College Physics (10th Edition)
10th Edition
ISBN: 9780321902788
Author: Hugh D. Young, Philip W. Adams, Raymond Joseph Chastain
Publisher: PEARSON
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Question
Chapter 24, Problem 52GP
To determine
The apparent distance from the upper benzene surface to the bottom when it is viewed at normal incidence.
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College Physics (10th Edition)
Ch. 24 - If a spherical mirror is immersed in water, does...Ch. 24 - For what range of object positions does a concave...Ch. 24 - If a screen is placed at the location of a real...Ch. 24 - Is it possible to view a virtual image directly...Ch. 24 - Prob. 5CQCh. 24 - On a sunny day, you can use the suns rays and a...Ch. 24 - A person looks at her reflection in the concave...Ch. 24 - What happens to the image produced by a converging...Ch. 24 - Without measuring its radius of curvature (which...Ch. 24 - Without measuring its radii of curvature (which is...
Ch. 24 - A spherical air bubble in water can function as a...Ch. 24 - Optical telescopes having a principal mirror only...Ch. 24 - A ray from an object passes through a thin lens,...Ch. 24 - If a single lens forms a real image, we can...Ch. 24 - If a single lens forms a virtual image, we can...Ch. 24 - An object lies outside the focal port of a...Ch. 24 - An object lies outside the focal point of a...Ch. 24 - Prob. 6MCPCh. 24 - An object is placed a distance 2f away from a...Ch. 24 - In order to form an image with a converging lens...Ch. 24 - A ray from an object passes through a thin lens,...Ch. 24 - As you move an object from just outside to just...Ch. 24 - As you move an object from just outside to just...Ch. 24 - You have a shiny salad bowl with a spherical shape...Ch. 24 - A candle 4.85 cm tall is 39.2 cm to the left of a...Ch. 24 - Two plane mirrors form a 60 wedge as shown in...Ch. 24 - An object is placed between two plane mirrors...Ch. 24 - If you run away from a plane mirror at 2.40 m/s,...Ch. 24 - A concave spherical mirror has a radius of...Ch. 24 - A concave spherical mirror has a radius of...Ch. 24 - The diameter of Mars is 6794 km. and its minimum...Ch. 24 - A concave mirror has a radius of curvature of 34.0...Ch. 24 - Rearview mirror. A mirror on the passenger side of...Ch. 24 - Examining your image in a convex mirror whose...Ch. 24 - A coin is placed next to the convex side of a thin...Ch. 24 - Consider a concave mirror that has a focal length...Ch. 24 - A spherical, concave shaving mirror has a radius...Ch. 24 - An object 0.600 cm tall is placed 16.5 cm to the...Ch. 24 - Repeat the previous problem for the case in which...Ch. 24 - The thin glass shell shown in Figure 24.43 has a...Ch. 24 - Dental mirror. A dentist uses a curved mirror to...Ch. 24 - The left end of a long glass rod 6.00 cm in...Ch. 24 - Prob. 19PCh. 24 - The left end of a long glass rod 8.00 cm in...Ch. 24 - A large aquarium has portholes of thin transparent...Ch. 24 - Focus of the eye. The cornea of the eye has a...Ch. 24 - A speck of dirt is embedded 3.50 cm below the...Ch. 24 - A skin diver is 2.0 m below the surface of a lake....Ch. 24 - A person is swimming 1.0 m beneath the surface of...Ch. 24 - A converging lens with a focal length of 7.00 cm...Ch. 24 - A converging lens with a focal length of 90.0 cm...Ch. 24 - You are standing 0.50 m in front of a lens that...Ch. 24 - Figure 24.44 shows an object and its image formed...Ch. 24 - Set up: 1s+1s=1f. The type of lens determines the...Ch. 24 - Figure 24.46 shows an object and its image formed...Ch. 24 - The two surfaces of a plastic converging lens have...Ch. 24 - A lens has an index of refraction of 1.7 and a...Ch. 24 - Set Up: Use 1f=(n1)(1R11R2) to calculate f and...Ch. 24 - The lens of the eye. The crystalline lens of the...Ch. 24 - The cornea as a simple lens. The cornea behaves as...Ch. 24 - An insect 3.75 mm tall is placed 22.5 cm to the...Ch. 24 - Two double-convex thin lenses each have surfaces...Ch. 24 - A converging meniscus lens (see Figure 24.30) with...Ch. 24 - A converging lens with a focal length of 12.0 cm...Ch. 24 - Combination of lenses, I. When two lenses are used...Ch. 24 - Set Up: Apply 1s+1s=1f with f = 35.0 cm. We know...Ch. 24 - Combination of lenses, II. Two thin lenses with a...Ch. 24 - A lens forms a real image that is 214 cm away from...Ch. 24 - A converging lens has a focal length of 14.0 cm...Ch. 24 - A converging lens forms an image of an...Ch. 24 - A diverging lens with a focal length of 48.0 cm...Ch. 24 - When an object is 16.0 cm from a lens, an image is...Ch. 24 - Figure 24.48 shows a small plant near a thin lens....Ch. 24 - Figure 24.49 shows a small plant near a thin lens....Ch. 24 - Figure 24.50 shows a small plant near a thin lens....Ch. 24 - Prob. 52GPCh. 24 - Where must you place an object in front of a...Ch. 24 - Set Up: Use 1s+1s=1f. A plot of 1f versus 1s...Ch. 24 - A concave mirror is to form an image of the...Ch. 24 - A lens has one convex surface of radius 6.00 cm...Ch. 24 - A 3 80-nm-tall object 24.0 cm from the center of...Ch. 24 - A lensmaker wants to make a magnifying glass from...Ch. 24 - An object is placed 18.0 cm from a screen, (a) At...Ch. 24 - In the text, Equations 24.4 and 24.7 were derived...Ch. 24 - A lens in a liquid. A lens obeys Snell s law,...Ch. 24 - Refraction of liquids. The focal length of a...Ch. 24 - Refraction of liquids. The focal length of a...Ch. 24 - If you place a concave mirror with a focal length...Ch. 24 - Refraction of liquids. The focal length of a...
