Period 2 Activity Solutions: Electromagnetic Waves Radiant Energy I

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Period 2 Activity Solutions: Electromagnetic Waves Radiant Energy I 2.1 How Do Electromagnetic Waves and Other Waves Transmit Energy? Your instructor will discuss the properties of waves. 1) Stretch a slinky across your table with one student holding each end. a) Vibrate one end of the slinky to send sine waves along it. What can you do to increase the frequency of the waves? Vibrating the slinky faster increases the frequency of the waves (how often one of the wave crests passes a given point on the table). b) What does increasing the frequency of the waves do to the wavelength? The wavelength becomes shorter. c) Place a Styrofoam ball near the slinky. Send one pulse wave along the slinky to knock the ball off of the table. Is it possible to transfer energy without a transfer of matter? Some of the energy of the wave is converted into the kinetic energy of the ball. This is an example of transferring energy with no transfer of matter (no matter was transferred down the slinky, and no matter was transferred to the ball). d) Group Discussion Question: List examples of transfer of energy without a transfer of matter. 2) Make measurements on the diagrams below to find the speed of the wave. a) Find the wavelength (in meters) of the wave in the diagram. 3 cm = 0.03 m Displacement 1 2 3 4 5 6 7 8 9 10 Distance (in cm) 1

Your instructor will discuss wave periods and frequency. b) Find the period of the wave in the diagram below. _1.5 seconds_ Displacement 0.5 1,0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 Time ( in sec) c) Calculate the frequency of the wave (in cycles/second, or Hertz). frequency = 1/period = 1/1.5 sec = 0.67 cycles/sec = 0.67 Hz d) Calculate the speed of this wave. S = f L = 0.67 Hz x 0.03 m = 0.02 m/s = 2 x 10 2 m/s e) Based on the speed you calculated, could these diagrams represent of a wave of electromagnetic radiation? Why or why not? This could not be a wave of electromagnetic radiation because it is traveling too slowly. All waves of electromagnetic radiation travel at the speed of 3 x 10 8 m/s (in a vacuum). When traveling in other media, such as air or water, the speed of electromagnetic waves is only slightly slower. f) Find the wavelength of a wave of electromagnetic radiation that has a frequency of 6 x 10 14 Hz. S = f L, or L = S = 3 x 10 8 m/s = 0.5 x 10 6 m = 5 x 10 7 m f 6 x 10 14 1/s 3) Your instructor will demonstrate the bell jar with a buzzer and a light bulb. a) Describe the differences you observe between sound waves and waves of electromagnetic radiation. Sound waves cannot move through a vacuum, as in the bell jar, but waves of electromagnetic radiation can. b) A sound wave has a wavelength of 0.5 meters and a frequency of 680 Hz. What is the speed of this wave? S = f L = 680 Hz x 0.5 m = 340 m/s 4) How many times greater is the speed of light than the speed of sound? Sound waves travel at varying speeds, always much slower than electromagnetic waves, which travel at 3 x 10 8 m/s (186,000 miles/s 2

in a vacuum). A typical sound wave travels at approximately 300 m/s in dry air. speed of light = 3 x 10 8 m/s = 1 x 10 6 times faster speed of sound 3 x 10 2 m/s 5) Group Discussion Question Scaling Quantities. Try to answer the following questions without using your calculator. 1) If the distances in graph 2.a were in meters, what would be the speed of the wave? 2) If the times in graph 2.b were in minutes, rather than seconds, what would be the speed of the wave? 2.2 What is the Electromagnetic Spectrum? 6) Examples of electromagnetic radiation Your instructor will demonstrate electromagnetic radiation of different wavelengths and frequencies. a) Radio waves Which devices operate using radio waves? Radio, walkie-talkies, remote control cars b) Microwaves Which devices use microwaves? Microwave oven, cellular phones, garage door opener, c) Infrared radiation 1) Which devices illustrate infrared radiation? TV remote, glow coil, infrared camera, radiometer. 2) How do we experience this type of electromagnetic radiation? If you closed your eyes, how could you tell if an incandescent light bulb was lit? We experience infrared radiation as heat (thermal energy). You could feel the heat from a nearby incandescent bulbs. d) Visible light 1) Look sideways at a pencil in a cup of water. Does the pencil appear to bend? Yes What is it that actually bends? Light waves travelling from the pencil to your eyes bend as they pass through the surface of the water. The light waves bend because the index of refraction of light in water is greater than the index of refraction of air. 2) Shine a light through a slit and then through a prism and onto a sheet of paper. What happens to the beam of light from the flashlight? The beam of light is split into colors by the prism. 3) List the colors of visible light from longest to shortest wavelength. Red, orange, yellow, green, blue, violet 4) Why is the light beam bent as it travels through the prism? When light enters a transparent medium such as glass, plastic, or water, the speed of the light wave changes. If the light 3

