Download Refraction - Snell`s Law, Internal Reflection, Dispersion (PowerPoint)

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Transcript
• Snell’s Law
• Total Internal Reflection
• Fiber Optics
• Dispersion
Optical fibers are called light pipes. They work by a
succession of total internal reflections
Snell’s Law
When the wave fronts slow down at a boundary it can be seen that the angle
that the fronts make with the boundary gets less. In other words the angle of
incidence (1) between the incident ray and a line drawn perpendicular to the
boundary (the normal) is greater than the angle of refraction (2).
Refracted ray
2
The angle of refraction is dependent on the angle of incidence and the
difference in the type of medium from one side of the boundary to the
other.
2
1
A
For example, light and sound will travel at different speeds in different media.
From the diagram it can be seen that if the incident wave is traveling at speed
v1 and the refracted ray v2: then the frequency of the waves crossing the
boundary will remain the same but the wavelength gets less because the
wave travels slower in the second material.
L1
1
normal
Incident ray
Example
An earthquake P wave passes across a boundary in rock where its velocity increases from 6.5 km/s to 8.0 km/s. What
happens to a) the angle with respect to the normal line b) the frequency and c) the wavelength of the wave?
v1 = 6.5 km/s
v2 = 8.0 km/s
a) The wave speeds up after crossing the boundary so the angle will get bigger (2 is greater than 1)
b) The frequency stays the same because the mediums must respond equally at the boundary
c) The wavelength gets longer because each wavefront crossing the boundary speeds up and the number of waves
crossing each second (the frequency) stays the same so according to the wave equation (v = f x ) the
wavelength will increase.
L2
n = c / v or v = c / n and v = f 
But we now know that for light
So
v1 = c n2 = n2
v2
therefore
n1 c
v1 = f 1
and
n1
v2
v1 =  1
v2
f
2
=
2
1
Refracted ray
=
2
n2
n1
2
We can thus relate the relative refractive index of the two mediums across a
boundary to the amount of bending of light. The amount of bending as you can see
is directly related to how much the material “slows down” the light as it passes
through (the inverse of the refractive index, 1 / n) and this in turn will influence the
wavelength.
Material of refractive
index, n2
2
1
A
L1
For the example diagram to the right it can be seen that n2 must be bigger than n1
because 1 is bigger than 2. Thinking about it conceptually, this makes sense
because we know that the refracted ray must be moving slower than the incident
ray because it is closer to the normal. The refracted ray must consist of the same
number of waves per second as the incident ray because you can’t “lose” waves but
because the refracted waves move slower, their wavelength must be shorter than
the incident waves. What this means is if 1 is big then 1 will be big compared with
2 and 2.
L2
1
Incident ray
Material of refractive index, n1
Example
A jeweler wants to tell whether a stone he receives is diamond. He lets a light ray of wavelength 650 nm hit the stone at an angle of 350
to the normal. If the wavelength within the stone is 445 nm (blue)
a) is the refracted angle bigger or smaller than 350 ?
b) Is the stone diamond?
1 = 650 nm 2 = 445 nm n1 (air) = 1.0003
n2 = ? 1 = 350
a) The wavelength decreases so the light wave must slow down when passing from air into the stone. The angle must therefore get smaller
b) 1 / 2 = n2 / n1
Therefore
n2 = (1 / 2) n1 = (650 nm / 445 nm) (1.0003) = 1.46
Diamond has a refractive index of 2.41 so the stone is not diamond
Total Internal Reflection
What happens to a light ray when it goes from a more
optically dense medium (bigger refractive index) to a less
optically dense medium? It will speed up and bend away
from the normal according to our theory of refraction.
a
b
c
Air (n = 1)
r
(Figure b in the diagram to the right shows that r is
greater than i ).
d
Boundary / Interface
You can see that as the angle of incidence is increased (a
through c), the angle of refraction gets closer to 900. At a
particular angle of incidence (d) called the critical angle
the angle of refraction is 900. Above this critical angle (e)
most of the ray is not refracted but now reflected.
The bigger the refractive index (n) of the incident medium,
the slower the speed of the light ray (n = c/v) in this
medium. When the light ray emerges into the air the wave
will speed up more than for a smaller incident, n, so will
give a larger angle of refraction. This means that a
refracted angle of 900 is reached more quickly thus giving
a smaller critical angle. (see black dashed lines above)
The essence of this logic is: a big incident refractive
index will give a small critical angle
c*
Material
(water, glass,
plastic)
c
c
e
i
normal
normal
normal
* Dashed arrows for incident material with a greater refractive index
Why Diamond Sparkles
The unusually high refractive index of diamond leads to its small critical angle in
air of 24.50. Diamond gemstones are cut with many facets in such a way that
much of the incident light undergoes multiple total internal reflections within the
diamond before passing out again into the air. Many of the rays incident on the
diamond from above are reflected back upward towards the faceted crown.
Optical Fibers
Easily the most important application of internal reflection is fiberoptics. Techniques have evolved in recent times for efficiently conducting light
and near IR (1300 nm) energy along thin, transparent, dielectric fibers.
