Single-Slit Diffraction As the width of the slit producing a single-slit diffraction pattern is reduced, how will the diffraction pattern produced change?
Read more- Physics / University Physics, Volume 3 17 / Chapter 4 / Problem 18
Textbook Solutions for University Physics, Volume 3
Question
Single-Slit Diffraction
(a) Calculate the angle at which a \(2.00-\mu \mathrm{m}\)-wide slit produces its first minimum for 410-nm violet light. (b) Where is the first minimum for 700-nm red light?
Text Transcription:
2.00 mu m
Solution
The first step in solving 4 problem number trying to solve the problem we have to refer to the textbook question: Single-Slit Diffraction(a) Calculate the angle at which a \(2.00-\mu \mathrm{m}\)-wide slit produces its first minimum for 410-nm violet light. (b) Where is the first minimum for 700-nm red light?Text Transcription:2.00 mu m
From the textbook chapter Diffraction you will find a few key concepts needed to solve this.
Visible to paid subscribers only
Step 3 of 7)Visible to paid subscribers only
full solution
?Single-Slit Diffraction(a) Calculate the angle at which a \(2.00-\mu \mathrm{m}\)-wide
Chapter 4 textbook questions
-
Chapter 4: Problem 1 University Physics, Volume 3 17 -
Chapter 4: Problem 2 University Physics, Volume 3 17Single-Slit Diffraction Compare interference and diffraction.
Read more -
Chapter 4: Problem 3 University Physics, Volume 3 17Single-Slit Diffraction If you and a friend are on opposite sides of a hill, you can communicate with walkie-talkies but not with flashlights. Explain.
Read more -
Chapter 4: Problem 4 University Physics, Volume 3 17Single-Slit Diffraction What happens to the diffraction pattern of a single slit when the entire optical apparatus is immersed in water?
Read more -
Chapter 4: Problem 5 University Physics, Volume 3 17Single-Slit Diffraction In our study of diffraction by a single slit, we assume that the length of the slit is much larger than the width. What happens to the diffraction pattern if these two dimensions were comparable?
Read more -
Chapter 4: Problem 6 University Physics, Volume 3 17Single-Slit Diffraction A rectangular slit is twice as wide as it is high. Is the central diffraction peak wider in the vertical direction or in the horizontal direction?
Read more -
Chapter 4: Problem 7 University Physics, Volume 3 17Intensity in Single-Slit Diffraction In Equation 4.4, the parameter \(\beta\) looks like an angle but is not an angle that you can measure with a protractor in the physical world. Explain what \(\beta\) represents. Text Transcription: beta
Read more -
Chapter 4: Problem 17 University Physics, Volume 3 17Single-Slit Diffraction (a) At what angle is the first minimum for 550-nm light falling on a single slit of width \(1.00 \mu \mathrm{m}\)? (b) Will there be a second minimum? Text Transcription: 1.00 mu m
Read more -
Chapter 4: Problem 18 University Physics, Volume 3 17Single-Slit Diffraction (a) Calculate the angle at which a \(2.00-\mu \mathrm{m}\)-wide slit produces its first minimum for 410-nm violet light. (b) Where is the first minimum for 700-nm red light? Text Transcription: 2.00 mu m
Read more -
Chapter 4: Problem 19 University Physics, Volume 3 17Single-Slit Diffraction (a) How wide is a single slit that produces its first minimum for 633-nm light at an angle of \(28.0^{\circ}\) (b) At what angle will the second minimum be? Text Transcription: 28.0 degrees
Read more -
Chapter 4: Problem 20 University Physics, Volume 3 17Single-Slit Diffraction (a) What is the width of a single slit that produces its first minimum at \(60.0^{\circ}\) for 600-nm light? (b) Find the wavelength of light that has its first minimum at \(62.0^{\circ}\). Text Transcription: 60.0 degrees 62.0 degrees
Read more -
Chapter 4: Problem 21 University Physics, Volume 3 17Single-Slit Diffraction Find the wavelength of light that has its third minimum at an angle of \(48.6^{\circ}\) when it falls on a single slit of width \(3.00 \mu m\). Text Transcription: 48.6 degrees 3.00 mu m
Read more -
Chapter 4: Problem 22 University Physics, Volume 3 17Single-Slit Diffraction (a) Sodium vapor light averaging 589 nm in wavelength falls on a single slit of width \(7.50 \mu m\). At what angle does it produces its second minimum? (b) What is the highest-order minimum produced? Text Transcription: 7.50 mu m
Read more -
Chapter 4: Problem 23 University Physics, Volume 3 17Single-Slit Diffraction Consider a single-slit diffraction pattern for \(\lambda = 589 nm\), projected on a screen that is 1.00 m from a slit of width 0.25 mm. How far from the center of the pattern are the centers of the first and second dark fringes? Text Transcription: lambda 589 nm
Read more -
Chapter 4: Problem 24 University Physics, Volume 3 17Single-Slit Diffraction (a) Find the angle between the first minima for the two sodium vapor lines, which have wavelengths of 589.1 and 589.6 nm, when they fall upon a single slit of width \(2.00 \mu \mathrm{m}\). (b) What is the distance between these minima if the diffraction pattern falls on a screen 1.00 m from the slit? (c) Discuss the ease or difficulty of measuring sucha distance. Text Transcription: 2.00 mu m
Read more -
Chapter 4: Problem 25 University Physics, Volume 3 17Single-Slit Diffraction (a) What is the minimum width of a single slit (in multiples of \(\lambda\)) that will produce a first minimum for a wavelength \(\lambda\)? (b) What is its minimum width if it produces 50 minima? (c) 1000 minima? Text Transcription: lambda
Read more -
Chapter 4: Problem 26 University Physics, Volume 3 17Single-Slit Diffraction (a) If a single slit produces a first minimum at \(14.5^{\circ}\), at what angle is the second-order minimum? (b) What is the angle of the third- order minimum? (c) Is there a fourth-order minimum? (d) Use your answers to illustrate how the angular width of the central maximum is about twice the angular width of the next maximum (which is the angle between the first and second minima). Text Transcription: 14.5 degrees
Read more -
Chapter 4: Problem 27 University Physics, Volume 3 17Single-Slit Diffraction If the separation between the first and the second minima of a single-slit diffraction pattern is 6.0 mm, what is the distance between the screen and the slit? The light wavelength is 500 nm and the slit width is 0.16 mm.
