Q&A Hero

Q: At a bright diffraction line phasors associated with waves from the slits of a multiple-slit barrier: A) are aligned B) form a closed polygon C) form a polygon with several sides missing D) are parallel but adjacent phasors point in opposite directions E) form the arc of a circle

Q: A light spectrum is formed on a screen using a diffraction grating. The entire apparatus (source, grating and screen) is now immersed in a liquid of index 1.33. As a result, the pattern on the screen: A) remains the same B) spreads out C) crowds together D) becomes reversed, with the previously blue end becoming red E) disappears because the index isn't an integer

Q: In the equation for the lines of a diffraction grating,dis:A) the number of slitsB) the slit widthC) the slit separationD) the order of the lineE) the index of refraction

Q: In a double-slit diffraction experiment the number of interference fringes within the central diffraction maximum can be increased by: A) increasing the wavelength B) decreasing the wavelength C) increasing the slit separation D) decreasing the slit width E) increasing the slit width

Q: When 450-nm light is incident normally on a certain double-slit system the number of interference maxima within the central diffraction maximum is 5. When 900-nm light is incident on the same slit system the number is: A) 2 B) 3 C) 5 D) 9 E) 10

Q: Two slits in an opaque barrier each have a width of 0.020 mm and are separated by 0.050 mm. When coherent monochromatic light passes through the slits the number of interference maxima within the central diffraction maximum: A) is 1 B) is 2 C) is 4 D) is 5 E) cannot be determined unless the wavelength is given

Q: If we increase the wavelength of the light used to form a double-slit diffraction pattern: A) the width of the central diffraction peak increases and the number of bright fringes within the peak increases B) the width of the central diffraction peak increases and the number of bright fringes within the peak decreases C) the width of the central diffraction peak decreases and the number of bright fringes within the peak increases D) the width of the central diffraction peak decreases and the number of bright fringes within the peak decreases E) the width of the central diffraction peak increases and the number of bright fringes within the peak stays the same

Q: Two slits of width aand separation dare illuminated by a beam of light of wavelength . The separation of the interference fringes on a screen a distance Daway is:

Q: Figure (i) shows a double-slit pattern obtained using monochromatic light. Consider the following five possible changes in conditions: 1) decrease the frequency 2) increase the frequency 3) increase the width of each slit 4) increase the separation between the slits 5) decrease the separation between the slits Which of the above would change Figure (i) into Figure (ii)? A) 3 only B) 5 only C) 1 and 3 only D) 1 and 5 only E) 2 and 4 only

Q: The resolving power of a telescope can be increased by: A) increasing the objective focal length and decreasing the eyepiece focal length B) increasing the lens diameters C) decreasing the lens diameters D) inserting a correction lens between objective and eyepiece E) none of the above

Q: Two stars that are close together are photographed through a telescope. The black and white film is equally sensitive to all colors. Which situation would result in the most clearly separated images of the stars? A) Small lens, red stars B) Small lens, blue stars C) Large lens, red stars D) Large lens, blue stars E) Large lens, one star red and the other blue

Q: A diffraction-limited laser of length and aperture diameter dgenerates light of wavelength . If the beam is directed at the surface of the Moon a distance Daway, the radius of the illuminated area on the moon is approximately:

Q: Light of wavelength 480 nm falls on a slit of width 3.5 m. What is the relative intensity (that is, the value of I/Im) of the diffraction pattern at an angle of 18? A) 2.4 x 10-4 B) 1.7 x 10-3 C) 1.1 x 10-2 D) 1.0 x 10-1 E) 1.0

Q: The intensity of the single-slit diffraction pattern at any angle is given by . For light of wavelength 480 nm falling on a slit of width 3.5 m, what is the value of when = 18?A) 0.31 radB) 2.3 radC) 7.1 radD) 7.3 radE) 9.8 rad

Q: Two wavelengths, 800 nm and 600 nm, are used separately in single-slit diffraction experiments. The diagram shows the intensities on a far-away viewing screen as function of the angle made by the rays with the straight-ahead direction. If both wavelengths are then used simultaneously, which point corresponds to the smallest angle at which the light on the screen is purely 800-nm light? A) A B) B C) C D) D E) E

