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Light Waves. What is Light? Light is the range of frequencies of the electromagnetic spectrum that stimulate the retina of the eye.

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Presentation on theme: "Light Waves. What is Light? Light is the range of frequencies of the electromagnetic spectrum that stimulate the retina of the eye."— Presentation transcript:

1 Light Waves

2 What is Light? Light is the range of frequencies of the electromagnetic spectrum that stimulate the retina of the eye.

3 Light & Matter Transparent (Glass): Materials that allow light to pass through without distorting images. Translucent (Cloudy Glass): Materials that allow light to pass through them, but do not allow them to be seen clearly. Opaque (Brick): Material in which all light is absorbed or reflected. Not is transmitted through.

4 Reflection and Absorption of Light and Color The color observed by any object is the same as that not absorbed by the object. For example, a red block will absorb all colors of the EM visible light spectrum except for red. How does this apply to the clothes we wear?

5 Continuous Waves When a wave impacts a boundary, some of the energy is reflected, while some passes through. The wave that passes through is called a transmitted wave. A wave that is transmitted through a boundary will lose some of its energy. Electromagnetic radiation will both slow down and have a shorter wavelength when going into a denser media. Sound will increase in speed when transitioning into a denser media. Speed of Light in different mediums

6 Higher speed Longer wavelength Lower speed Shorter wavelength Continuous Waves – Higher Speed to Lower Speed Note the differences in wavelength and amplitude between of the wave in the two different mediums Displacement Boundary Incident + Reflected Wave Transmitted Wave v1v1 v2v2 -v 1 Note: This phenomena is seen with light traveling from air to water.

7 Incident + Reflected Wave Lower speed Shorter wavelength Higher speed Longer wavelength Transmitted Wave -v 1 v2v2 v1v1 Continuous Waves – Lower Speed to Higher Speed Note the differences in wavelength and amplitude between of the wave in the two different mediums Boundary

8 Law of Reflection The angle of incidence with respect to the normal is equal to the angle of reflection.

9 Specular & Diffuse Reflection Light incident upon an object with a smooth surface will create specular reflection. Light incident upon an object with a rough surface will create diffuse reflection.

10 Refraction of Light When light travels through a surface between two different media, the light will be refracted if the angle of incidence is greater than zero. If light is passing into a more dense media, it willbend towards a normal with the boundary.

11 Law of Refraction (Snell’s Law) The ratio of the sine of the angle of incidence to the angle of refraction is a constant. n 1 sin 1 = n 2 sin 2 Where: n 1, n 2 = index of refraction  1 = Angle of incidence  2 = Angle of refraction Note, the incident ray will always bend towards the normal when transitioning from a material with a lower index of refraction to one with a higher index of refraction. www.sol.sci.uop.edu

12 Speed of Light and the Index of Refraction The index of refraction, by definition, is the ratio of the speed of light in a vacuum to the speed of light in a substance. The index of refraction is always greater than 1.

13 Total Internal Reflection When the angle of incidence is such that the angle of refraction is equal to 90 o, the critical angle ( c ) has been attained. All rays will be reflected internally at all angles greater than this angle.  c = sin -1 (n 2 /n 1 ) Note: Internal reflection can only occur if n 2 < n 1. Internal Reflection (Use PHET) Internal Reflection Application – fiber optic cable www.micro.magnet.fsu.edu 1 2 1 2

14 Homework: Light I Light I: Chapter 16 16, 18, 31, 32, 33, 41 16. Wavelength decreases as freq inc. 18. Screen B has ¼ the illumination of Screen A 31. 7x 10E-7m 32. d = vt = 3E8m/sec * 1.28s = 3.84E8m 33. d = vt  d/v = t = 1.5E8km/3E8m/sec = 1.5E11m/3E8m/sec = 500 sec 41.d = vt = 3E8 * 0.1s = 3E7m = 3E4km. Since we are talking about a round trip time, a distance of 1.5E4km is needed.