Read more -
Chapter 4: Problem 28 University Physics, Volume 3 17Single-Slit Diffraction A water break at the entrance to a harbor consists of a rock barrier with a 50.0-m-wide opening. Ocean waves of 20.0-m wavelength approach the opening straight on. At what angles to the incident direction are the boats inside the harbor most protected against wave action?
Read more -
Chapter 4: Problem 29 University Physics, Volume 3 17Single-Slit Diffraction An aircraft maintenance technician walks past a tall hangar door that acts like a single slit for sound entering the hangar. Outside the door, on a line perpendicular to the opening in the door, a jet engine makes a 600-Hz sound. At what angle with the door will the technician observe the first minimum in sound intensity if the vertical opening is 0.800 m wide and the speed of sound is 340 m/s?
Read more -
Chapter 4: Problem 30 University Physics, Volume 3 17Intensity in Single-Slit Diffraction A single slit of width \(3.0 \mu \mathrm{m}\) is illuminated by a sodium yellow light of wavelength 589 nm. Find the intensity at a \(15^{\circ}\) angle to the axis in terms of the intensity of the central maximum. Text Transcription: 3.0 mu m 15 degrees
Read more -
Chapter 4: Problem 31 University Physics, Volume 3 17Intensity in Single-Slit Diffraction A single slit of width 0.1 mm is illuminated by a mercury light of wavelength 576 nm. Find the intensity at a \(10^{\circ}\) angle to the axis in terms of the intensity of the central maximum. Text Transcription: 10 degrees
Read more -
Chapter 4: Problem 32 University Physics, Volume 3 17Intensity in Single-Slit Diffraction The width of the central peak in a single-slit diffraction pattern is 5.0 mm. The wavelength of the light is 600 nm, and the screen is 2.0 m from the slit. (a) What is the width of the slit? (b) Determine the ratio of the intensity at 4.5 mm from the center of the pattern to the intensity at the center.
Read more -
Chapter 4: Problem 33 University Physics, Volume 3 17Intensity in Single-Slit Diffraction Consider the single-slit diffraction pattern for \(\lambda=600 \mathrm{~nm}, a=0.025 \mathrm{~mm}, \text { and } x=2.0 \mathrm{~m}\). Find the intensity in terms of \(I_{o} \text { at } \theta=0.5^{\circ}, 1.0, 1.5^{\circ}, 3.0^{\circ}, \text { and } 10.0^{\circ}\). Text Transcription: lambda=600 nm, a=0.025 mm, and x=2.0m. I_0 at theta=0.5 degree, 1.0 degree, 1.5 degree, 3.0 degree, and 10.0 degree
Read more -
Chapter 4: Problem 35 University Physics, Volume 3 17Double-Slit Diffraction A double slit produces a diffraction pattern that is a combination of single- and double-slit interference. Find the ratio of the width of the slits to the separation between them, if the first minimum of the single-slit pattern falls on the fifth maximum of the double-slit pattern. (This will greatly reduce the intensity of the fifth maximum.)
Read more -
Chapter 4: Problem 36 University Physics, Volume 3 17Double-Slit Diffraction For a double-slit configuration where the slit separation is four times the slit width, how many interference fringes lie in the central peak of the diffraction pattern?
Read more -
Chapter 4: Problem 41 University Physics, Volume 3 17Diffraction Gratings A diffraction grating has 2000 lines per centimeter. At what angle will the first-order maximum be for 520-nm-wavelength green light?
Read more -
Chapter 4: Problem 42 University Physics, Volume 3 17Diffraction Gratings Find the angle for the third-order maximum for 580-nm-wavelength yellow light falling on a difraction grating having 1500 lines per centimeter.
Read more -
Chapter 4: Problem 43 University Physics, Volume 3 17Diffraction Gratings How many lines per centimeter are there on a diffraction grating that gives a first-order maximum for 470-nm blue light at an angle of \(25.0^{\circ}\)? Text Transcription: 25.0 degrees
Read more -
Chapter 4: Problem 47 University Physics, Volume 3 17Diffraction Gratings (a) What do the four angles in the preceding problem become if a 5000-line per centimeter diffraction grating is used? (b) Using this grating, what would the angles be for the second-order maxima? (c) Discuss the relationship between integral reductions in lines per centimeter and the new angles of various order maxima.
Read more -
Chapter 4: Problem 80 University Physics, Volume 3 17Microwaves of wavelength 10.0 mm fall normally on a metal plate that contains a slit 25 mm wide. (a) Where are the first minima of the diffraction pattern? (b) Would there be minima if the wavelength were 30.0 mm?
Read more -
Chapter 4: Problem 81 University Physics, Volume 3 17Quasars, or quasi-stellar radio sources, are astronomical objects discovered in 1960. They are distant but strong emitters of radio waves with angular size so small, they were originally unresolved, the same as stars. The quasar 3C405 is actually two discrete radio sources that subtend an angle of 82 arcsec. If this object is studied using radio emissions at a frequency of 410 MHz, what is the minimum diameter of a radio telescope that can resolve the two sources?