Q: The intensity at a secondary maximum of a single-slit diffraction pattern is less than the intensity at the central maximum chiefly because: A) some Huygens wavelets sum to zero at the secondary maximum but not at the central maximum B) the secondary maximum is further from the slits than the central maximum and intensity decreases as the square of the distance C) the Huygens construction is not valid for a secondary maximum D) the amplitude of every Huygens wavelet is smaller when it travels to a secondary maximum than when it travels to the central maximum E) none of the above

Q: In a single-slit diffraction pattern, the central maximum is about twice as wide as the other maxima. This is because: A) half the light is diffracted up and half is diffracted down B) the central maximum has both electric and magnetic fields present C) the small angle approximation applies only near the central maximum D) the screen is flat instead of spherical E) none of the above

Q: A diffraction pattern is produced on a viewing screen by illuminating a long narrow slit with light of wavelength . If the slit width is decreased and no other changes are made: A) the intensity at the center of the pattern decreases and the pattern expands away from the bright center B) the intensity at the center increases and the pattern contracts toward the bright center C) the intensity at the center of the pattern does not change and the pattern expands away from the bright center D) the intensity at the center of the pattern does not change and the pattern contracts toward the bright center E) neither the intensity at the center of the pattern nor the pattern itself change

Q: A diffraction pattern is produced on a viewing screen by illuminating a long narrow slit with light of wavelength . If is increased and no other changes are made: A) the intensity at the center of the pattern decreases and the pattern expands away from the bright center B) the intensity at the center of the pattern increases and the pattern contracts toward the bright center C) the intensity at the center of the pattern does not change and the pattern expands away from the bright center D) the intensity at the center of the pattern does not change and the pattern contracts toward the bright center E) neither the intensity at the center of the pattern nor the pattern itself change

Q: A parallel beam of monochromatic light is incident on a slit of width 2 cm. The light passing through the slit falls on a screen 2 m away. As the slit width is decreased: A) the width of the pattern on the screen continuously decreases B) the width of the pattern on the screen at first decreases but then increases C) the width of the pattern on the screen increases and then decreases D) the width of the pattern on the screen remains the same E) the width of the pattern on the screen continuously increases

Q: A student wishes to produce a single-slit diffraction pattern in a ripple tank experiment. He considers the following parameters: I. frequency II. wavelength III. water depth IV. slit width Which two of the above should be decreased to produce more bending? A) I, III B) I, IV C) II, III D) II, IV E) III, IV

Q: Monochromatic plane waves of light are incident normally on a single slit. Which one of the five figures below most correctly shows the diffraction pattern observed on a distant screen? A) I B) II C) III D) IV E) V

Q: Consider a single-slit diffraction pattern caused by a slit of width a. There is a minimum at equal to:

Q: The diagram shows a single slit with the direction to a point P on a distant screen (not shown). At P, the pattern has its maximum nearest the central maximum. If X and Y are the edges of the slit, what is the path length difference (PX) - (PY)?

Q: The diagram shows a single slit with the direction to a point P on a distant screen (not shown). At P, the pattern has its second minimum (from its central maximum). If X and Y are the edges of the slit, what is the path length difference (PX) " (PY)?

Q: No fringes are seen in a single-slit diffraction pattern if: A) the screen is far away B) the wavelength is less than the slit width C) the wavelength is greater than the slit width D) the wavelength is less than the distance to the screen E) the distance to the screen is greater than the slit width

Q: In the equation for single-slit diffraction, ï±ï€ is:A) the angle to the first minimumB) the angle to the second maximumC) the phase angle between the extreme raysD) where Nis an integerE) where Nis an integer

Q: A plane wave with a wavelength of 500 nm is incident normally on a single slit with a width of 5.0 x10-6m. Consider waves that reach a point on a far-away screen such that rays from the slit make an angle of 1.0ï‚°with the normal. The difference in phase for waves from the top and bottom of the slit is:A) 0 radB) 0.55 radC) 1.1 radD) 1.6 radE) 2.2 rad

Q: At the second minimum adjacent to the central maximum of a single-slit diffraction pattern the Huygens wavelet from the top of the slit is 180°out of phase with the wavelet from:A) a point one-fourth of the slit width from the topB) the midpoint of the slitC) a point one-fourth of the slit width from the bottom of the slitD) the bottom of the slitE) none of these

