use crude imitations or take lots of short
exposures for computer enhancement processing to
achieve better results than viewing would permit.

100
Diffraction Grating

Diffraction gratings are like multiple slits,
usually with thousands of lines (crude slits) per
inch, if not tens of thousands of lines
It may be a reflective or a transmission grating
Variable d usually refers to the spacing between
the lines and one is interested in the positions
of the maxima

101

d sin ?bright m? where m0,/- 1,2,3
eqn 38.7
m 0 is the 0th order maximum which doesnt
separate out by wavelength as ? 0
m 1 for the first order wavelengths, 2 for the
second and note that when m is not 0, ?bright
depends upon wavelength
Note too figure 37.8 shows that the number of
slits used increases the sharpness

102

Also, note that when the wavelength doubles, like
from violet to red, the angle for the second
order violet may be greater than the angle for
the first order red so there could be overlap

103
Diffraction Grating Applications

Gratings provide an excellent way to break up
light into different wavelengths and provide a
linear result unlike a prism that depends upon
the change of the index of refraction with
wavelength in order to work

104
X-ray Diffraction

While diffraction works well with visible light,
it turns out that with shorter wavelengths, can
be used to study much smaller items. X-rays have
been used to study the structure of crystals with
a spacing between molecules of around 0.1nm
2d sin ? m? where m1,2,3 describes the
condition for constructive interference known as
Braggs law, eqn 38.8 for reflections from atomic
planes in a crystal

105
Polarization

Light, like radio waves, is referred to as
electromagnetic radiation because it has an
electric field E and a magnetic field B which are
perpendicular to each other and both are
perpendicular to the direction of travel
Light normally consists of a bunch of waves in
superposition that are randomly oriented
according to their electric field E.
Polarization refers to the direction of the
electric field vector E.

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Light, like radio waves, can be polarized or
unpolarized and there are a variety of
polarizations possible
Light from an incandescent light bulb is
unpolarized
Radio waves from a vertical antenna are said to
be vertically polarized as the electric field
varies in the vertical direction. These are also
linearly polarized as the electric field is in
one direction that doesnt change with time

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Given two vectors, E and c, the electric field
and the wave velocity or direction of
propagation, a plane is formed and the wave is
said to be plane polarized
One may create a plane polarized wave by either
creating it that way as in radio or by removing
or filtering out all other polarizations
There are 4 ways to create a linearly polarized
beam from an unpolarized beam

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Selective Absorption

Polaroid a film that selectively filters out
light through absorption, Invented by Land in
1938
Commonly used in sun glasses
Composed of 2 sheets, the polarizer and the
analyzer rotated by an angle ?

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Maluss Law

Intensity of the transmitted polarized beam from
the polarizer to the analyzer is Imax and the
output from the analyzer intensity is I Imax
cos2 ? eqn 38.9 and is known as Maluss law and
applies to two polarizing materials whose
transmission axes are at an angle ? to each other
I is maximum when ? 0 or 180 and
I 0 when ? 90

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Polarization by Reflection

Polaroid sun glasses are popular because
reflected light tends to become polarized
Even though light may be unpolarized, when it is
reflected it may become completely or partially
polarized
Reflection has a preference for waves with
electric fields parallel to the surface

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If ?1 is varied so that the angle between the
refracted ray and the reflected ray 90 the
reflected beam is totally polarized while the
refracted beam is partially polarized. This
angle is the polarizing angle ?p and from Snells
law n2/n1 sin ?p /sin ? and by geometry tan ?p
n2/n1 eqn 38.10 Brewsters law

?1
?1
?1
?1
n1
n1
n2
90
n2
?2
?2
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Polarization by Double Refraction

Some materials like calcite and quartz are double
refracting or birefringent materials which can
split an unpolarized beam into an ordinary O ray
and an extraordinary E ray which are mutually
perpendicular in polarization and have different
indices of refraction
There is an optical axis where the indices of
refraction are the same
Some materials exhibit this when stressed and
optical stress analysis may be used in
mechanical design work

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Polarization by Scattering

Why is the daytime sky blue?
Its called scattering and occurs from
particulates and primarily from molecules of
oxygen and nitrogen the most predominant
molecules in the atmosphere
Because the molecular size is around 0.2nm and
much smaller than visible wavelengths and the
scattering varies by 1/?4, shorter wavelengths
such is violet and ble are scattered more
efficiently and hence has higher intensity than
longer wavelengths such as red.
Since eyes are less sensitive to violet, color
shows up more as blue even though theres less
intensity

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Nonlinear Polarization

Aside from linear polarization there are other
forms of polarization
Circular polarization
Elliptical polarization
Helical antennas are circularly polarized and
work better transmitting through the atmosphere
to space
Light may also be circularly polarized when
composed of two waves 90 degrees apart in
polarization and out of phase by 90 degrees

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Example

Given a single slit with width of 0.2mm and 600nm
laser light casting a pattern on a screen 6m
away, a) what is the linear spacing between two
sucessive fringes on the screen? b) how far from
the central bright fringe is the 4th dark fringe?
c) How far from the central (zeroth) bright
fringe is the first bright fringe located?

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a 2.0E-4m, ? 6.0E-7m D6m, a sin ? m ?, y
Dm?/a
a) let m1 for distance from m0, y 0.018m
b)m4, y Dm?/a 0.072m
c) bright fringes are ½ values, first dark fringe
is m1 so first light is m 1.5
yDm?/a 6 1.5 6.0E-7 / 2.0E-4 0.027m

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Example 2

Diffraction grating with 500 lines per mm. a)
What is the angle between red light of wavelength
700nm and violet light at 400nm for the second
order spectrum?
b) Does the 3rd order spectrum overlap the
second? c) If a beam of green light of wavelength
550nm passes through the grating and is projected
onto a wall 4 m away, what is the distance
between the first order fringe and the second
order fringe?

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d 0.001mm/500 2.0 E-6m or 2.0 µm
d sin ? m?
red 2.0E-6 sin ? 2(7.0E-7), ? 44.4
violet 2.0E-6 sin ? 2(4.0E-7), ? 23.6
?? 44.4 23.6 20.8
b) 3rd order, m3, d sin ? 3?
2E-6 sin ? 3 (4.0E-7), ? 36.9 smallest angle
of 3rd order and largest for 2nd order is red
44.4, they overlap significantly

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