Unit 5: Optics: Mirrors & Lenses When waves interact with matter, they can be reflected, transmitted, or a combination of both (refracted).

return of a wave back to its original medium Reflection reflection: return of a wave back to its original medium The wall is a very rigid medium compared with the spring, so all the wave energy is reflected back along the spring. Waves that travel along the spring are almost totally reflected at the wall.

medium boundary Reflection If the wall is replaced with a less rigid medium, such as a heavy spring, some energy is transmitted into the new medium. The incoming wave is partially reflected. medium boundary

straight-line describing the direction of incident and reflected waves The Law of Reflection ray: straight-line describing the direction of incident and reflected waves normal: a line perpendicular to the surface

= angle of incidence: between the incident ray and the normal The Law of Reflection angle of incidence: between the incident ray and the normal angle of reflection: between the reflected ray and the normal Law of Reflection: angle of incidence angle of reflection =

The Law of Reflection think! If you look at your blue shirt in a mirror, what is the color of its image? What does this tell you about the incident frequency of light compared with the reflected frequency? Answer: The color is the same because the frequency of light is not changed by reflection.

Mirrors If a candle flame is placed in front of a plane mirror, rays of light from the candle are reflected from the mirror in all directions. Each of the infinite number of rays obeys the law of reflection. These reflected rays appear to originate from a point located behind the mirror.

appears where light does not actually reach Mirrors You perceive the candle flame to be located behind the mirror. virtual image: appears where light does not actually reach Mirrors only produce virtual images. The image and object are the same size.

Mirrors convex mirror: curves outward forming a virtual image smaller and closer than the object is. concave mirror: (“caved in”) curves inward forming a virtual image larger and further away than the object is.

reflection of light from a rough surface Diffuse Reflection diffuse reflection: reflection of light from a rough surface The many different angled incident rays reflect in many directions as each ray follows the law of reflection. Is the Law of Reflection observed here? YES!

Diffuse Reflection A surface may be polished for long wavelengths, but not polished for short wavelengths. Incident rays of light on paper encounter millions of tiny flat surfaces facing in all directions, so they are reflected in all directions.

When a wave reaches a boundary it … can partially or totally reflect. Quick Quiz! When a wave reaches a boundary it … can partially or totally reflect. cannot reflect into the first medium. scatters. is absorbed into the second medium.

The law of reflection applies to … only partially reflected waves. Quick Quiz. The law of reflection applies to … only partially reflected waves. only totally reflected waves. only normal waves. both partially and totally reflected waves.

Your image behind a plane mirror is at a distance equal to… Quick Quiz. Your image behind a plane mirror is at a distance equal to… half your height. half your distance from the mirror. your distance in front of the mirror. slightly more than your distance in front of the mirror.

angle of incoming light. Quick Quiz. A surface may be a polished reflector or a diffuse reflector depending on the … color of light. brightness of light. wavelength of light. angle of incoming light.

It will be deflected from its straight-line course. Refraction It will be deflected from its straight-line course. The path bends toward the normal. Then, it continues in a straight line at slower speed, but in a bent direction. refraction: bending of a wave across the boundary between two media at an angle

Refraction of Sound Does sound travel faster through warm or cool air?

Due to the refraction of light: a pencil in a glass of water appears bent swimming pools appear shallower the air above a hot road seems to shimmer (mirage) stars twinkle The directions of the light rays change because of refraction.

Refraction of Light As a light wave passes from air into water, or from a faster to a slower medium, it refracts. (and from slower to faster)

Refraction of Light When light rays enter a faster medium the rays bend away from the normal. When light rays enter a slower medium, the rays bend toward the normal.

Refraction of Light

Refraction of Light

Atmospheric Refraction The sky appears to be reflected from a wet surface, but, light is being refracted through a layer of hot air.

Atmospheric Refraction A distorted image, called a mirage, is caused by refraction of light in Earth’s atmosphere. A layer of very hot air is in contact with the ground on very hot days. Light travels faster through hot air than through the cooler air above which gradually refracts the light rays.

Refraction occurs when a wave crosses a boundary and changes… speed. Quick Quiz! Refraction occurs when a wave crosses a boundary and changes… speed. direction. frequency. amplitude.

Changes in wind speed and temperature cause sound waves to… reflect. Quick Quiz. Changes in wind speed and temperature cause sound waves to… reflect. reverberate. refract. scatter.

Refracted light that bends away from the normal is light that has… Quick Quiz. Refracted light that bends away from the normal is light that has… slowed down. speeded up. nearly been absorbed. diffracted.

Converging and Diverging Lenses glass or plastic that forms an image by bending (refracting) parallel rays of light that pass through it WB p. 113-114 p. 477 #1,3-6 p. 478 #21

converging lens (convex lens): Converging and Diverging Lenses converging lens (convex lens): bends parallel rays of light to converge at a single point diverging lens (concave lens) bends parallel rays of light to appear to originate from a single point

Converging and Diverging Lenses The principal axis of a lens is the line joining the centers of curvature of its surfaces. focal point: point at which a beam of light parallel to the principal axis converges. focal length: distance between the lens center and focal point

Image Formation by a Lens A converging lens can be used as a magnifying glass to produce a virtual image of a nearby object. A converging lens will magnify only when the object is between the focal point and the lens. When you use a magnifying glass, you hold it close to the object to see it magnified.

Ray Diagrams Ray diagrams show the principal rays that can be used to determine the size and location of an image. An arrow is used to represent the object. For simplicity, one end of the object is placed right on the principal axis.

Converging Lens Directions Ray Diagrams A ray Parallel to the principal axis will be refracted by the lens to the focal point.

Converging Lens Directions Ray Diagrams A ray Parallel to the principal axis will be refracted by the lens to the focal point. A ray will pass through the Center with no appreciable change in direction.

Converging Lens Directions Ray Diagrams A ray Parallel to the principal axis will be refracted by the lens to the focal point. A ray will pass through the Center with no appreciable change in direction. A ray that passes through the Focal point in front of the lens emerges from the lens parallel to the principal axis.

Ray Diagrams If the distance from the lens to the object is less than the focal length, the rays diverge from the lens. The location of the image is found by extending the rays backward to the point where they converge.

animation Ray Diagrams

Diverging Lens Directions Ray Diagrams A ray parallel to the principal axis will be bent by the lens as if it had come from the focal point. A ray through the center goes straight through. A ray toward the focal point on the far side of the lens is bent so that it emerges parallel to the axis.

Diverging Lens Directions Ray Diagrams On emerging from the lens, the three rays appear to come from a point on the same side of the lens as the object. The image formed by a diverging lens is always virtual, smaller, and right-side up.

The action of lenses depends mainly on … Quick Quiz! The action of lenses depends mainly on … convexing light in various directions. changing the direction of light rays or waves. converging light rays or waves. diverging light rays or waves.

Quick Quiz. The minimum number of light rays necessary to construct the position of an image is … one. two. three. four.

A diverging lens forms … only a real image. only a virtual image. Quick Quiz. A diverging lens forms … only a real image. only a virtual image. both a real image and a virtual image. a perfect image.