Q: At the first minimum adjacent to the central maximum of a single-slit diffraction pattern the phase difference between the Huygens wavelet from the top of the slit and the wavelet from the midpoint of the slit is:

Q: A point source of monochromatic light is placed in front of a soccer ball and a screen is placed behind the ball. The light intensity pattern on the screen is best described as: A) a dark disk on a bright background B) a dark disk with bright rings outside C) a dark disk with a bright spot at its center D) a dark disk with a bright spot at its center and bright rings outside E) a bright disk with bright rings outside

Q: In order to obtain a single-slit diffraction pattern with a central maximum and several secondary maxima, the slit width could be:

Q: The shimmering or wavy lines that can often be seen near the ground on a hot day are due to: A) Brownian movement B) reflection C) refraction D) diffraction E) dispersion

Q: When the atmosphere is not quite clear, one may sometimes see colored circles concentric with the Sun or the Moon. These are generally not more than a few diameters of the Sun or Moon and invariably the innermost ring is blue. The explanation for these phenomena involves: A) reflection B) refraction C) interference D) diffraction E) Doppler effect

Q: When a highly coherent beam of light is directed against a very fine wire, the shadow formed behind it is not just that of a single wire but rather looks like the shadow of several parallel wires. The explanation of this involves: A) refraction B) diffraction C) reflection D) Doppler effect E) an optical illusion

Q: The rainbow seen after a rain shower is caused by: A) diffraction B) interference C) refraction D) polarization E) absorption

Q: Diffraction plays an important role in which of the following phenomena? A) The sun appears as a disk rather than a point to the naked eye B) Light is bent as it passes through a glass prism C) A cheerleader yells through a megaphone D) A farsighted person uses eyeglasses of positive focal length E) A thin soap film exhibits colors when illuminated with white light

Q: Radio waves are readily diffracted around buildings whereas light waves are negligibly diffracted around buildings. This is because radio waves: A) are plane polarized B) have much longer wavelengths than light waves C) have much shorter wavelengths than light waves D) are nearly monochromatic (single frequency) E) are amplitude modulated (AM)

Q: Sound differs from light in that sound: A) is not subject to diffraction B) is a torsional wave rather than a longitudinal wave C) does not require energy for its origin D) is a longitudinal wave rather than a transverse wave E) is always monochromatic

Q: A beam of x rays of wavelength 0.10nm is found to diffract in second order from the face of a LiF crystal at a Bragg angle of 30°. The distance between adjacent crystal planesis about:A) 0.10nmB) 0.20 nmC) 0.25 nmD) 0.30 nmE) 0.40 nm

Q: An x-ray beam of wavelength 3 x10-11m is incident on a calcite crystal of lattice spacing 0.3 nm. The smallest angle between crystal planes and the x-ray beam which will result in constructive interference is:A) 2.9B) 5.7C) 12D) 23E) none of these

Q: A beam of x-rays of wavelength 0.20 nm is diffracted by a set of planes in a crystal whose separation is 3.1 x10-8cm. The smallest angle between the beam and the crystal planes for which a reflection occurs is:A) 0.70 radB) 0.33 radC) 0.066 radD) 0.033 radE) 0.0033 rad

Q: The largest x-ray wavelength that can be diffracted by crystal planes with a separation of 0.316 nm is: A) 0.158 nm B) 0.316 nm C) 0.474 nm D) 0.632 nm E) 1.26 nm

Q: Bragg's law for x-ray diffraction is , where is the angle between the incident beam and:A) a reflecting plane of atomsB) the normal to a reflecting plane of atomsC) the scattered beamD) the normal to the scattered beamE) the refracted beam

Q: X rays are: A) electromagnetic waves B) negatively charged ions C) rapidly moving electrons D) rapidly moving protons E) rapidly moving neutrons

Q: Which of the following is true for Bragg diffraction but not for diffraction from a grating? A) Two different wavelengths may be used B) For a given wavelength, a maximum may exist in several directions C) Long waves are deviated more than short ones D) There is only one grating spacing E) Maxima occur only for particular angles of incidence