Read more -
Chapter 4: Problem 82 University Physics, Volume 3 17Two slits each of width 1800 nm and separated by the center-to-center distance of 1200 nm are illuminated by plane waves from a krypton ion laser-emitting at wavelength 461.9 nm. Find the number of interference peaks in the central diffraction peak.
Read more -
Chapter 4: Problem 83 University Physics, Volume 3 17A microwave of an unknown wavelength is incident on a single slit of width 6 cm. The angular width of the central peak is found to be \(25^{\circ}\). Find the wavelength. Text Transcription: 25 degrees
Read more -
Chapter 4: Problem 84 University Physics, Volume 3 17Red light (wavelength 632.8 nm in air) from a Helium-Neon laser is incident on a single slit of width 0.05 mm. The entire apparatus is immersed in water of refractive index 1.333. Determine the angular width of the central peak.
Read more -
Chapter 4: Problem 85 University Physics, Volume 3 17A light ray of wavelength 461.9 nm emerges from a 2-mm circular aperture of a krypton ion laser. Due to diffraction, the beam expands as it moves out. How large is the central bright spot at (a) 1 m, (b) 1 km, (c) 1000 km, and (d) at the surface of the moon at a distance of 400,000 km from Earth.
Read more -
Chapter 4: Problem 86 University Physics, Volume 3 17How far apart must two objects be on the moon to be distinguishable by eye if only the diffraction effects of the eye’s pupil limit the resolution? Assume 550 nm for the wavelength of light, the pupil diameter 5.0 mm, and 400,000 km for the distance to the moon.
Read more -
Chapter 4: Problem 87 University Physics, Volume 3 17How far apart must two objects be on the moon to be resolvable by the 8.1-m-diameter Gemini North telescope at Mauna Kea, Hawaii, if only the diffraction effects of the telescope aperture limit the resolution? Assume 550 nm for the wavelength of light and 400,000 km for the distance to the moon.
Read more -
Chapter 4: Problem 88 University Physics, Volume 3 17A spy satellite is reputed to be able to resolve objects 10. cm apart while operating 197 km above the surface of Earth. What is the diameter of the aperture of the telescope if the resolution is only limited by the diffraction effects? Use 550 nm for light.
Read more -
Chapter 4: Problem 92 University Physics, Volume 3 17A single slit of width 2100 nm is illuminated normally by a wave of wavelength 632.8 nm. Find the phase difference between waves from the top and one third from the bottom of the slit to a point on a screen at a horizontal distance of 2.0 m and vertical distance of 10.0 cm from the center.
Read more -
Chapter 4: Problem 95 University Physics, Volume 3 17A diffraction grating produces a second maximum that is 89.7 cm from the central maximum on a screen 2.0 m away. If the grating has 600 lines per centimeter, what is the wavelength of the light that produces the diffraction pattern?
Read more -
Chapter 4: Problem 96 University Physics, Volume 3 17A grating with 4000 lines per centimeter is used to diffract light that contains all wavelengths between 400 and 650 nm. How wide is the firstorder spectrum on a screen 3.0 m from the grating?
Read more -
Chapter 4: Problem 118 University Physics, Volume 3 17Blue light of wavelength 450 nm falls on a slit of width 0.25 mm. A converging lens of focal length 20 cm is placed behind the slit and focuses the diffraction pattern on a screen. (a) How far is the screen from the lens? (b) What is the distance between the first and the third minima of the diffraction pattern?
Read more -
Chapter 4: Problem 119 University Physics, Volume 3 17(a) Assume that the maxima are halfway between the minima of a single-slit diffraction pattern. The use the diameter and circumference of the phasor diagram, as described in Intensity in Single-Slit Diffraction , to determine the intensities of the third and fourth maxima in terms of the intensity of the central maximum. (b) Do the same calculation, using Equation 4.4 .
Read more -
Chapter 4: Problem 121 University Physics, Volume 3 17What is the maximum number of lines per centimeter a diffraction grating can have and produce a complete first-order spectrum for visible light?
