2/11/2024 0 Comments Sound waves diffractWhen light passes through an aperture, most of the beam goes straight through without disturbance, with only the edges experiencing diffraction. Where the aperture or obstruction is large compared to the wave passing through or around it, there is only a little "fuzziness" at the edge, as in the case of the flagpole. This "gray area" is an example of light diffraction. At first, it appears that the shadow is "solid," but if one looks closely enough, it becomes clear that, at the edges, there is a blurringįrom darkness to light. This can be observed by looking closely at the shadow of a flagpole on a bright morning. Hence, most studies of diffraction in light involve very small openings, as, for instance, in the diffraction grating discussed below.īut light does not only diffract when passing through an aperture, such as the concert-hall door in the earlier illustration it also diffracts around obstacles, as, for instance, the post or pillar mentioned earlier. We have already seen that wavelength plays a role in diffraction so, too, does the size of the aperture relative to the wavelength. Observing Diffraction in Lightĭue to the much wider range of areas in which light diffraction has been applied by scientists, diffraction of light and not sound will be the principal topic for the remainder of this essay. Chances are, then, that the most easily audible sounds from inside the concert hall are the bass and drums higher-pitched notes from a guitar or other instruments, such as a Hammond organ, are not as likely to reach a listener outside. As with light waves -though, of course, to a much lesserĮxtent -short-wavelength sound waves are less capable of diffracting around large objects than are long-wave length sound waves. The higher the pitch, the greater the frequency, and, hence, the shorter the wavelength. Whereas differing wavelengths in light are manifested as differing colors, a change in sound wavelength indicates a change in pitch. Wavelengths for visible light range from 400 (violet) to 700 nm (red): hence, it would be possible to fit about 5,000 of even the longest visible-light wavelengths on the head of a pin! Light waves, on the other hand, have a wavelength, typically measured in nanometers (nm), which are equal to one-millionth of a millimeter. The waves by which sound is transmitted are larger, or comparable in size to, the column or the door -which is an example of an aperture -and, hence, they pass easily through apertures and around obstacles. Longitudinal waves radiate outward in concentric circles, rather like the rings of a bull's-eye. Sound travels by longitudinal waves, or waves in which the movement of vibration is in the same direction as the wave itself. The reason for the difference -that is, why sound diffraction is more pronounced than light diffraction -is that sound waves are much, much larger than light waves. But, if you moved away from the door and stood with your back to the building, you would see little light, whereas the sound would still be easily audible. And if you stood right in front of the doorway, you would be able to see light from inside the concert hall. The sound quality would be far from perfect, of course, but you would still be able to hear the music well enough. Suppose, now, that you had failed to obtain a ticket, but a friend who worked at the concert venue arranged to let you stand outside an open door and hear the band. Light waves diffract slightly in such a situation, but not enough to make a difference with regard to your enjoyment of the concert: if you looked closely while sitting behind the post, you would be able to observe the diffraction of the light waves glowing slightly, as they widened around the post. But you have little trouble hearing the music, since sound waves simply diffract around the pillar. You cannot see the band, of course, because the light waves from the stage are blocked. Imagine going to a concert hall to hear a band, and to your chagrin, you discover that your seat is directly behind a wide post. HOW IT WORKS Comparing Sound and Light Diffraction (Because sound waves are much larger than light waves, however, diffraction of sound is a part of daily life that most people take for granted.) Diffraction of light waves, on the other hand, is much more complicated, and has a number of applications in science and technology, including the use of diffraction gratings in the production of holograms. Any type of energy that travels in a wave is capable of diffraction, and the diffraction of sound and light waves produces a number of effects. Diffraction is the bending of waves around obstacles, or the spreading of waves by passing them through an aperture, or opening.
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