Q: Bragg's law for x-ray diffraction is . The quantity dis:A) the height of a unit cellB) the smallest interatomic distanceC) the distance from detector to sampleD) the distance between planes of atomsE) the usual calculus symbol for a differential

Q: What is the minimum number of slits required in a diffraction grating to just resolve light with wavelengths of 471.0 nm and 471.6 nm? A) 99 B) 197 C) 393 D) 786 E) 1179

Q: A diffraction grating just resolves the wavelengths 400.0 nm and 400.1 nm in first order. The number of slits in the grating is: A) 400 B) 1000 C) 2500 D) 4000 E) not enough information is given

Q: Two nearly equal wavelengths of light are incident on an Nslit grating. The two wavelengths are not resolvable. When Nis increased they become resolvable. This is because: A) more light gets through the grating B) the lines get more intense C) the entire pattern spreads out D) there are more orders present E) the lines become more narrow

Q: To obtain greater dispersion by a diffraction grating: A) the slit width should be increased B) the slit width should be decreased C) the slit separation should be increased D) the slit separation should be decreased E) more slits with the same width and separation should be added to the system

Q: Light of wavelength 550 nm is incident on a diffraction grating that is 1 cm wide and has 1000 slits. What is the dispersion of the m= 2 line? A) 2.0 x 105rad/m B) 2.0 x 104rad/m C) 2.0 x 103rad/m D) 2.0 x 102rad/m E) 2.0 x 101rad/m

Q: A light beam incident on a diffraction grating consists of waves with two different wavelengths. The separation of the two first order lines is great if: A) the dispersion is great B) the resolution is great C) the dispersion is small D) the resolution is small E) none of the above (line separation does not depend on either dispersion or resolution)

Q: The dispersion of a diffraction grating indicates: A) the resolution of the grating B) the separation of lines of the same order C) the number of rulings in the grating D) the width of the lines E) the spreading apart of diffraction lines associated with different wavelengths

Q: The resolving power of a diffraction grating is defined by are:A) any two wavelengthsB) any two wavelengths that are nearly the sameC) two wavelengths for which lines of the same order are separated by radiansD) two wavelengths for which lines of the same order are separated by 2radiansE) two wavelengths for which lines of the same order are separated by half the width of a maximum

Q: The resolving power Rof a grating can have units: A) cm B) degree/nm C) watt D) nm/cm E) watt/nm

Q: The dispersion Dof a grating can have units: A) cm B) 1/nm C) nm/cm D) radian E) none of these

Q: The widths of the lines produced by monochromatic light falling on a diffraction grating can be reduced by: A) increasing the wavelength of the light B) increasing the number of rulings without changing their spacing C) decreasing the spacing between adjacent rulings without changing the number of rulings D) decreasing both the wavelength and the spacing between rulings by the same factor E) increasing the number of rulings and decreasing their spacing so the length of the grating remains the same

Q: As more slits with the same spacing are added to a multiple-slit system the lines: A) spread further apart B) move closer together C) become wider D) become narrower E) do not change in position or width

Q: Light of wavelength 550 nm is incident on a diffraction grating that is 1 cm wide and has 1000 slits. What is the half-width of the m= 1 line? A) 5.5 x 10-5rad B) 5.5 x 10-4rad C) 5.5 x 10-3rad D) 5.5 x 10-2rad E) 5.5 x 10-1rad

Q: If 550-nm light is incident normally on a diffraction grating and exactly 6 lines are produced, the ruling separation must be:

Q: Monochromatic light is normally incident on a diffraction grating. The mthorder line is at an angle of diffraction and has width w. A wide single slit is now placed in front of the grating and its width is then slowly reduced. As a result:A) both and wincreaseB) both and wdecreaseC) remains the same and wincreasesD) remains the same and wdecreasesE) decreases and wincreases

Q: If white light is incident on a diffraction grating: A) the first order lines for all visible wavelengths occur at smaller diffraction angles than any of the second order lines B) some first order lines overlap the second order lines if the ruling separation is small but do not if it is large C) some first order lines overlap second order lines if the ruling separation is large but do not if it is small D) some first order lines overlap second order lines no matter what the ruling separation E) first and second order lines have the same range of diffraction angles

Q: A beam of white light (from 400 nm for violet to 700 nm for red) is normally incident on a diffraction grating. It produces two orders on a distant screen. Which diagram below (R = red, V = violet) correctly shows the pattern on the screen? A) I. B) II. C) III. D) IV. E) V.

