Total Internal Refraction PDF

12.5 Total Internal Reflection When light travels from one medium into another, some of the light is reflected and some is refracted. As you know, light slows down...

12.5 Total Internal Reflection When light travels from one medium into another, some of the light is reflected and some is refracted. As you know, light slows down when it travels from air into acrylic or water. This results in the light bending toward the normal. Light, however, bends away from the normal when it speeds up at the boundary of two media. (An example of this is when light travels from acrylic into air.) In this situation, the angle of refraction is always larger than the angle of incidence (Figure 1). In fact, the angle of refraction continues to increase as the angle of incidence increases. Eventually, the angle of refraction will become 90°. critical angle the angle of incidence that The angle of incidence at this point is called the critical angle. The critical angle results in an angle of refraction of 90° is the angle of incidence that produces a refracted angle of 90°. n1 > n2 air n2 = 1.00 water n1 = 1.33 Figure 1 Medium 1 (water) has an index of refraction that is greater than that of medium 2 (air). So an incident ray in water speeds up as it goes into air. If you increase the angle of incidence past the critical angle, the refracted ray will no longer exit the medium. Instead, it will reflect back into the medium. In other words, the refracted ray disappears; only a reflected ray is total internal reﬂection the situation visible. This phenomenon is called total internal reflection (Figure 2). when the angle of incidence is greater than the critical angle LEARNING TIP Understanding Diagrams It is often easier to understand a concept from a diagram than from words. Total internal reﬂection is a perfect example of this. After looking at Figure 2, draw your own diagrams to illustrate total internal reﬂection. Show your diagrams to a classmate and explain them. Figure 2 Total internal reﬂection of laser light in water 526 Chapter 12 The Refraction of Light NEL Total internal reflection occurs when these two conditions are met: 1. Light is travelling more slowly in the first medium than in the second. 2. The angle of incidence is large enough that no refraction occurs in To see some interesting simulations the second medium. Instead, the ray is reflected back into the first for total internal reﬂection, medium (Figure 3). GO TO NELSON SCIENCE air Ray 1 air Ray 2 air Ray 3 water water water critical angle (a) (b) (c) Figure 3 Ray 1 is refracted as it passes from water into air. Ray 2 has an angle of refraction of 90°; the angle of incidence is equal to the critical angle. Ray 3 is reﬂected internally back into water and does not go into air. Note that in (a) and (b), some light is reﬂected internally but not as strongly as in (c). Water has a critical angle of 48.8°. This means that an angle of incidence greater than 48.8° would result in total internal reflection in the water. The critical angle is a physical property of a medium. (Recall that the index of refraction is another physical property.) Diamonds Are Forever One of the features that make diamonds so attractive in jewellery is the fact that they sparkle. This “sparkling” is due to the cut of the diamond faces, which, combined with the high index of refraction for diamond (n  2.42), results in the total internal reflection of light. The high refractive index means that diamonds have a very small critical angle: 24.4°. So a great deal of incident light undergoes total internal reflection inside the diamond. A light To learn more about how ray can bounce around several times inside the diamond before eventually jewellers and gem cutters use exiting through a top face of the gemstone (Figure 4(a)). This causes the optics in their work, “sparkling” eﬀect that makes diamonds so appealing (Figure 4(b)). GO TO NELSON SCIENCE READING TIP Evaluating Examine illustrations and captions carefully to determine how they increase your understanding of a text. Make connections to what you already know about the topic. For example, you might have seen pictures of diamonds that (a) (b) appear to support the explanation for Figure 4 (a) Many light rays undergo two total internal reﬂections inside a diamond. why diamonds sparkle. (b) This is what makes a diamond “sparkle.” NEL 12.5 Total Internal Reﬂection 527 Fibre Optics Fibre optics is a technology that uses light to transmit information along a glass cable. The light must not escape as it travels along the cable. To achieve this, the cable must have a small critical angle so that light entering it will have an angle of incidence greater than the critical angle. Substances that have a small critical angle include high-purity glass and special types of plastics, such as Lucite (Figure 5). (a) (b) Figure 5 (a) A laser beam undergoes total internal reﬂection in a Lucite rod. (b) In close-up, you can see the point at which total internal reﬂection occurs. READING TIP Fibre optics is used extensively in the communications industry for Evaluating phones, computers, and TVs. Fibre optics also plays a major role in the Check a text for clues of bias. Are movie industry. Science fiction films sometimes make use of fibre-optic advantages and disadvantages cables to represent small windows in “giant” spaceships (Figure 6). The described? If only advantages are given, automotive industry uses optical fibres to transmit light to the instrument can you think of any disadvantages? For example, in a text about the applications panel in cars. As you learned in Chapter 2, medical professionals use fibre- of ﬁbre optics, does the author treat the optic technologies to see into parts of the human body that would otherwise topic in a balanced way? Are both pros be inaccessible. An endoscope is a fibre-optic device that allows doctors and cons described? If not, does the to check the health of various internal organs (Figure 7). The endoscope text show a bias toward one side of the consists of two separate fibre-optic bundles. One bundle shines light into the issue? body. The second bundle carries the reflected light back to the instrument. To learn more about careers in A colonoscopy, for example, is now a very common procedure among males ﬁbre optics, over 50 years of age. In this procedure, doctors use an endoscope to check GO TO NELSON SCIENCE for growths that could develop into colon cancer. Figure 6 Light travels along optical ﬁbres and Figure 7 An endoscope is an important ﬁbre- then emerges at the ends. optic device used for medical diagnoses. 