Read more -
Chapter 4: Problem 34 University Physics, Volume 3 17Intensity in Single-Slit Diffraction Two slits of width \(2 \mu \mathrm{m}\), and at . Find , , each in an opaque material, are separated by a center-to-center distance of \(6 \mu \mathrm{m}\). A monochromatic light of wavelength 450 nm is incident on the double slit. One finds a combined interference and diffraction pattern on the screen. (a) How many peaks of the interference will be observed in the central maximum of the diffraction pattern? (b) How many peaks of the interference will be observed if the slit width is doubled while keeping the distance between the slits same? (c) How many peaks of interference will be observed if the slits are separated by twice the distance, that is \(12 \mu \mathrm{m}\),while keeping the widths of the slits same? (d) What will happen in (a) if instead of 450-nm light another light of wavelength 680 nm is used? (e) What is the value of the ratio of the intensity of the central peak to the intensity of the next bright peak in (a)? (f) Does this ratio depend on the wavelength of the light? (g) Does this ratio depend on the width or separation of the slits? Text Transcription: 2 mu m 6 mu m 12 mu m
Read more -
Chapter 4: Problem 37 University Physics, Volume 3 17Intensity in Single-Slit Diffraction Light of wavelength 500 nm falls normally on 50 slits that are \(2.5 \times 10^{-3} \mathrm{~mm}\) wide and spaced \(5.0 \times 10^{-3} \mathrm{~mm}\) apart. How many interference fringes lie in the central peak of the diffraction pattern? Text Transcription: 2.5 times !0^-3 mm 5.0 times !0^-3 mm
Read more -
Chapter 4: Problem 38 University Physics, Volume 3 17Intensity in Single-Slit Diffraction A monochromatic light of wavelength 589 nm incident on a double slit with slit width \(2.5 \mu \mathrm{m}\) and unknown separation results in a diffraction pattern containing nine interference peaks inside the central maximum. Find the separation of the slits. Text Transcription: 2.5 mu m
Read more -
Chapter 4: Problem 39 University Physics, Volume 3 17Intensity in Single-Slit Diffraction When a monochromatic light of wavelength 430 nm incident on a double slit of slit separation \(5 \mu \mathrm{m}\), there are 11 interference fringes in its central maximum. How many interference fringes will be in the central maximum of a light of the same wavelength and slit widths, but a new slit separation of \(4 \mu \mathrm{m}\)? Text Transcription: 5 mu m 4 mu m
Read more -
Chapter 4: Problem 40 University Physics, Volume 3 17Intensity in Single-Slit Diffraction Determine the intensities of two interference peaks other than the central peak in the central maximum of the diffraction, if possible, when a light of wavelength 628 nm is incident on a double slit of width 500 nm and separation 1500 nm. Use the intensity of the central spot to be \(1 \mathrm{~mW} / \mathrm{cm}^{2}\)? Text Transcription: 1 mW/cm^2
Read more -
Chapter 4: Problem 44 University Physics, Volume 3 17Diffraction Gratings What is the distance between lines on a diffraction grating that produces a second-order maximum for 760-nm red light at an angle of \(60.0^{\circ}\)? Text Transcription: 60.0 degrees
Read more -
Chapter 4: Problem 45 University Physics, Volume 3 17Diffraction Gratings Calculate the wavelength of light that has its second-order maximum at \(45.0^{\circ}\) when falling on a diffraction grating that has 5000 lines per centimeter. Text Transcription: 45.0 degrees
Read more -
Chapter 4: Problem 46 University Physics, Volume 3 17Diffraction Gratings An electric current through hydrogen gas produces several distinct wavelengths of visible light. What are the wavelengths of the hydrogen spectrum, if they form first-order maxima at angles \(24.2^{\circ}, 25.7^{\circ}, 29.1^{\circ}, \text { and } 41.0^{\circ}\) when projected on a diffraction grating having 10,000 lines per centimeter? Text Transcription: 24.2 degrees, 25.7 degrees, 29.1 degrees and 41.0 degrees
Read more -
Chapter 4: Problem 79 University Physics, Volume 3 17White light falls on two narrow slits separated by 0.40 mm. The interference pattern is observed on a screen 3.0 m away. (a) What is the separation between the first maxima for red light \((\lambda=700 \mathrm{~nm})\) and violet light \((\lambda=400 \mathrm{~nm})\) (b) At what point nearest the central maximum will a maximum for yellow light \((\lambda=600 \mathrm{~nm})\) coincide with a maximum for violet light? Identify the order for each maximum. Text Transcription: lambda=700 nm lambda=400 nm lambda=600 nm
Read more -
Chapter 4: Problem 89 University Physics, Volume 3 17Monochromatic light of wavelength 530 nm passes through a horizontal single slit of width \(1.5 \mu \mathrm{m}\) in an opaque plate. A screen of dimensions \(2.0 \mathrm{~m} \times 2.0 \mathrm{~m}\) is 1.2 m away from the slit. (a) Which way is the diffraction pattern spread out on the screen? (b) What are the angles of the minima with respect to the center? (c) What are the angles of the maxima? (d) How wide is the central bright fringe on the screen? (e) How wide is the next bright fringe on the screen? Text Transcription: 1.5 mu m 2.0 m times 2.0 m
Read more -
Chapter 4: Problem 90 University Physics, Volume 3 17A monochromatic light of unknown wavelength is incident on a slit of width \(20 \mu \mathrm{m}\) diffraction pattern is seen at a screen 2.5 m away where the central maximum is spread over a distance of 10.0 cm. Find the wavelength. Text Transcription: 20 mu m
Read more -
Chapter 4: Problem 91 University Physics, Volume 3 17A source of light having two wavelengths 550 nm and 600 nm of equal intensity is incident on a slit of width \(1.8 \mu \mathrm{m}\). Find the separation of the m = 1 bright spots of the two wavelengths on a screen 30.0 cm away. Text Transcription: 1.8 mu m
Read more -
Chapter 4: Problem 93 University Physics, Volume 3 17A single slit of width \(3.0 \mu \mathrm{m}\) is illuminated by a sodium yellow light of wavelength 589 nm. Find the intensity at a \(15^{\circ}\) angle to the axis in terms of the intensity of the central maximum. Text Transcription: 3.0 m m 15 degrees
Read more -
Chapter 4: Problem 94 University Physics, Volume 3 17A single slit of width 0.10 mm is illuminated by a mercury lamp of wavelength 576 nm. Find the intensity at a \(10^{\circ}\) angle to the axis in terms of the intensity of the central maximum. Text Transcription: 10 degrees
Read more -
Chapter 4: Problem 97 University Physics, Volume 3 17A diffraction grating with 2000 lines per centimeter is used to measure the wavelengths emitted by a hydrogen gas discharge tube. (a) At what angles will you find the maxima of the two first order blue lines of wavelengths 410 and 434 nm? (b) The maxima of two other first order lines are found at \(\theta_{1}=0.097 \mathrm{rad} \text { and } \theta_{2}=0.132 \mathrm{rad}\). What are the wavelengths of these lines? Text Transcription: theta_1=0.097 rad and theta_2=0.132 rad
Read more -
Chapter 4: Problem 98 University Physics, Volume 3 17For white light \((400 \mathrm{~nm}<\lambda<700 \mathrm{~nm})\) falling normally on a diffraction grating, show that the second and third-order spectra overlap no matter what the grating constant d is. Text Transcription: 400 nm < lambda < 700 nm
Read more -
Chapter 4: Problem 120 University Physics, Volume 3 17(a) By differentiating Equation 4.4 , show that the higher-order maxima of the single-slit diffraction pattern occur at values of \(\beta\) that satisfy \(\tan \beta=\beta\). (b) Plot \(y=\tan \beta \text { and } y=\beta\) versus \(\beta\) and find the intersections of these two curves. What information do they give you about the locations of the maxima? (c) Convince yourself that these points do not appear exactly at \(\beta=\left(n+\frac{1}{2}\right) \pi\) where n = 1, 2, 3, … , but are quite close to these values. Text Transcription: beta tan beta=beta y=tan beta and y=beta beta=(n+1/2) pi
Read more -
Chapter 4: Problem 8 University Physics, Volume 3 17Double-Slit Diffraction Shown below is the central part of the interference pattern for a pure wavelength of red light projected onto a double slit. The pattern is actually a combination of single- and double-slit interference. Note that the bright spots are evenly spaced. Is this a double- or single-slit characteristic? Note that some of the bright spots are dim on either side of the center. Is this a single- or double-slit characteristic? Which is smaller, the slit width or the separation between slits? Explain your responses. (credit: PASCO)
Read more -
Chapter 4: Problem 9 University Physics, Volume 3 17Circular Apertures and Resolution Is higher resolution obtained in a microscope with red or blue light? Explain your answer.
