Reflection and Mirrors Ch. 29 in your text book
Objectives – Students will be able to: 1) Identify the incident and reflected angle 2) Explain why mirrors need to be smooth in order to work well. 3) Draw the location of the virtual image produced by a mirror. Reflection
Incident ray – the ray of light approaching the material
Reflected ray – the ray of light leaving Incident ray the material Reflected ray
The normal line is always placed where the incident ray hits the material surface. Reflection
Incident angle – the angle between the Incident angle Reflected angle normal and the incident ray of light Incident ray θ θ Reflected ray Reflected angle – the angle between the normal and the reflected ray of light Reflection
Use your hands to show me a line that is normal to the following lines? Reflection Lab Reflection
The reflected angle and incident angle will always be the same. These angles are measured with respect to the normal line.
Reflected angle 30° How large is the incident angle? θ 60° Reflected ray Reflection
The reflected angle and incident angle will always be the same. These angles are measured with respect to the normal line.
How large is the incident angle? 40° 50° Reflection
The reflected angle and incident angle will always be the same. These angles are measured with respect to the normal line.
How large is the incident angle? 65° 25° Mirrors
We see the light that enters our eye. Mirrors need to be smooth in order to reflect light well. No surface is perfectly smooth, but the smaller the bumps are, the smoother the surface is. Mirrors
When we polish something, all we’re doing is making smaller bumps on the surface. Mirrors
Smooth surfaces reflect Rough surfaces reflect light in more light in the same many directions. direction. Mirrors
A mirror is often glass with a reflective side view of a mirror surface on one side.
Reflective surface glass All mirrors create images, either real or virtual Flat Mirrors
Virtual image – An image created by the illusion that light is coming from an object or passing through it. Light does not come from a virtual image. Most mirrors produce this kind of image. Flat Mirrors
The image in a flat mirror is as far from the mirror as the object is.
Check for understanding: If you are doing your makeup one foot away from the mirror, how far away from you is the image of yourself that you’re looking at? 4m 4m
8m Flat Mirrors Check for understanding: With your partner, answer the following questions about the image below How far from the man is the virtual image of himself? How far from the chair is the virtual image of itself? How far from the man is the virtual image of the chair? Ray Diagrams For Mirrors
A ray diagram lets us see the path that an isolated ray of light travels. These diagrams help us figure out what we see when light is reflected. Ray Diagrams For Mirrors
Light leaves the red dot, reflects off the mirror, and hits our eye. How do we draw that ray diagram? The normal line needs to be half way between the object and your eye
The incident and reflected rays will make the same angle to the normal. If the incident and reflected angles are different, it means the normal line isn’t half way between the object and the eye. Reflection
Where do we see image in the mirror?
We think we see it along the same line as the reflected ray that hits our eye. Reflection In your notes, draw how the light reflects from the mirror into our eyes and draw where the image is that we see in the mirror. Reflection
This is not the reflected ray, but it still is at the same angle to the normal Reflection How would we draw the image of the box in the mirror? 1) Choose two points that aren’t next to each other 2) Start by draw a horizontal ray from each point to the mirror. 3) Draw normal lines
4) The reflected angle needs to be the same as the incident angle. The arrows will also need to be the same length. Not all mirrors are flat. Curved Mirrors
With your partner, come up with a couple examples of where we see these types of mirrors used. Curved Mirrors
Concave mirror – rays converge to one location (focus) Reflections For Concave Mirrors Curved mirrors follow the same rules as flat mirrors – the reflected angle is the same as the incident angle. Curved Mirrors
Convex mirror – rays diverge, spread out Reflections For Convex Mirrors Curved mirrors follow the same rules as flat mirrors – the reflected angle is the same as the incident angle. U of A Mirror Lab U of A Mirror Lab U of A Mirror Lab U of A Mirror Lab
These mirrors are very carefully, precisely polished. It doesn’t take much for them to completely miss what they’re trying to see. If the reflection is a small fraction of a degree off at the mirror, it will end up being sent way off the path we intended. To Finish Up… On the small piece of paper, please do the following: D 1) Identify the incident angle in the diagram to the right. C 2) Explain why mirrors need to be smooth in order to work B well. A 3) Draw the location of the virtual image of the Dorado head (don’t worry about too much detail)
flat mirror
Snell’s law Light goes from small n to larger n – angle moves toward normal Light goes from larger n to small n – angle moves away from normal Check for understanding on angle moving to or from normal Larger n = slower speed of light Check for understanding – Rank the following n for how fast light travels, rank fastest to slowest Show light going through 5 different materials – rank indices of refraction from biggest to smallest; rank speed of light from fastest to slowest Examples of calculations, specifically how to get the angle