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Radiant Energy or Electromagnetic Energy (EM). All radiant energy travels at 3.0 x 10 8 m/sec in space Velocity of a wave = wavelength x frequency Visible light is just one type of EM Energy. Electromagnetic Spectrum. All of the forms of radiation given off by vibrating electric charges.
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Radiant Energy or Electromagnetic Energy (EM) • All radiant energy travels at 3.0 x 108 m/sec in space • Velocity of a wave = wavelength x frequency • Visible light is just one type of EM Energy
Electromagnetic Spectrum All of the forms of radiation given off by vibrating electric charges Radiation comes in the form of vibrating or “throbbing bundles of energy” called photons The frequency of the vibrating electric charges determines which type and how much energy will be given off
The entire E.M. Spectrum in order from lowest to highest frequency • Radio waves: AM and FM • Microwaves: cooking • Infrared: heat • Visible: (ROYGBV) • Ultraviolet: tanning • Xrays: medical • Gamma: deadly radioactivity
Waves - Energy carried by rhythmic disturbances • Two types: • 1. E.M. radiation move through empty space • 2. Mechanical require a medium (air, water or any type of matter) for movement
All waves have similar properties • Frequency- the number of vibrations per second or the speed of the movement of the vibrating particles • Amplitude – the size of the movement of the vibrating particles • Both are controlled by the disturbance that created the waves
Velocity of all waves - v=f λ f-frequency and λ is wavelength (distance between identical points on two consecutive waves) Reflection- bounce off barriers in regular ways Refraction- waves can change direction when speed changes
And the answer is? J 3300 Hz 38 At 0°C sound travels through air at a speed of 330 m/s. If a sound wave is produced with a wavelength of 0.10 m, what is the wave’s frequency? F 0.0033 Hz G 33 Hz H 330 Hz J 3300 Hz Use the formula chart!!! Velocity = f λ OR 330 m/s = f x 0.10 m
Transverse Waves • In Transverse Waves particles vibrate at right angles to the direction the wave travels. • Ex. E. M. Waves, waves on a slinky or rope coil, ocean waves
Longitudinal or Compress ional Waves Vibrating particles move back and forth along the direction of the wave velocity Parts consist of compressions and rarefactions Ex. Sound Waves
Sound Waves are Compression Waves Sound is produced when a compression is made. It requires a producer and a medium to travel through. The more elastic the object, the faster sound travels.
Sound acts like other waves • Echoes are reflected sound waves • Sonar uses echoes to judge distance to obstructions • Human hearing is 20-20,000 Hz, below 10 Hz is infrasonic, and above 20,000 Hz is ultrasonic.
Sound Waves move through matter not through empty space. 32 One tuning fork is struck and placed next to an identical fork. The two forks do not touch. The second tuning fork starts to vibrate because of — F interference G the Doppler effect H resonance J standing waves Resonance is the vibration of another object struck by a wave of the correct frequency. Since the forks are identical, the second one receives the correct frequency to begin vibrating.