enters the medium at an angle to the surface, the change in speed causes the light to be refracted, or bent away from the surface of the medium. e) Ultraviolet light Which devices illustrate ultraviolet radiation? The black light bulbs emit ultraviolet radiation as well as visible violet visible light. f) X rays What are some uses of X ray radiation? X rays can penetrate soft body tissue but not bone, allowing a picture of the bone structure. X rays can be used to diagnose illnesses and treat diseases such as cancer. g) Gamma rays Hold the block containing a Cobalt-60 sample near the Geiger counter. Describe what happens. The Geiger counter clicks, indicating counts of gamma ray radiation. (We will study gamma rays in more detail in a future period.) 2.3 What is the Quantum Model of Electromagnetic Radiation? 7) Your instructor will discuss the quantum (photon model) of radiant energy a) Find the energy of a photon with a frequency of 5 x 10 12 Hz. E = h f = (6.63 x 10 34 J s) x (5 x 10 12 1/s) = 33.2 x 10 22 J = 3.32 x 10 21 J b) What is energy of a photon with a wavelength of 2 x 10 6 meters? E = h c = (6.63 x 10 34 J s) x (3 x 10 8 m/s) = 9.95 x 10 20 J L 2 x 10 6 m 2.4 How Can the Quantum Model Explain the Operation of Solar Cells? 8) Observe the demonstration of a toy that operates with power from a solar cell. Does the solar toy work when an incandescent bulb shines on its solar cell? Does it work when a glow coil shines on its solar cell? Explain your observations. The solar toy runs when photons of visible light are absorbed by the solar cell. The absorbed photons eject electrons from atoms in the cell. These electrons generate an electric current. However, the photons of infrared light from the glow coil do not have enough energy per photon to eject an electron from an atom. 9) Solar Cells Try to operate the solar-powered toy by shining different radiant light sources onto the solar cells. a) First, predict which light sources will operate the solar cells. Then check your predictions by shining each light source onto the solar cells. Prediction Answer 1) microwaves No 2) visible light Yes 3) ultraviolet light Yes 4

b) Why do some light sources operate the solar cells, while other sources do not? Microwaves do not have enough energy per photon to operate the solar cells. Waves of visible light and ultraviolet light have shorter wavelengths and higher frequencies than microwaves. Visible light photons and ultraviolet light photons have enough energy per photon to produce a flow of electrons. c) Explain why solar cells are also called photoelectric cells. Solar cells produce an electric current when their atoms absorb photons of energy equal to or greater than the frequency of visible light. Absorbed photons with sufficient energy can eject electrons from their atoms in the cell. The electrons form an electric current. 10) Suppose that a solar cell produces an electric current only when it absorbs photons with at least 2.5 x 10 19 joules of energy per photon. What is the maximum wavelength of electromagnetic radiation that will make the solar cell work? What type of electromagnetic radiation is this? h c E = L = L 34 This is a photon of visible light. 11) Group Discussion Question: If visible light has enough energy per photon to make the solar cell operate, which other forms of electromagnetic radiation do you think would operate the solar cell? Which forms of electromagnetic radiation would not work? 8 h c E ( 6.63 x 10 J s) x (3 x 10 m/s) 7 = = 8.0 x 10 m 19 2.5 x 10 J 5

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