A typical fiber thickness might be in the range of say, 50m, just about the thickness of a human head-hair. An optical fiber is like a light pipe.
Light entering it at the proper angle will zig zag its way through it as many as 15000 times per meter without being lost through the walls of the
fiber. The smooth surface of a single filament must be clean of contamination, or the boundary conditions change and the light leaks out at
those spots. Accordingly, each fiber core is usually enshrouded in a transparent sheaf of lower-index material called cladding. The lower
index of refraction of the cladding wrt the core ensures a small critical angle therefore allowing the light to undergo total internal reflection
along the fiber
Incidentally, just like an optical fiber, to keep a diamond ring sparkling you must keep the bottom of the diamond clean so that the sharp
change in refractive index from diamond to air is maintained., and the critical angle is kept low. Dirt or moisture on the bottom of the diamond
increases the critical angle, allowing much of the light incident on the diamond to escape through the bottom.
Optical fibers are obviously useful for getting light into inaccessible places. They were first put into use in medical endoscopes for looking
down the throat. Nowadays mechanics and machinists also use them to look inside the interiors of engines.
In the new era of optical communications, optical fibers are replacing metal wires, not for transmitting power, but information. The much
higher frequencies of light allow for an incredible increase in data-handling capacity. For example, using some sophisticated transmitting
techniques, a pair of copper telephone wires can be made to carry up to two dozen simultaneous conversations.
To get a feel for how much information that is, consider the fact that a single ordinary TV transmission is equivalent to about 1300
simultaneous telephone conversations, which in turn, is roughly equal to sending more than 2500 typewritten pages each second! (See
QWEST advertisement). So, at present it is quite impractical to send television over copper phone lines. Today, when you talk on the
phone, your voice is converted into an electrical signal that goes to a tiny laser which transmits your voice as a series of flashes. Optical
fibers can carry up to 20,000 conversations at once because of spaces in each person’s conversation. (multiplexing)
This is only the beginning; achieved capacities to date don’t even begin to approach the theoretical limit. There are however some
problems with this new medium of communication. Because the optical medium is not perfectly transparent, it is necessary to boost the
signal every 50-km with repeater stations. This is still much less expensive than systems of metal wire, which require boosting every
kilometer.
Dispersion
Dispersion involves the separation of light into colors according to their frequency..
Wavelength Relationship
We have already seen from our discussions of Snell’s Law that the speed
of light in a transparent medium depends on the frequency and therefore
the wavelength of light.
Since the natural or resonant frequency of most transparent materials is in
the ultraviolet part of the spectrum, visible light of higher frequencies
travels more slowly than light of lower frequencies. Violet light travels about
1% slower in ordinary glass than red light. The colors between red and
violet travel at their own intermediate speed.
Example
Light of wavelength 400 nm is incident at an angle of 450 on acrylic and is refracted as it
passes into the material. What wavelength of light incident on fused quartz at an angle of
450 would be refracted at exactly the same angle?
The two materials must have the same index of refraction, n, so a wavelength of about 250
nm is needed. This conceptually makes sense because shorter wavelengths are refracted
more by a certain material but Fused Quartz also acts as a less optically dense material
than Acrylic. The shorter wavelength compensates for this.
Normal
Prism
Since different frequencies of light travel at different speeds in transparent
materials, they will refract differently and bend at different angles. When
light is bent twice at non-parallel boundaries, as in a prism, the separation
of light into colors of light is quite apparent. Dispersion is what enabled Sir
Isaac Newton to produce a spectrum.
In the diagram opposite, it can be seen that violet light ,(smallest
wavelength) bends the most towards the normal line in the prism, and also
bends the most away from it when it leaves.
Normal
Rainbows
Dispersion is most evident when seeing a rainbow. To see one you will need two things, water drops and sun light. Not
only that, but to see one you will also need the sun behind you.
The fact that rainbows are semicircular tells you that the light from one has to come from the water drops at the right angle angle*.
When white light enters a water drop light is refracted and disperses into its component colors. Violet is bent the most and red the
least. When the rays reach the opposite part of the drop they are partly reflected and leave the drop at an angle between 40 0 and
420 from their incident direction. (figure a)
Even though each drop produces the spectrum of colors, an observer is in a position to only see one color from each drop. This is
why red appears at the top of the rainbow. (figure c).
Sometimes you will see a secondary rainbow above the primary rainbow with the colors inverted. This is a result of double reflection
within the raindrop. (figure b).
*Note:
If you viewed a rainbow from an airplane you would see that it is circular. The horizon normally gets in the way making it look
semicircular.
Diamonds Revisited
Like a prism, the diamond is a dispersive medium (that is n varies somewhat with ), and so the various
colors composing white light travel somewhat different paths and emerge in different directions. Hence as the
diamond is turned, different colors can be seen, giving it its characteristic sparkling quality.
Chromatic Aberration
Chromatic aberration is the result of different speeds of light of various colors and hence the different refractions they
undergo. In a simple lens red light and blue light bend by different amounts (as in a prism), so they do not come to focus in
the same place.