Transcript Chapter 27
Reflection and Refraction
1. REFLECTION
Most objects we see reflect light.
2.
PRINCIPLE OF LEAST TIME
Fermat's principle: Light travels in straight lines and will take the path of least time.
Fermat says take this path.
3. LAW OF REFLECTION
• Using Fermat's principle one can show the law of reflection.
A 1 2 3 4 5 B Mirror
• The law of reflection states that the angle of incidence ( q i ) equals the angle of reflection ( q r ).
• This is true for specular reflection.
(Specular reflection is “mirror-like” reflection.)
Incident Ray Normal q i q r Reflected Ray Specular Reflecting Surface Included in the law of reflection is the fact that the incident ray, the normal, and the reflected ray all lie in the same plane.
Demo - Candle Burning Under Water Video - Candle Burning Under Water Video - Water Wave Reflections Demo - Mirror Track Tracing – Take home exercise for PQ Points
Plane Mirror Plane Mirror Ray Diagramming
Plane Mirror Plane Mirror Ray Diagramming
Plane Mirrors
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Using ray diagramming one finds that the image is Upright Same size as the object Virtual
Diffuse Reflection
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Video - Diffuse Reflection
• If successive elevations of a surface are no more than l /8 apart, then the surface is said to be polished at that wavelength.
• Most objects are seen by diffuse reflection.
Magnification of a surface Diffuse Reflection
Colored lines are for the purpose of distinguishing reflected rays from incident rays.
• Something that is barely polished for red light would not be polished for blue light.
• Consider microwave satellite dishes. They are polished for microwaves but not for visible.
• The metal screen in a microwave oven serves what purpose?
Reflection from Curved Surfaces (Concave shown here) Ray Diagramming f Principal axis Reflecting Surface The law of specular reflection is still obeyed.
Reflection from Curved Surfaces (Concave shown here) Ray Diagramming f Principal axis Reflecting Surface The law of specular reflection is still obeyed.
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Demo - Coin Mirage
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Demo – Deep Concave Mirror
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Demo - Make-up Mirror Images
• Concave mirrors can produce real inverted images that are magnified, diminished, or the same size as the object.
• Concave mirrors can produce virtual upright images that are magnified.
More on Mirrors • Convex mirrors always produce a diminished, upright, virtual image.
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Demo - Convex Mirror
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Demo - Two Perpendicular Mirrors
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Demo - Three Perpendicular Mirrors
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Demo – Road Reflectors
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Question - Why is it hard to see at night after or during a rain?
Chapter 28 Review Questions
What type of mirror would you use to produce a magnified image of your face? (a) flat (b) concave (c) convex (d) you could use a concave or a convex mirror
What is (are) the purpose(s) of the wire screen in the door of a microwave oven?
(a) to absorb microwaves (b) to allow you to see what's cooking (c) to reflect microwaves (d) all of the above (e) only (b) and (c)
4. REFRACTION
• Fermat's principle can also explain refraction (remember the beach).
• Refraction of light is the bending of light as it passes obliquely from one medium to another.
• It is due to the different speeds of light in the two different media.
Index of Refraction Index of refraction of a material equals the speed of light in a vacuum divided by the speed of light in the material.
n
c v
Demo – Green Laser Refraction in an Aquarium Demo - Twinkling with Laser Slide - Twinkling Cartoon
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Video - Water Wave Refractions
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Video - "Broken" Pencil Refraction
Because of atmospheric refraction, we have lingering, elliptical sunsets.
Sun Sun Earth
Mirage Cool air Warm air Highway Mirage Surface of water?
Looming Warm air Cool air
Chapter 28 Review Question
An oar partially immersed in water appears "broken" because of (a) refraction (b) diffraction (c) polarization (d) interference (e) absorption
5.
CAUSE OF REFRACTION
• When light passes from one medium to another, its speed changes which in turn causes a bending of the light.