528 Chapter 12 The Refraction of Light NEL The Triangular Prism A triangular prism also exhibits total internal reflection. The critical angle for glass is about 41.1°. If a prism is oriented in such a way that the angle of incidence is greater than 41.1°, total internal reflection will result. Prisms are much more useful to reflect light than mirrors because a prism reflects almost 100 % of the light internally. Mirrors reflect most incident light but lose a little through absorption. Also, the silvered surface of mirrors deteriorates over time. For these reasons, most optical devices, such as cameras and binoculars, use prisms instead of mirrors. The emergent ray can be either 90° or 180° relative to the incident ray, depending on the placement of the prism (Figure 8). 45° 45° 45° 45° 45° 45° (a) (b) Figure 8 By changing the orientation of the prism, you can change the direction of the emergent ray by either 90° or 180°. In (a) the light ray goes through just one reﬂection. In (b) it goes through two reﬂections. In Chapter 11, you learned that plane mirrors could be used to make a simple periscope. A more complex periscope uses triangular prisms to change the direction of light by 90° (Figure 9). Each triangular face has angles of 45°, 45°, and 90°. A pair of binoculars uses two such prisms to change the direction of light by 180° (Figure 10). triangular prisms prisms Figure 9 A periscope uses triangular prisms to Figure 10 Binoculars use two triangular prisms change the direction of light by 90° twice. to change the path of light. NEL 12.5 Total Internal Reﬂection 529 Retro-reﬂectors and Prisms retro-reﬂector an optical device in which A retro-reflector is an optical device that returns any incident light back the emergent ray is parallel to the incident in exactly the same direction from which it came. The prism orientation in ray Figure 8(b) on the previous page is an example of a retro-reflector because the emergent ray is parallel to the incident ray as a result of two total internal reflections. If you cut oﬀ the corner of a glass cube, you would produce a corner cube retro-reflector. This type of retro-reflector has three perpendicular faces (like the corner of a room) (Figure 11). It will reflect an incident ray coming from any direction back along its original direction. Figure 11 (a) and (b) A corner cube retro-reﬂector is created by cutting off the corner of a cube. (c) The resulting corner cube retro-reﬂector after three corners have been ground down. (a) (b) (c) (a) (b) (c) The Laser Ranging Retro-Reflector (LR³ or “LR-cubed”) left on the Moon by the Apollo 11 astronauts is an example of this type of retro-reflector. The LR³ is an array of 100 corner cube retro-reflectors set up in a 10 × 10 grid mounted on a square aluminum panel that is 46 cm long, about the size of a large pizza box. These 100 corner-cubed prisms on the Moon are made of quartz. With this device, scientists on Earth have been able to shine a very powerful laser beam at the Moon and bounce it oﬀ the LR³. This enabled scientists to determine the Earth–Moon distance with an accuracy of 3 cm. The LR³ is still working, and recent laser measurements have refined the C12-F31-UDOS10SB.ai Earth–Moon distance even further, down to within a few millimetres. You may not have heard of retro-reflectors before, but you have almost To learn more about the LR³ on the Moon and retro-reﬂectors certainly seen them. They are built into bike reflectors and the reflective in general, strips on clothing and helmets. Road signs also contain tiny retro-reflectors GO TO NELSON SCIENCE in the paint so that you can see the signs at night (Figure 12). Ontario Science 10 SB 0-17-635528-6 FN C12-F31-UDOS10SB CO CrowleArt Group Deborah Crowle Pass 3rd pass Approved Not Approved Figure 12 Retro-reflectors on road signs help you see the signs at night. 530 Chapter 12 The Refraction of Light NEL UNIT TASK Bookmark You can apply what you learned about total internal reﬂection as you plan what optical device you will construct for the Unit Task described on page 588. IN SUMMARY The critical angle is the angle of incidence for Optical devices such as periscopes, binoculars, which the angle of refraction is 90°. This occurs and fibre-optic cables make use of total internal only when light passes from one medium into reflection. another with a lower index of refraction. A triangular prism, depending on its orientation, can Total internal reﬂection occurs if the angle of change the direction of light by 90° (one total internal incidence is greater that the critical angle. reflection) or 180° (two total internal reflections). CHECK YOUR LEARNING 1. What two conditions must be satisﬁed in order for total internal reﬂection to occur? K/U 2. Why does total internal reﬂection occur only when light medium A medium travels more slowly through the ﬁrst medium than in medium A A the second and not the other way around? Include a ray diagram with your answer. T/I mediumBB medium medium B 3. The critical angle for sapphire is 34.4°. For each angle of incidence, determine if it would result in total internal reﬂection in a sapphire. K/U (a) (a) 23.7° (b) 34.7° (c) 53.4° (d) 31.5° 4. What is the advantage of using triangular prisms over plane mirrors in optical devices requiring the reﬂection of light? K/U A medium A medium 5. Will you get more total internal reﬂection with a medium medium A A that has a small critical angle or with one that has a large critical angle? Explain. K/U mediumBB medium medium B 6. Brainstorm to create a list of suggestions for using retro-reﬂectors to improve road safety on a winding, dark, country road. A (b) 7. Brieﬂy describe three applications that make use of the total internal reﬂection of light. A 8. Figure 13 shows light travelling through two different media. In which diagrams would total internal reﬂection be possible if the angle of incidence were increased? T/I medium A medium medium A A 9. Look again at Figure 13. For each diagram, in which medium would total internal reﬂection occur? Explain your answers. T/I medium B medium medium B B (c) Figure 13 NEL 12.5 Total Internal Reﬂection 531

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