Read more -
Chapter 4: Problem 10 University Physics, Volume 3 17Circular Apertures and Resolution The resolving power of refracting telescope increases with the size of its objective lens. What other advantage is gained with a larger lens?
Read more -
Chapter 4: Problem 11 University Physics, Volume 3 17Circular Apertures and Resolution The distance between atoms in a molecule is about \(10^{-8} \mathrm{~cm}\). Can visible light be used to “see” molecules? Text Transcription: 10^-8 cm
Read more -
Chapter 4: Problem 12 University Physics, Volume 3 17Circular Apertures and Resolution A beam of light always spreads out. Why can a beam not be created with parallel rays to prevent spreading? Why can lenses, mirrors, or apertures not be used to correct the spreading?
Read more -
Chapter 4: Problem 13 University Physics, Volume 3 17X-Ray Diffraction Crystal lattices can be examined with X-rays but not UV. Why?
Read more -
Chapter 4: Problem 14 University Physics, Volume 3 17Holography How can you tell that a hologram is a true three dimensional image and that those in three dimensional movies are not?
Read more -
Chapter 4: Problem 15 University Physics, Volume 3 17Holography If a hologram is recorded using monochromatic light at one wavelength but its image is viewed at another wavelength, say 10% shorter, what will you see? What if it is viewed using light of exactly half the original wavelength?
Read more -
Chapter 4: Problem 16 University Physics, Volume 3 17Holography What image will one see if a hologram is recorded using monochromatic light but its image is viewed in white light? Explain.
Read more -
Chapter 4: Problem 48 University Physics, Volume 3 17Diffraction Gratings What is the spacing between structures in a feather that acts as a reflection grating, giving that they produce a first-order maximum for 525-nm light at a \(30.0^{\circ}\) angle. Text Transcription: 30 degrees
Read more -
Chapter 4: Problem 49 University Physics, Volume 3 17Diffraction Gratings An opal such as that shown in Figure 4.15 acts like a reflection grating with rows separated by about \(8 \mu \mathrm{m}\). If the opal is illuminated normally, (a) at what angle will red light be seen and (b) at what angle will blue light be seen? Text Transcription: 8 mu m
Read more -
Chapter 4: Problem 50 University Physics, Volume 3 17Diffraction Gratings At what angle does a diffraction grating produce a second-order maximum for light having a first-order maximum at \(20.0^{\circ}\)? Text Transcription: 20 degrees
Read more -
Chapter 4: Problem 51 University Physics, Volume 3 17Diffraction Gratings (a) Find the maximum number of lines per centimeter a diffraction grating can have and produce a maximum for the smallest wavelength of visible light. (b) Would such a grating be useful for ultraviolet spectra? (c) For infrared spectra?
Read more -
Chapter 4: Problem 52 University Physics, Volume 3 17Diffraction Gratings (a) Show that a 30,000 line per centimeter grating will not produce a maximum for visible light. (b) What is the longest wavelength for which it does produce a first-order maximum? (c) What is the greatest number of line per centimeter a diffraction grating can have and produce a complete second-order spectrum for visible light?
Read more -
Chapter 4: Problem 53 University Physics, Volume 3 17Diffraction Gratings (a) Show that a 30,000 line per centimeter grating will not produce a maximum for visible light. The analysis shown below also applies to diffraction gratings with lines separated by a distance d. What is the distance between fringes produced by a diffraction grating having 125 lines per centimeter for 600-nm light, if the screen is 1.50 m away? (Hint: The distance between adjacent fringes is \(\Delta y=x \lambda / d\), assuming the slit separation d is comparable to \(\lambda\).) Text Transcription: Delta y = x lambda/d lambda
Read more -
Chapter 4: Problem 54 University Physics, Volume 3 17Circular Apertures and Resolution The 305-m-diameter Arecibo radio telescope pictured in Figure 4.20 detects radio waves with a 4.00-cm average wavelength. (a) What is the angle between two just-resolvable point sources for this telescope? (b) How close together could these point sources be at the 2 million light-year distance of the Andromeda Galaxy?