• Examples: Car running onto shoulder of road Light passing from air into water
Wave fronts of light q i q R Air Water
• This bending produces illusions.
• Example: Objects in water appear closer and nearer to the surface.
Eye Air Water
Demo – Bow Fishing
Fish can see everything above the surface of water within a 96 0 cone.
96 0
Demo - Disappearing Pyrex
Dispersion
• • Different frequencies are bent different amounts which causes a separation of white light into its constituent colors.
• This is the basic principle behind the operation of a prism. We say that a prism disperses the light.
• The higher frequencies interact most (slow down the most) and thus are bent the most.
Demo - Aquarium Prism
Dis pe rsio
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n a Pr ism White Light Source Slit Prism
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Picture - Rainbow
• Individual drops act as dispersers.
The 42 o cone Demo – Rainbow Model
• A single eye can only see a small range of colors from a single raindrop.
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Double rainbows are dimmer, higher, and have colors reversed.
to picture.
Earth
Green Flash
Sun Dispersion occurs causing multiple images of the sun.
The last to set would be blue, but most of the blue has been scattered which leaves green.
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TOTAL INTERNAL REFLECTION
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Video - Laser Under Water
• Critical angle is the angle where total internal reflection (TIR) begins.
• TIR is possible only when light is entering a medium of lesser index of refraction.
• Binoculars make use of TIR.
Two Prisms in a Monocular
Flex Cam – Monocular
• Fiber optic devices make use of TIR.
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Demo - Laser and Light Pipe
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Video - Woman at Edge of Pool
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Flex Cam – Aquarium and Finger Dip in Water
Chapter 28 Review Questions
A lingering sunset is (a) a looming effect (b) caused by an elliptical (oval) sun (c) due to atmospheric refraction (d) caused by reflections from the upper atmosphere
When a beam of light emerges at a nonzero angle from water to air, the beam (a) bends away from the normal (b) continues in the same direction (c) bends toward the normal (d) changes frequency (e) slows down
7. LENSES
• Lenses use refraction to form images. •
Demo - Fresnel Lens
A Convex Lens Converges Light Rays f
Imaging with a Convex Lens
is bent upon entering the lens.
Arrow as Object A ray parallel to the principal axis and passes through a point called the focal point.
sees an image here.
f Principal Axis An eye placed here Convex Lens A ray passing through the center of the lens is basically undeflected.
This arrangement produces an inverted, real, diminished image.
More Imaging With a Convex Lens Arrow as Object is bent upon entering the lens.
Upon exiting the lens it is bent again and passes through a point called the focal point.
f sees an image here.
Principal Axis Convex Lens An eye placed here A ray passing through the center of the lens is basically undeflected.
A Concave Lens Diverges Light Rays f
Imaging with a Concave Lens
is bent upon entering the lens.
Arrow as Object A ray parallel to the principal axis such that is appears to have come from a point called the focal point.
f Principal Axis sees an image here.
Concave Lens An eye placed here A ray passing through the center of the lens is basically undeflected.
Types of Lenses
Plano Convex Plano Concave Double Convex Double Concave Convex Meniscus Concave Meniscus Convex lenses are positive converging lenses.
Concave lenses are negative diverging lenses.
8. LENS DEFECTS
Spherical Aberration Convex Lens Cure – Diaphragm or lens combination
Chromatic Aberration Convex Lens Cure – Diaphragm or lens combinations (achromatic lens)
Demo – Overhead Chromatic Aberration
Astigmatism – due to barrel-shaped cornea
Eyeglasses •
Picture - Farsightedness
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Picture - Nearsightedness
Chapter 28 Review Questions
One way to reduce the problem of spherical aberration in a positive lens is to join a negative lens to it to form a compound lens.
(a) True (b) False
If you wish to take a picture of your image while standing 5 ft in front of a plane mirror, for what distance should you set your camera to provide the sharpest focus?
(a) 10 ft (b) 5 ft (c) 2.5 ft (d) it can't be done