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Chapter 33: Electromagnetic Waves The above is a sun dog that appears to the left or right of the Sun and sometimes on both sides. Because sun dogs often.

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Presentation on theme: "Chapter 33: Electromagnetic Waves The above is a sun dog that appears to the left or right of the Sun and sometimes on both sides. Because sun dogs often."— Presentation transcript:

1 Chapter 33: Electromagnetic Waves The above is a sun dog that appears to the left or right of the Sun and sometimes on both sides. Because sun dogs often show colors, they can be mistaken for rainbows. However, sun dogs are not produced by water drops as rainbows are. What produces sun dogs? Today’s information age is based almost entirely on the physics of electromagnetic waves. The connection between electric and magnetic fields to produce light is one of the greatest achievements produced by physics, and electromagnetic waves are at the core of many fields in science and engineering.

2 The wavelength/frequency range in which electromagnetic (EM) waves (light) are visible is only a tiny fraction of the entire electromagnetic spectrum. Maxwell’s Rainbow The relative sensitivity of the average human eye to electromagnetic waves at different wavelengths.

3 Although light waves spread as they move from a source, often we can approximate its travel as being a straight line  geometrical optics. Reflection and Refraction What happens when a narrow beam of light encounters a glass surface? Reflection: Refraction: Law of Reflection Snell’s Law n is the index of refraction of the material, See Table 33-1.

4 TABLE 33-1 Some Indexes of Refraction MediumIndexMediumIndex VacuumExactly 1Typical crown glass 1.52 Air (STP)1.00029Sodium chloride 1.54 Water (20° C) 1.33Polystyrene1.55 Acetone1.36Carbon disulfide 1.63 Ethyl alcohol1.36Heavy flint glass 1.65 Sugar solution (30%) 1.38Sapphire1.77 Fused quartz1.46Heaviest flint glass 1.89 Sugar solution (80%) 1.49Diamond2.42

5 The index of refraction n encountered by light in any medium except vacuum depends on the wavelength of the light. So if light consisting of different wavelengths enters a material, the different wavelengths will be refracted differently  chromatic dispersion. Chromatic Dispersion Fig. 33-19 Fig. 33-20 N 2,blue >n 2,red Chromatic dispersion can be good (e.g., used to analyze wavelength composition of light) or bad (e.g., chromatic aberration in lenses). (33-19)

6 Rainbows The most charming example of chromatic dispersion is a rainbow. Primary Rainbow Secondary Rainbow (a) The separation of colors when sunlight refracts into and out of falling raindrops leads to a primary rainbow. The antisolar point A is on the horizon at the right. The rainbow colors appear at an angle of 42° from the direction of A. (d) The separation of colors leading to a secondary rainbow.

7 Total Internal Reflection Total internal reflection takes place in optical fibers, which are used in many applications including in communications and medical technologies.

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