15 Reflection Lab Angles Angle 1Angle 2Angle 3Angle 4Angle 5Angle 6 A105015252030 B 2045253530 C554030103545 D 6550401055 E405545605030 F605065453060 G203060455515 H502040601030

16 Have you ever seen this?

17 MiragesMirages can happen at any time of the year,but they are more commonly seen during the summer due to the hotter temperatures. The temperature difference between the layers of air is more important to the formation of a mirage than the actual temperature. The greater the difference in temperature the greater the bending effect.

18 Science (cont.) There are two types of mirages. Superior and inferior mirages. Mirages are caused by light rays passing through a layer of hot air near the surface. This causes a bending effect. When the light rays are refracted a mirage is created.Superior and inferior miragesrefracted

19 Light Passing Through Glass θ1θ1 θ4θ4 θ3θ3 θ2θ2 Incident Ray Reflected Ray Refracted Ray Air Glass Note:  1 =  4  2 =  3 The light exiting the glass is parallel to the light entering it.

20 Start Period 1 here

21 Sunset is an illusion

22 Light II Chapter 17 p. 410 5, 6, 8, 10, 11 5. Angle of incidence is greater than angle of refraction 6. Angle of incidence is less than angle of refraction. 8. index of refraction times sine of angle of incidence = index of refraction times sine of angle of refraction 10. Angle of incidence that produces an angle of refraction whose sine is 90 degrees. 11. Total internal reflection.

23 Chromatic Dispersion When white light enters a medium, the different wavelengths that comprise the light will travel at different speeds. If the angle of incidence is greater than zero, the wave will exhibit chromatic dispersion. Note: The shorter the wavelength, the greater the bending. What happens to the frequency? NOTHING www.physics.uiowa.edu

24 Diffraction of Light When a wave front is incident on a barrier with an opening, the wave will spread out after crossing the barrier. This process is called diffraction. Diffraction is an interference phenomena. As the slit becomes narrower, the amount of diffraction will increase. As the wavelength of light increases, the amount of diffraction will increase. Diffraction

25 Is light a Wave? Young Double-Slit Experiment: The wave properties of light were first demonstrated by Thomas Young in 1801. Showed that light undergoes interference in and diffraction in much the same way that water and sound waves do. Used a source of monochromatic light so that only one wavelength was chosen. Also used light with no phase difference.

26 Young Double-Slit Experiment www.src.wits.ac.za Huygen’s Wavelets

27 Young Double Slit Experiment www.hyperphysics.phy-astr.gsu.edu

28 Young Double Slit Experiment  (delta) = r 2 – r 1 If r 2 – r 1 is equal to some multiple of, then the image on the screen will be a maximum (constructive interference). If we assume that D is very big and r 1 and r 2 are parallel, then the angle between them will be .  = d sin  or m = d sin   d  r1r1 r2r2 D

29 Young Double Slit Experiment To determine the distance y between the central and first maximum, we will again assume that D is very large compared to y or d. From the diagram, we see that tan  = y/D However, for small angles of , tan = sin Therefore, we can substitute y/D for sin and get:  d  r1r1 r2r2 D y

30 Young Double Slit Experiment What are the implications of the formula? As wavelength () and distance (D) to the screen increases, the distance between maximums increases. As the distance between slits (d) increases, the distance between maximums decreases.

31 Key Ideas Transverse waves such as electro-magnetic radiation do not require a medium. Light Waves travel at different speeds in different mediums. It slows down when going from air to a liquid or solid. Waves can interfere with one another resulting in constructive or destructive interference. The law of reflection states that angle of incident wave equals the angle of the reflected wave.

32 Key Ideas Snell’s Law / Law of Refraction: A wave will bend toward the normal when transitioning from a media with a low index of refraction (e.g. air) to a media with a higher index of refraction. Total internal reflection occurs when the angle of incidence is greater than the critical angle. Consequently, no light will escape. Diffraction is the spreading out of a wave when it encounters a barrier. Thomas Young’s double slit experiment showed that light has wave properties similar to water and sound.


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