Read more -
Chapter 4: Problem 55 University Physics, Volume 3 17Circular Apertures and Resolution Assuming the angular resolution found for the Hubble Telescope in Example 4.6 , what is the smallest detail that could be observed on the moon?
Read more -
Chapter 4: Problem 56 University Physics, Volume 3 17Circular Apertures and Resolution Diffraction spreading for a flashlight is insignificant compared with other limitations in its optics, such as spherical aberrations in its mirror. To show this, calculate the minimum angular spreading of a flashlight beam that is originally 5.00 cm in diameter with an average wavelength of 600 nm.
Read more -
Chapter 4: Problem 57 University Physics, Volume 3 17Circular Apertures and Resolution (a) What is the minimum angular spread of a 633-nm wavelength He-Ne laser beam that is originally 1.00 mm in diameter? (b) If this laser is aimed at a mountain cliff 15.0 km away, how big will the illuminated spot be? (c) How big a spot would be illuminated on the moon, neglecting atmospheric effects? (This might be done to hit a corner reflector to measure the round-trip time and, hence, distance.)
Read more -
Chapter 4: Problem 58 University Physics, Volume 3 17Circular Apertures and Resolution A telescope can be used to enlarge the diameter of a laser beam and limit diffraction spreading. The laser beam is sent through the telescope in opposite the normal direction and can then be projected onto a satellite or the moon. (a) If this is done with the Mount Wilson telescope, producing a 2.54-m-diameter beam of 633-nm light, what is the minimum angular spread of the beam? (b) Neglecting atmospheric effects, what is the size of the spot this beam would make on the moon, assuming a lunar distance of \(3.84 \times 10^{8} \mathrm{~m}\)? Text Transcription: 3.84 times 10^8 m
Read more -
Chapter 4: Problem 59 University Physics, Volume 3 17Circular Apertures and Resolution The limit to the eye’s acuity is actually related to diffraction by the pupil. (a) What is the angle between two just-resolvable points of light for a 3.00-mm-diameter pupil, assuming an average wavelength of 550 nm? (b) Take your result to be the practical limit for the eye. What is the greatest possible distance a car can be from you if you can resolve its two headlights, given they are 1.30 m apart? (c) What is the distance between two just-resolvable points held at an arm’s length (0.800 m) from your eye? (d) How does your answer to (c) compare to details you normally observe in everyday circumstances?
Read more -
Chapter 4: Problem 60 University Physics, Volume 3 17Circular Apertures and Resolution What is the minimum diameter mirror on a telescope that would allow you to see details as small as 5.00 km on the moon some 384,000 km away? Assume an average wavelength of 550 nm for the light received.
Read more -
Chapter 4: Problem 61 University Physics, Volume 3 17Circular Apertures and Resolution Find the radius of a star’s image on the retina of an eye if its pupil is open to 0.65 cm and the distance from the pupil to the retina is 2.8 cm. Assume \(\lambda=550 \mathrm{~nm}\). Text Transcription: lambda=550 nm
Read more -
Chapter 4: Problem 62 University Physics, Volume 3 17Circular Apertures and Resolution (a) The dwarf planet Pluto and its moon, Charon, are separated by 19,600 km. Neglecting atmospheric effects, should the 5.08-mdiameter Palomar Mountain telescope be able to resolve these bodies when they are \(4.50 \times 10^{9} \mathrm{~km}\) from Earth? Assume an average wavelength of 550 nm. (b) In actuality, it is just barely possible to discern that Pluto and Charon are separate bodies using a ground-based telescope. What are the reasons for this? Text Transcription: 4.50 times 10^9 km
Read more -
Chapter 4: Problem 63 University Physics, Volume 3 17Circular Apertures and Resolution A spy satellite orbits Earth at a height of 180 km. What is the minimum diameter of the objective lens in a telescope that must be used to resolve columns of troops marching 2.0 m apart? Assume \(\lambda=550 \mathrm{~nm}\). Text Transcription: lambda=550 nm
Read more -
Chapter 4: Problem 64 University Physics, Volume 3 17Circular Apertures and Resolution What is the minimum angular separation of two stars that are just-resolvable by the 8.1-m Gemini South telescope, if atmospheric effects do not limit resolution? Use 550 nm for the wavelength of the light from the stars.
Read more -
Chapter 4: Problem 65 University Physics, Volume 3 17Circular Apertures and Resolution The headlights of a car are 1.3 m apart. What is the maximum distance at which the eye can resolve these two headlights? Take the pupil diameter to be 0.40 cm.
Read more -
Chapter 4: Problem 66 University Physics, Volume 3 17Circular Apertures and Resolution When dots are placed on a page from a laser printer, they must be close enough so that you do not see the individual dots of ink. To do this, the separation of the dots must be less than Raleigh’s criterion. Take the pupil of the eye to be 3.0 mm and the distance from the paper to the eye of 35 cm; find the minimum separation of two dots such that they cannot be resolved. How many dots per inch (dpi) does this correspond to?
Read more -
Chapter 4: Problem 67 University Physics, Volume 3 17Circular Apertures and Resolution Suppose you are looking down at a highway from a jetliner flying at an altitude of 6.0 km. How far apart must two cars be if you are able to distinguish them? Assume that \(\lambda=550 \mathrm{~nm}\) and that the diameter of your pupils is 4.0 mm. Text Transcription: lambda=550 nm
Read more -
Chapter 4: Problem 68 University Physics, Volume 3 17Circular Apertures and Resolution Can an astronaut orbiting Earth in a satellite at a distance of 180 km from the surface distinguish two skyscrapers that are 20 m apart? Assume that the pupils of the astronaut’s eyes have a diameter of 5.0 mm and that most of the light is centered around 500 nm.