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- Figure P38.43 shows a concave meniscus lens. If |r1| = 8.50 cm and |r2| = 6.50 cm, find the focal length and determine whether the lens is converging or diverging. The lens is made of glass with index of refraction n = 1.55. CHECK and THINK: How do your answers change if the object is placed on the right side of the lens? FIGURE P38.43arrow_forwardA person looking into an empty container is able to see the far edge of the containers bottom, as shown in Figure P22.23a. The height of the container is h, and its width is d. When the container is completely filled with a fluid of index of refraction n and viewed from the same angle, the person can see the center of a coin at the middle of the containers bottom, as shown in Figure P22.23b. (a) Show that the ratio h/d is given by hd=n214n2 (b) Assuming the container has a width of 8.00 cm and is filled with water, use the expression above to find the height of the container.arrow_forwardHow many times will the incident beam in Figure P34.33 (page 922) be reflected by each of the parallel mirrors? Figure P34.33arrow_forward
- Consider a beam of light from the left entering a prism of apex angle as shown in Figure P34.34. Two angles of incidence, 1, and 3, are shown as Hell as two angles of refraction, 2 and 4. Show that = 1 + 3. Figure P34.34arrow_forwardFigure P23.28 shows a curved surface separating a material with index of refraction n1 from a material with index n2. The surface forms an image I of object O. The ray shown in red passes through the surface along a radial line. Its angles of incidence and refraction are both zero, so its direction does not change at the surface. For the ray shown in blue, the direction changes according to n1 sin 1 = n2 sin 2. For paraxial rays, we assume 1 and 2 are small, so we may write n1 tan 1 n2 tan 2. The magnification is defined as M = h/h. Prove that the magnification is given by M = n1q/n2p. Figure P23.28arrow_forwardA ray of light strikes a flat, 2.00-cm-thick block of glass (n = 1.50) at ail angle of 30.0 with respect to the normal (Fig. P22.18). (a) Find the angle of refraction at the lop surface. (b) Find the angle of incidence at the bottom surface and the refracted angle. (c) Find the lateral distance d by which the light beam is shifted. (d) Calculate the speed of light in the glass and (e) the time required for the light to pass through the glass block. (f) Is the travel time through the block affected by the angle of incidence? Explain.arrow_forward
- Figure P23.28 shows a curved surface separating a material with index of refraction n1 from a material with index n2. The surface forms an image I of object O. The ray shown in red passes through the surface along a radial line. Its angles of incidence and refraction are both zero, so its direction does not change at the surface. For the ray shown in blue, the direction changes according to n1 sin 1 = n2 sin 2. For paraxial rays, we assume 1 and 2 are small, so we may write n1 tan 1 n2 tan 2. The magnification is defined as M = h/h. Prove that the magnification is given by M = n1q/n2p. Figure P23.28arrow_forward(a) Using information in Figure 25.53, find the height of the instructor's head above the water, noting that you will first have to calculate the angle of incidence. (b) Find the apparent depth of the diver’s head below water as seen by the instructor.arrow_forwardTwo rays travelling parallel to the principal axis strike a large plano-convex lens having a refractive index of 1.60 (Fig. P23.54). If the convex face is spherical, a ray near the edge does not pass through the local point (spherical aberration occurs). Assume this face has a radius of curvature of R = 20.0 cm and the two rays are at distances h1 = 0.500 cm and h2 = 12.0 cm from the principal axis. Find the difference x in the position where each crosses the principal axis. Figure P23.54arrow_forward
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Laws of Refraction of Light | Don't Memorise; Author: Don't Memorise;https://www.youtube.com/watch?v=4l2thi5_84o;License: Standard YouTube License, CC-BY