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WAVES How does energy travel?

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Waves rhythmic disturbances (vibrations) that transfer energy through matter or space carry energy from one place to another Very disturbing!

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Waves Water Waves How does the video display what a wave is? Transfers energy from water to people

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Waves Tuning Fork Demo How does the demo display what a wave is? Transfers energy from fork to water

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Waves Earthquake How does the video of an earthquake in Japan display what a wave is? Transfers energy from seismic wave in earth (earthquake) to building

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Classes of Waves One way to distinguish between different waves is by what they move through or their medium Medium: material through which a wave transfers energy solid, liquid, gas, or combination some waves require no medium Types of waves based on medium: mechanical waves electromagnetic waves

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Mechanical Waves Mechanical waves: waves that require a medium particles of the medium must vibrate in order for energy to be transferred Examples: Water waves Sound waves Seismic waves (earthquakes)

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Electromagnetic Waves Electromagnetic waves: waves that do not require a medium can travel through empty space or matter Empty space: where matter isnt present Examples: radio waves microwaves infrared waves visible light ultraviolet waves X-rays Gamma rays

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More Classes of Waves Not all waves transfer energy the same way Waves can be classified by comparing the direction of particles in the medium to move with the direction in which the wave moves. Two classes of waves: Transverse Longitudinal

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Making Waves With your group members, try to make each class of waves using the provided slinky Transverse Longitudinal

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Slinky Wave Lab With a partner you will discover some more about energy waves!

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Slinky Wave Lab Conclusions 1.) What moves down the slinky as the wave propagates (propagates means moves forward)? Energy 2.) According to the law of conservation of energy, energy cannot be created or destroyed. If so, what is the source of energy that created the wave in this lab? Your hand (mechanical energy) 3.) Once the energy enters the slinky at your hand, where does it go? Down the slinky to the other person

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If the energy is moving from your hand to the slinky from one end of it to the other 4.) In what direction does the medium (look at piece of tape) move compared to the energy of the wave in a transverse wave? Perpendicular to (90 degree angle) 5.)...Longitudinal wave? Parallel to (same direction) Slinky Wave Lab Conclusions

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6.) What can we conclude about the speed of a wave when you change the size of the pulse? The speed of a wave stays the same regardless of the size of the pulse 7.) What factor do you think could affect the speed of a wave? The medium Slinky Wave Lab Conclusions

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8.) What happens to the number of waves between two points when you increase the rate of pulses? More waves 9.) What happens to the width of the waves between two points when you increase the rate of the pulses The width decreases Slinky Wave Lab Conclusions

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Transverse Wave of People The entire class will form a transverse pulse. Stand shoulder to shoulder in a straight line. Create a stadium wave. When the pulse travels through you, which way did you move? How does this compare to the transverse wave of the slinky?

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Transverse Waves Transverse waves: a wave in which the medium moves perpendicular to the direction of wave motion examples: electromagnetic waves, strings on an instrument, some seismic waves

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Anatomy of a Transverse Waves Crest- highest point of transverse wave Trough- lowest point of transverse wave Wavelength- distance from one point on a wave to the corresponding point on the next wave

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Longitudinal Wave of People The entire class will form a longitudinal wave. Line up in a single file. Place your hands on the shoulders of the person in front of you. The person at the back of the line will send some energy to the person at the front of the line by nudging the person in front of them. When the pulse travels through you, which way do you move? When the pulse travels through you, which way did you move? How does this compare to the longitudinal wave of the slinky?

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Longitudinal Waves Longitudinal waves: a wave in which the particles of medium vibrate back in forth in the same direction as (parallel to) the wave also called compressional waves Examples: Sound, some seismic waves

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Anatomy of a Longitudinal Waves Compression- Where the particles of the medium are close together (more dense) Rarefaction- Where the particles of the medium are further apart (less dense) rarefaction compression wavelength