Read more -
Chapter 4: Problem 69 University Physics, Volume 3 17Circular Apertures and Resolution The characters of a stadium scoreboard are formed with closely spaced lightbulbs that radiate primarily yellow light. (Use \(\lambda=600 \mathrm{~nm}\).) How closely must the bulbs be spaced so that an observer 80 m away sees a display of continuous lines rather than the individual bulbs? Assume that the pupil of the observer’s eye has a diameter of 5.0 mm. Text Transcription: lambda=600 nm
Read more -
Chapter 4: Problem 70 University Physics, Volume 3 17Circular Apertures and Resolution If a microscope can accept light from objects at angles as large as \(\alpha=70^{\circ}\), what is the smallest structure that can be resolved when illuminated with light of wavelength 500 nm and (a) the specimen is in air? (b) When the specimen is immersed in oil, with index of refraction of 1.52? Text Transcription: alpha=70 degrees
Read more -
Chapter 4: Problem 71 University Physics, Volume 3 17Circular Apertures and Resolution A camera uses a lens with aperture 2.0 cm. What is the angular resolution of a photograph taken at 700 nm wavelength? Can it resolve the millimeter markings of a ruler placed 35 m away?
Read more -
Chapter 4: Problem 72 University Physics, Volume 3 17X-Ray Diffraction X-rays of wavelength 0.103 nm reflects off a crystal and a second-order maximum is recorded at a Bragg angle of \(25.5^{\circ}\). What is the spacing between the scattering planes in this crystal? Text Transcription: 25.5 degrees
Read more -
Chapter 4: Problem 73 University Physics, Volume 3 17X-Ray Diffraction A first-order Bragg reflection maximum is observed when a monochromatic X-ray falls on a crystal at a \(32.3^{\circ}\) angle to a reflecting plane. What is the wavelength of this X-ray? Text Transcription: 32.3 degrees
Read more -
Chapter 4: Problem 74 University Physics, Volume 3 17X-Ray Diffraction An X-ray scattering experiment is performed on a crystal whose atoms form planes separated by 0.440 nm. Using an X-ray source of wavelength 0.548 nm, what is the angle (with respect to the planes in question) at which the experimenter needs to illuminate the crystal in order to observe a first-order maximum?
Read more -
Chapter 4: Problem 75 University Physics, Volume 3 17X-Ray Diffraction The structure of the NaCl crystal forms reflecting planes 0.541 nm apart. What is the smallest angle, measured from these planes, at which X-ray diffraction can be observed, if Xrays of wavelength 0.085 nm are used?
Read more -
Chapter 4: Problem 76 University Physics, Volume 3 17X-Ray Diffraction On a certain crystal, a first-order X-ray diffraction maximum is observed at an angle of \(27.1^{\circ}\) relative to its surface, using an X-ray source of unknown wavelength. Additionally, when illuminated with a different, this time of known wavelength 0.137 nm, a second-order maximum is detected at \(37.3^{\circ}\). Determine (a) the spacing between the reflecting planes, and (b) the unknown wavelength. Text Transcription: 27.1 degrees 37.3 degrees
Read more -
Chapter 4: Problem 77 University Physics, Volume 3 17X-Ray Diffraction Calcite crystals contain scattering planes separated by 0.30 nm. What is the angular separation between first and second-order diffraction maxima when X-rays of 0.130 nm wavelength are used?
Read more -
Chapter 4: Problem 78 University Physics, Volume 3 17X-Ray Diffraction The first-order Bragg angle for a certain crystal is \(12.1^{\circ}\). What is the second-order angle? Text Transcription: 12. degrees
Read more -
Chapter 4: Problem 99 University Physics, Volume 3 17How many complete orders of the visible spectrum \((400 \mathrm{~nm}<\lambda<700 \mathrm{~nm})\) can be produced with a diffraction grating that contains 5000 lines per centimeter? Text Transcription: 400 nm< lambda < 700 nm
Read more -
Chapter 4: Problem 100 University Physics, Volume 3 17Two lamps producing light of wavelength 589 nm are fixed 1.0 m apart on a wooden plank. What is the maximum distance an observer can be and still resolve the lamps as two separate sources of light, if the resolution is affected solely by the diffraction of light entering the eye? Assume light enters the eye through a pupil of diameter 4.5 mm.
Read more -
Chapter 4: Problem 101 University Physics, Volume 3 17On a bright clear day, you are at the top of a mountain and looking at a city 12 km away. There are two tall towers 20.0 m apart in the city. Can your eye resolve the two towers if the diameter of the pupil is 4.0 mm? If not, what should be the minimum magnification power of the telescope needed to resolve the two towers? In your calculations use 550 nm for the wavelength of the light.
Read more -
Chapter 4: Problem 102 University Physics, Volume 3 17Radio telescopes are telescopes used for the detection of radio emission from space. Because radio waves have much longer wavelengths than visible light, the diameter of a radio telescope must be very large to provide good resolution. For example, the radio telescope in Penticton, BC in Canada, has a diameter of 26 m and can be operated at frequencies as high as 6.6 GHz. (a) What is the wavelength corresponding to this frequency? (b) What is the angular separation of two radio sources that can be resolved by this telescope? (c) Compare the telescope’s resolution with the angular size of the moon.
