1. Essential Question: How do waves interact with matter?
Wave Interactions
Essential Question: How do waves interact with matter?
Instructional Approach(s): The teacher should introduce the essential question and the standard that aligns to the essential question

2. Wave Interactions
Waves do not just stop when they reach the end of a medium or when they meet an obstacle in the path.
These interactions include: absorption, reflection, diffraction, and refraction.
We will be examining these interactions in regards to light waves
Instructional Approach(s): The teacher should present the information on the slide while the students record the important information on their notes.

3. Wave Interactions
When waves strike an object, some of the waves are absorbed by the object, some are reflected by it, and some might pass through it (transmitted).
What happens to the wave when it strikes the object depends on the material of the object.
Instructional Approach(s): The teacher should present the information on the slide while the students record the important information on their notes.

4. DEF: is the transfer of energy into matter.
Absorption
DEF: is the transfer of energy into matter.
Some absorbed waves can make things feel warmer.
Instructional Approach(s): The teacher should present the information on the slide while the students record the important information on their notes.

5. Example: When a beam of light shines through the air, particles in the air absorb some of the energy from the light. As a result, the beam of light becomes dim.
Instructional Approach(s): The teacher should present the information on the slide provide examples of light absorption.

6. Example: Light-How we see color
Absorption will be discussed more in the next essential question on how light is detected by the human eye.
Instructional Approach(s): The teacher should present the information on the slide.

7. Reflection DEF: when a wave strikes an object or surface and bounce.
Light reflected from objects is how we see all objects.
Instructional Approach(s): The teacher should present the information on the slide while the students record the important information on their notes.

8. The Law of Reflection The angle of Incidence = The angle of Reflection
Reflected Beam
Incident Beam
Angle of Reflection
Angle of Incidence
Instructional Approach(s): The teacher should present the illustration on the slide to reinforce reflection.

9. If the surface is smooth and even, the reflection will be clear.
Example # 1
If the surface is smooth and even, the reflection will be clear.
Instructional Approach(s): The teacher should present the information on the slide while the students record the important information on their notes.

10. If the surface is uneven, like ripples in a pond, the light is reflected in many directions and the image is not clear.
Instructional Approach(s): The teacher should present the information on the slide while the students record the important information on their notes.

11. Copy This! WU3/8/17.
1. How is the girl able to see the trees outside the window?
2. How is the girl able to see herself on the glass? What Law is this?
3. What does the girl feel when she touches the glass? Why?
Instructional Approach(s): The teacher should present questions to the class or one student. Click on the next slide to show the correct answers.

12. And reflected back into your eyes
You can see objects outside because light is transmitted through the glass
And reflected back into your eyes
Light is reflected off the glass and follows the Law of Reflection.
The glass feels warm when you touch it because some of the light is absorbed by the glass

13. Diffraction
Def: the bending and spreading of waves around a barrier or through an opening.
Depends on its wavelength and the size of the barrier or the opening.
The greatest amount of diffraction occurs when the barrier or opening is the same size or smaller than the wavelength
Instructional Approach(s): The teacher should present the information on the slide while the students record the important information on their notes.

14. Examples Sound travelling around a corner or through a door.
Instructional Approach(s): The teacher should present the illustration on the slide to reinforce diffraction.

15. Instructional Approach(s): The teacher should present the illustration on the slide to reinforce diffraction.

16. Diffraction
Light waves have very small wavelengths; therefore, light waves cannot diffract very much around large obstacles, such as buildings. Thus, you cannot see around corners (but you can hear sound around corners)
Instructional Approach(s): The teacher should present the information.

17. Refraction
DEF: the bending of a wave as it moves from one medium into another.
The speed and wavelength of a wave changes during refraction (velocity changes).
Instructional Approach(s): The teacher should present the information on the slide while the students record the important information on their notes.

18. The speed of light varies depending on the material through which the waves are traveling. When a wave enters a new material at an angle, the part of the wave that enters first begins traveling at a different speed from that of the rest of the wave.
Instructional Approach(s): The teacher should present the illustration on the slide to reinforce rarefaction.

19. Example: the illusion of a bent straw or spoon in a clear glass of water.
Light waves travel faster in air than in water, so as it passes through the water, it slows down and appears to bend.
Instructional Approach(s): The teacher should present the illustration on the slide to reinforce rarefaction.

20. Example 2
Submerged objects always appear to be shallower than they are because the light from them changes angle at the surface, bending downward toward the water.
Instructional Approach(s): The teacher should present the illustration on the slide to reinforce rarefaction.

21. Example 3: Rainbows.
As light passes through a prism, such as a crystal or a drop of water, refraction causes light to bend and separate into many colors.
Instructional Approach(s): The teacher should present the illustration on the slide to reinforce rarefaction.

22. Interference The interaction between waves that meet.
Constructive- Waves adding their energy to make a wave with a bigger amplitude
Destructive- waves cancelling their energy make a wave with a smaller amplitude.

23. Distributed Summarizing
Explain the difference between Diffraction and Refraction. Give examples of both. How is refraction an optical illusion?
Instructional Approach(s): Think-pair-share. The teacher should walk among the students and listen to ensure mastery and understanding.