Q: A mixture of 450-nm and 900-nm light is incident on a multiple-slit system. Which of the following is true? A) All lines of the 900-nm light coincide with lines of the 450-nm light B) All lines of the 450-nm light coincide with lines of the 900-nm light C) None of the lines of the 900-nm light coincide with lines of the 450-nm light D) None of the lines of the 450-nm light coincide with lines of the 900-nm light E) None of the above

Q: Light of wavelength is normally incident on a diffraction grating G. On the screen S, the central line is at P and the first order line is at Q, as shown. The distance between adjacent slits in the grating is:

Q: A diffraction grating of width Wproduces a deviation in second order for light of wavelength . The total number Nof slits in the grating is given by:

Q: When light of a certain wavelength is incident normally on a certain diffraction grating the line of order 1 is at a diffraction angle of 25°. The diffraction angle for the second order line is:A) 25°B) 42°C) 50°D) 58°E) 75°

Q: The spacing between adjacent slits on a diffraction grating is The deviation of the first order diffracted beam is given by:

Q: 600-nm light is incident on a diffraction grating with a ruling separation of 1.7 x10-6m. The second order line occurs at a diffraction angle of:A) 0B) 10°C) 21°D) 42°E) 45°

Q: An N-slit system has slit separation dand slit width a. Plane waves with intensity Iand wavelength are incident normally on it. The angular separation of the lines depends only on:

Q: In the equation for the lines of a diffraction grating, is:A) the number of slitsB) the slit widthC) the slit separationD) the order of the lineE) the path length difference

Q: In the equation for the lines of a diffraction grating,mis:A) the number of slitsB) the slit widthC) the slit separationD) the order of the lineE) the index of refraction

Q: A person with her eye relaxed looks through a diffraction grating at a distant monochromatic point source of light. The slits of the grating are vertical. She sees: A) one point of light B) a hazy horizontal strip of light of the same color as the source C) a hazy strip of light varying from violet to red D) a sequence of horizontal points of light E) a sequence of closely spaced vertical lines

Q: In a Michelson interferometer, in order to shift the pattern by half a fringe, one of the mirrors at the end of an arm must be moved by: A) one wavelength B) half a wavelength C) one-quarter wavelength D) It depends on the wavelength. E) It depends on which mirror is moved.

Q: A thin film with an index of refraction of 1.60 is placed in one of the beams of a Michelson interferometer. If this causes a shift of 8 bright fringes in the pattern produced by light of wavelength 580 nm, what is the thickness of the film? A) 1.5 m B) 2.9 m C) 3.9 m D) 7.7 m E) 16 m

Q: An air wedge is formed using two glass plates that are in contact along their left edge. When viewed by highly monochromatic light, there are exactly 4001 dark bands in the reflected light. The air is now evacuated (with the glass plates remaining rigidly fixed) and the number of dark bands decreases to exactly 4000. The index of refraction of the air is: A) 0.00025 B) 0.00050 C) 1.00025 D) 1.00050 E) 1.00000, by definition

Q: An air wedge is formed from two glass plates which are in contact at their left edges. There are ten dark bands when viewed by reflection using monochromatic light. The left edge of the top plate is now slowly lifted until the plates are parallel. During this process: A) the dark bands crowd toward the right edge B) the dark bands remain stationary C) the dark bands crowd toward the left edge D) the dark bands spread out, disappearing off the right edge E) the dark bands spread out, disappearing off the left edge

Q: In a thin film experiment, a wedge of air is used between two glass plates. If the wavelength of the incident light in air is 480 nm, how much thicker is the air wedge at the 16th dark fringe than it is at the 6th? A) 240 nm B) 480 nm C) 2400 nm D) 4800 nm E) none of these

Q: A liquid of refractive index n= 4/3 replaces the air between a fixed wedge formed from two glass plates as shown. As a result, the spacing between adjacent dark bands in the interference pattern: A) increases by a factor of 4/3 B) increases by a factor of 3 C) remains the same D) decreases to 3/4 of its original value E) decreases to 1/3 of its original value