Read more -
Chapter 4: Problem 103 University Physics, Volume 3 17Calculate the wavelength of light that produces its first minimum at an angle of \(36.9^{\circ}\) when falling on a single slit of width \(1.00 \mu \mathrm{m}\). Text Transcription: 36.9 degrees 1.00 mu m
Read more -
Chapter 4: Problem 104 University Physics, Volume 3 17(a) Find the angle of the third diffraction minimum for 633-nm light falling on a slit of width \(20.0 \mu \mathrm{m}\). (b) What slit width would place this minimum at \(85.0^{\circ}\)? Text Transcription: 20.0 mu m 85.0 degrees
Read more -
Chapter 4: Problem 105 University Physics, Volume 3 17As an example of diffraction by apertures of everyday dimensions, consider a doorway of width 1.0 m. (a) What is the angular position of the first minimum in the diffraction pattern of 600-nm light? (b) Repeat this calculation for a musical note of frequency 440 Hz (A above middle C). Take the speed of sound to be 343 m/s.
Read more -
Chapter 4: Problem 106 University Physics, Volume 3 17What are the angular positions of the first and second minima in a diffraction pattern produced by a slit of width 0.20 mm that is illuminated by 400 nm light? What is the angular width of the central peak?
Read more -
Chapter 4: Problem 107 University Physics, Volume 3 17How far would you place a screen from the slit of the previous problem so that the second minimum is a distance of 2.5 mm from the center of the diffraction pattern?
Read more -
Chapter 4: Problem 108 University Physics, Volume 3 17How narrow is a slit that produces a diffraction pattern on a screen 1.8 m away whose central peak is 1.0 m wide? Assume \(\lambda=589 \mathrm{~nm}\). Text Transcription: lambda=589 nm
Read more -
Chapter 4: Problem 109 University Physics, Volume 3 17Suppose that the central peak of a single-slit diffraction pattern is so wide that the first minima can be assumed to occur at angular positions of \(\pm 90^{\circ}\). For this case, what is the ratio of the slit width to the wavelength of the light? Text Transcription: +_ 90 degrees
Read more -
Chapter 4: Problem 110 University Physics, Volume 3 17The central diffraction peak of the double-slit interference pattern contains exactly nine fringes. What is the ratio of the slit separation to the slit width?
Read more -
Chapter 4: Problem 111 University Physics, Volume 3 17Determine the intensities of three interference peaks other than the central peak in the central maximum of the diffraction, if possible, when a light of wavelength 500 nm is incident normally on a double slit of width 1000 nm and separation 1500 nm. Use the intensity of the central spot to be \(1 \mathrm{~mW} / \mathrm{cm}^{2}\). Text Transcription: 1 mW/cm^2
Read more -
Chapter 4: Problem 112 University Physics, Volume 3 17The yellow light from a sodium vapor lamp seems to be of pure wavelength, but it produces two first-order maxima at \(36.093^{\circ}\) and \(36.129^{\circ}\) when projected on a 10,000 line per centimeter diffraction grating. What are the two wavelengths to an accuracy of 0.1 nm? Text Transcription: 36.093 degrees 36.129 degrees
Read more -
Chapter 4: Problem 113 University Physics, Volume 3 17Structures on a bird feather act like a reflection grating having 8000 lines per centimeter. What is the angle of the first-order maximum for 600-nm light?
Read more -
Chapter 4: Problem 114 University Physics, Volume 3 17If a diffraction grating produces a first-order maximum for the shortest wavelength of visible light at \(30.0^{\circ}\), at what angle will the first-order maximum be for the largest wavelength of visible light? Text Transcription: 30. degrees
Read more -
Chapter 4: Problem 115 University Physics, Volume 3 17(a) What visible wavelength has its fourth order maximum at an angle of \(25.0^{\circ}\) when projected on a 25,000-line per centimeter diffraction grating? (b) What is unreasonable about this result? (c) Which assumptions are unreasonable or inconsistent? Text Transcription: 25.0 degrees
Read more -
Chapter 4: Problem 117 University Physics, Volume 3 17An amateur astronomer wants to build a telescope with a diffraction limit that will allow him to see if there are people on the moons of Jupiter. (a) What diameter mirror is needed to be able to see 1.00-m detail on a Jovian moon at a distance of \(7.50 \times 10^{8} \mathrm{~km}\) from Earth? The wavelength of light averages 600 nm. (b) What is unreasonable about this result? (c) Which assumptions are unreasonable or inconsistent? Text Transcription: 7.50 times 10^8 km
Read more -
Chapter 4: Problem 122 University Physics, Volume 3 17Show that a diffraction grating cannot produce a second-order maximum for a given wavelength of light unless the first-order maximum is at an angle less than \(30.0^{\circ}\). Text Transcription: 30.0 degrees
Read more -
Chapter 4: Problem 123 University Physics, Volume 3 17A He-Ne laser beam is reflected from the surface of a CD onto a wall. The brightest spot is the reflected beam at an angle equal to the angle of incidence. However, fringes are also observed. If the wall is 1.50 m from the CD, and the first fringe is 0.600 m from the central maximum, what is the spacing of grooves on the CD?
Read more -
Chapter 4: Problem 116 University Physics, Volume 3 17Consider a spectrometer based on a diffraction grating. Construct a problem in which you calculate the distance between two wavelengths of electromagnetic radiation in your spectrometer. Among the things to be considered are the wavelengths you wish to be able to distinguish, the number of lines per meter on the diffraction grating, and the distance from the grating to the screen or detector. Discuss the practicality of the device in terms of being able to discern between wavelengths of interest.
Read more -
Chapter 4: Problem 124 University Physics, Volume 3 17Objects viewed through a microscope are placed very close to the focal point of the objective lens. Show that the minimum separation x of two objects resolvable through the microscope is given by \(x=\frac{1.22 \lambda f_{0}}{D}\), where \(f_{0}\) is the focal length and D is the diameter of the objective lens as shown below. Text Transcription: x=1.22 lambda f_/D f_0
Read more