![]() ![]() Some natural phenomena also emit infrasound, such as volcanic eruptions (below 20 Hz) and earthquakes (below 10 Hz). They use these signals to communicate over distances up to 10 km. Also, sound waves can behave as longitudinal and transversal when the medium is a solid material.Īs you may imagine, the study of sound waves is mainly concerned with how it propagates through that strange fluid called air, as that's how we usually receive sound.Īlthough we believe we can hear all the sounds emitted by elephants, most of the sounds produced by these animals are low-frequency noises below 20 Hz, known as infrasound. Longitudinal waves are the most relevant in our daily lives as they are present a long as a fluid acts as the propagation medium. The most common example of this type is sea waves. Combined waves: These are a combination of longitudinal and transversal waves.Transverse waves: The particles move back and forth transversely (at right angles) to the wave motion.Longitudinal waves: Each particle moves back and forth in the same direction as the wave.Mechanical waves are classified into three groups, depending on the direction of the periodic motion relative to the movement of the wave: Examples of electromagnetic waves are light, microwaves, and radio waves. Sound is an example of a mechanical wave, and other examples include ripples on the water's surface, seismic shear waves, and water waves. The main difference is that mechanical waves need a medium to travel (a material), whereas electromagnetic waves can travel through a vacuum. There are two main kinds of waves: mechanical waves and electromagnetic waves. Waves occur when there's a disturbance in a system, and that disturbance travels from one place to another. Waves are everywhere and manifest in different ways. Textbook content produced by OpenStax is licensed under a Creative Commons Attribution License. Use the information below to generate a citation. ![]() Then you must include on every digital page view the following attribution: If you are redistributing all or part of this book in a digital format, Then you must include on every physical page the following attribution: If you are redistributing all or part of this book in a print format, Want to cite, share, or modify this book? This book uses the This book may not be used in the training of large language models or otherwise be ingested into large language models or generative AI offerings without OpenStax's permission. In addition, we will see that Huygens’s principle tells us how and where light rays interfere. It is useful not only in describing how light waves propagate but also in explaining the laws of reflection and refraction. Huygens’s principle works for all types of waves, including water waves, sound waves, and light waves. The new wave front is a plane tangent to the wavelets and is where we would expect the wave to be a time t later. We can draw these wavelets at a time t later, so that they have moved a distance s = v t. Each point on the wave front emits a semicircular wave that moves at the propagation speed v. A wave front is the long edge that moves, for example, with the crest or the trough. The new wave front is tangent to all of the wavelets.įigure 1.26 shows how Huygens’s principle is applied. Starting from some known position, Huygens’s principle states that every point on a wave front is a source of wavelets that spread out in the forward direction at the same speed as the wave itself. The Dutch scientist Christiaan Huygens (1629–1695) developed a useful technique for determining in detail how and where waves propagate. The direction of propagation is perpendicular to the wave fronts (or wave crests) and is represented by a ray. The view from above is perhaps more useful in developing concepts about wave optics.įigure 1.25 A transverse wave, such as an electromagnetic light wave, as viewed from above and from the side. The side view would be a graph of the electric or magnetic field. From above, we view the wave fronts (or wave crests) as if we were looking down on ocean waves. A light wave can be imagined to propagate like this, although we do not actually see it wiggling through space. Huygens’s principle is an indispensable tool for this analysis.įigure 1.25 shows how a transverse wave looks as viewed from above and from the side. This is particularly true when the wavelength is not negligible compared to the dimensions of an optical device, such as a slit in the case of diffraction. However, some phenomena require analysis and explanations based on the wave characteristics of light. So far in this chapter, we have been discussing optical phenomena using the ray model of light. Use Huygens’s principle to explain diffraction.Use Huygens’s principle to explain the law of refraction.Use Huygens’s principle to explain the law of reflection.By the end of this section, you will be able to:
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