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Chapter 18: Waves and Energy Transfer

Chapter 18: Waves and Energy Transfer. Catch the Wave!. Amplitude. 18.1 Wave Properties. Interference. Mechanical Waves. Trough and Crest. LONGITUDINAL WAVES. TRANSVERSE WAVES. Surface Waves. California Standards.

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Chapter 18: Waves and Energy Transfer

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  1. Chapter 18: Waves and Energy Transfer Catch the Wave!

  2. Amplitude 18.1 Wave Properties Interference Mechanical Waves Trough and Crest LONGITUDINAL WAVES TRANSVERSE WAVES Surface Waves

  3. California Standards 4. Waves have characteristic properties that do not depend on the type of wave. As a basis for understanding this concept: 4a. Students know waves carry energy from one place to another. 4b. Students know how to identify transverse and longitudinal waves in mechanical media, such as springs and ropes, and on the earth (seismic waves). 4c. Students know how to solve problems involving wavelength, frequency, and wave speed. 4f. Students know how to identify the characteristic properties of waves: interference (beats), diffraction, refraction, Doppler effect, and polarization.

  4. 18.1 Objectives Identify how waves transfer energy without transferring matter. Contrasttransverse and longitudinal waves. Relate wave speed, wavelength, and frequency.

  5. Waves: Friends or Foes? Have you ever watched surfing or done it yourself? Ocean waves can be loads of fun. But at the same time they are very dangerous. You do not want waves to be too big. The Tsunami in Indonesia reminds us of that. Ocean waves contain energy. But where does it come from? Normal weather creates the winds that make normal sized waves. Storms, monsoons, and hurricanes, create the stronger winds that make larger waves. Earthquakes can make wave disturbances that can catapult water several miles inland.

  6. Anatomy of a Tsunami Indonesian Tsunami 12/26/04

  7. Ocean Waves

  8. Concept Development Map Definitions What is it? Applications A “wiggle in space and time”; a disturbance propagated from one place to another with no actual transport of matter. Middle English: wagen = in motion; restless English: Wag - to move Pendulum: String and ball Spring: Spring and weight Related words: Wavering, wavy Wave Liquids: Ocean waves To move one way and then the other, to and fro. To vacillate. To shake or vibrate. Curve up and then curve down. Sound: Voice, music Examples Do thewave. Microwaves, Light Banners wavering in the wind.. “New wave” music.

  9. Concept Development Map What is it? Definitions Applications A wave in which the individual particles of a medium vibrate from side to side perpendicular to the direction in which the wave travels. Latin: trans (across) + versus (to turn); a line that crosses an axis line Jump Rope Waves Spring and weight: Gravity Geometry: A transversal line crosses two or more parallel lines. Transverse Ocean waves are L+T To vibrate across the direction of travel. Earthquakes S-waves Examples Audience Wave Medical: Transverse muscles/arteries. Transverse a desert. Geometry: Transversal.

  10. Concept Development Map Definitions What is it? Applications A wave in which the individual particles of a medium vibrate back and forth in the direction in which the wave travels. Latin: longitude longus = long; extending in length Sound Waves Spring: Compressions Geo: Longitude is distance parallel to the prime meridian. Longitudinal Ocean waves are L+T To vibrate in the direction of travel. A “longitudinal” is a railway sleeper lying parallel to the rail. Earthquakes P-waves Examples Ultrasound Geography: Longitude. Ships: Longitudinal framing. Railraod: Longitudinal sleeper.

  11. What is a Wave? A wave is a rhythmic disturbance that carries energy through matter or space. Waves transfer ENERGY only, not matter. Wave Pulse - A single disturbance traveling through a medium. A medium is the material through which the wave travels. Continuous Wave - A continuous disturbance is generated from a source that travels through a medium.

  12. Mechanical Waves Transverse Wave - The disturbance vibrates perpendicular to the direction of wave travel (TRANS = Across). The simplest example is achieved by shaking a rope up and down. Longitudinal Wave - The disturbance vibrates parallel to the direction of wave travel (LONGITUDINAL = Along direction of travel). The simplest example is achieved by the squeeze and release of a coiled spring.

  13. Anatomy of a Wave A crest is the highest point. A trough is the lowest point. A node is where there is no movement. Can you see it? Anatomy of a wave Amplitude and Wavelength Wave Parts: w/ Frequency

  14. Anatomy of a Wave A node is where there is no movement. Can you see it? A crest is the highest point. A trough is the lowest point.

  15. Anatomy of a Wave The wavelength of a wave is the shortest distance between repeating points of the wave (i.e. crest to crest, trough to trough).

  16. Longitudinal and Transverse Waves

  17. Longitudinal/Transverse Demo

  18. Wave Speed Wave Speed - The distance a wave travels in a given time. It is given as the frequency times the wavelength.

  19. 18.2 Waves Behavior

  20. 18.2 Objectives Relate a wave’s speed to the medium in which the wave travels. Describehow waves are reflected and refracted at boundaries between media, and explain how waves diffract. Apply the principle of superposition to the phenomenon of interference.

  21. Incidence and Reflection Incident Wave - The wave that strikes the boundary, the incoming wave. Reflected Wave - The wave that returns from the boundary, the returning wave. Inverted Wave - Often the reflected wave is inverted (upside down) by the boundary if it is a wall.

  22. Reflected and Inverted Waves

  23. Superposition and Interference Principle of Superposition - The algebraic sum of the displacements of the waves. If we superimpose several waves on top of each other, like when you stack transparencies, then add the values a each x-axis position, you get a combined wave. Destructive Interference - The superposition of waves with displacements in the opposite direction. Constructive Interference - The superposition of waves with displacement in the same direction.

  24. Superposition Simple Wave Superposition Wave Superposition More Wave Superposition

  25. Standing Wave Standing Waves - A wave with stationary nodes and antinodes.

  26. Standing Waves Demo

  27. Reflection, Refraction, Diffraction Reflection - to bend or return back. The change in the direction of a wave at a surface. There is a returning wave that is either inverted or displaced in the same direction as the incident wave. Refraction - to break or impair. The change in direction of a wave crossing a boundary between two different media. Thedifferent wave speed of the two media causes the bending. There is no returning wave. Diffraction - to bend, break. The bending of waves around a barrier. The spreading of waves as they pass through a hole, slot, or slit. There is no returning wave.

  28. Reflection Reflection - (Re= again) to bend or return back. The change in the direction of a wave at a surface. There is a returning wave that is either inverted or displaced in the same direction as the incident wave. It is like “seeing it again”.

  29. Refraction Refraction - to break or impair. The change in direction of a wave crossing a boundary between two different media. Thedifferent wave speed of the two media causes the bending. There is no returning wave. Refraction Demo

  30. Diffraction Diffraction - to bend, break. The bending of waves around a barrier. The spreading of waves as they pass through a hole, slot, or slit. There is no returning wave.

  31. Tacoma Narrows Bridge

  32. Wwwhhhaaattt Happened? What do you think happened to the Tacoma Narrows Bridge? This is an example of Bernoulli’s Principle leading to oscillations (waves). The large vertical plates oscillated due to the wind passing by. By Bernoulli’s Principle, the wind created pressure differences above and below the vertical plates. This was transformed to wave motion (oscillations).

  33. Wave Examples Spring Wave - An oscillating spring is a longitudinal wave. It moves in ONE dimension (1D). Water Wave - An ocean wave has properties of both longitudinal and transverse waves. It moves in TWO dimensions (2D). Sound Wave - A sound wave is a longitudinal wave. It moves in THREE dimensions (3D).

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