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Exploring Wave Properties and Applications

Discover the characteristics of waves, from vibrations and wave types to interference and the Doppler effect, examining how waves are utilized in various phenomena. Learn about mechanical waves, wave speed, interference, standing waves, and shock waves.

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Exploring Wave Properties and Applications

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  1. Topic • Subtopic • Supporting Detail Essential Question: What are the characteristic properties of waves and how can they be used? Chapter 19: VIBRATIONS AND WAVES

  2. Waves Anything that moves back and forth, to and fro, side to side, in and out, or up and own is vibrating • A wave is a repeating movement or disturbance that transfers energy through matter or space • All waves carry energywithout transporting matter from place to place video

  3. Waves • molecules pass energy along to neighbor molecules who then pass energy to their neighbor molecules • all waves are produced by vibrations • waves will travel as long as there is energy to carry

  4. Mechanical Waves applet • waves that can only travel through a medium • medium: matter through which a wave travels • transverse waves: matter moves back and forth at right angles to direction wave travels • longitudinal waves: matter in medium moves in the same direction that wave travels

  5. Wave Description applet

  6. Wave Description • Vibration and Wave Characteristics • Crests • high points of the wave • Troughs • low points of the wave crest crest trough

  7. Wave Description • Amplitude • distance from the midpoint to the crest or to the trough • a measure of energy in a wave; the more energy a wave carries, the greater the amplitude • Wavelength (λ) • distance between successive identical parts of the wave (crest to crest, rough to trough, compression to compression, or rarefaction to rarefaction)

  8. Wave Description Frequency (f) how frequently a vibration occurs the number of to and fro vibrations in a given time or the number of waves passing any point per second The unit for frequency is Hertz (Hz) A frequency of 1 Hz is a vibration that occurs once each second. Mechanical objects (e.g., pendulums) have frequencies of a few Hz. Sound has a frequency of a few 100 or 1000 Hz. Radio waves have frequencies of a few million Hz (MHz). Cell phones operate at few billon Hz (GHz). 1 Frequency  period

  9. Wave Description Period time for one complete vibration Wave Speed wave speed (v) = frequency (f) x wavelength (λ) v = f λ 1 Period  frequency

  10. Wave Interference Wave interference occurs when two or more waves interact with each other because they occur in the same place at the same time. Superposition principle: The displacement due the interference of waves is determined by adding the disturbances produced by each wave.

  11. Wave Interference Constructive interference : When the crest of one wave overlaps the crest of another, their individual effects add together to produce a wave of increased amplitude. Destructive interference: When the crest of one wave overlaps the trough of another, the high part of one wave simply fills in the low part of another. So, their individual effects are reduced (or even canceled out).

  12. Wave Interference Example: We see the interference pattern made when two vibrating objects touch the surface of water. The regions where a crest of one wave overlaps the trough of another to produce regions of zero amplitude. At points along these regions, the waves arrive out of step, i.e., out of phase with each other.

  13. Standing Waves If we tie a rope to a wall and shake the free end up and down, we produce a train of waves in the rope. The wall is too rigid to shake, so the waves are reflected back along the rope. By shaking the rope just right, we can cause the incident and reflected waves to form a standing wave. applet • standing wave: when two sets of identical waves pass through a medium in opposite directions and the wave appears not to be traveling

  14. Standing Waves Nodes are the regions of minimal or zero displacement, with minimal or zero energy. Antinodes are the regions of maximum displacement and maximum energy. Antinodes and nodes occur equally apart from each other.

  15. Doppler Effect video • Change in frequency of a wave of sound or light due to the motion of the source or the receiver • Increase in frequency when source approaches you (B) • Decrease in frequency when source moves away from you (A)

  16. Doppler Effect • Doppler effect of light • Blue shift • increase in light frequency toward the blue end of the spectrum • Red shift • decrease in light frequency toward the red end of the spectrum

  17. Bow Waves • V-shaped wave produced by an object moving on a liquid surface faster than the wave speed Example: bug swimming as fast as the wave it makes

  18. Bow Waves • Supersonic: Aircraft flying faster than the speed of sound. • An increase in speed will produce a narrower V-shape of overlapping waves.

  19. Shock Waves • Shock wave: pattern of overlapping spheres that form a cone from objects traveling faster than the speed of sound.

  20. Shock Waves • Consists of two cones. • a high-pressure cone generated at the bow of the supersonic aircraft • a low-pressure cone that follows toward (or at) the tail of the aircraft • It is not required that a moving source be noisy.

  21. Shock Waves • Sonic Boom: Sharp cracking sound generated by a supersonic aircraft • Intensity due to overpressure and underpressure of atmospheric pressure between the two cones of the shock waves • Produced before it broke the sound barrier Example: • supersonic bullet • crack of circus whip

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