Deck 6: Optics and Telescopes

A)Lenses sort out the entering light by color (or wavelength) and absorb the colors not required for the image.
B)A lens captures all the light emitted by a source and focuses it to form an image.
C)A lens reduces the chromatic aberration found in light emitted naturally from a source.
D)Light that would not otherwise form an image enters a lens and has its direction changed so that it focuses to form an image.

A)Light of all colors converges to precisely the same point.
B)The red light converges to a point that is slightly closer to the lens than the point to which the blue light converges.
C)The blue light converges to a point that is slightly closer to the lens than the point to which the red light converges.
D)The image of the Sun will be distorted, being more red toward the bottom and somewhat green near the top.

A)the intensity of the light wave is reduced.
B)the frequency of the wave increases.
C)the wave slows down.
D)the entire wave turns around and returns to the source.

A)the change in direction of a light ray as it reflects from a more dense material than the one in which it is traveling
B)the absorption of light as it traverses a dense, transparent material
C)the breaking of white light into its composite colors
D)the change in direction of a light ray as it crosses from a less dense, transparent material to a more dense one

A)the speed of light is different in the two materials.
B)some light is reflected at the surface.
C)the amount of absorption of the light changes at the surface.
D)the frequency of the light changes at the surface.

A)slowdown of light in denser material.
B)speedup of light as it enters denser material.
C)change in the color or wavelength of light as it enters denser material.
D)reflection of part of the light at the surface.

A)4
B)1600
C)20
D)400

A)2 × 10⁴
B)2000
C)4 × 10⁶
D)4

A)10×
B)8×
C)16×
D)80×

A)400×
B)40×
C)4×
D)80×

A)the size of the objective mirror or lens
B)only the focal length of the objective
C)only the focal length of the eyepiece
D)the focal lengths of both the objective and the eyepiece

A)focal length of the eyepiece.
B)focal length of the objective minus the focal length of the eyepiece.
C)sum of the focal lengths of objective and eyepiece.
D)focal length of the objective.

A)Different colors are refracted at different angles to produce a spectrum.
B)Selected colors are absorbed so that the remaining light that leaves the prism is colored.
C)The speed of the red light that leaves the prism is higher than that of the blue light, leading to a colored beam.
D)Selected colors are reflected from the outer faces of the prism, and the light that passes through is colored.

A)The directions of all wavelengths are changed by the same amount.
B)The intermediate wavelengths.
C)The longer wavelengths.
D)The shorter wavelengths.

A)radio telescope
B)Cassegrain telescope
C)reflecting telescope
D)refracting telescope

A)opaqueness of the glass lens to certain wavelengths of light
B)bubbles in the glass lens that scatters light
C)chromatic aberration, focusing light of different wavelengths to different foci
D)spherical aberration at the primary reflecting surface

A)refracting
B)Newtonian reflecting
C)reflecting, prime focus
D)Cassegrain reflecting

A)sag too much under their own weight.
B)give too much magnification.
C)have too little chromatic aberration.
D)be too thick, and suffer too much spherical aberration.

A)red light bends more than blue light.
B)blue light bends more than red light.
C)all colors bend the same amount.
D)no bending is experienced by any of the colors.

A)The thick lens has the longer focal length.
B)The thin lens has the longer focal length.
C)Focal length is determined by the focal point for parallel light and has nothing to do with lens thickness.
D)To determine relative focal length, you would have to know both the lens thickness and the light wavelength.

A)The length of the telescope tube is 8 inches.
B)The radius of the mirror is 8 inches.
C)The diameter of the mirror is 8 inches.
D)The focal length of the mirror is 8 inches.

A)spherical aberration.
B)chromatic aberration.
C)coma.
D)astigmatism.

A)equal to the angle between the incident beam and the perpendicular.
B)equal to 1/2 the angle between the incident beam and the perpendicular.
C)always a right angle, or 90°.
D)twice the angle between incident beam and the perpendicular.

A)r is equal to 2i.
B)the reflected ray always follows the perpendicular direction from the reflecting surface.
C)r is equal to i/2.
D)r is equal to i.

A)2α on the opposite side of the perpendicular to the incident ray
B)0°; the ray will always reflect along the perpendicular, a condition necessary for the focusing of light.
C)the same angle α on the opposite side of the perpendicular to the incident ray
D)the same angle α on the same side of the perpendicular, returning along the incident direction

A)two curved mirrors.
B)several mirrors, some curved, some flat, to guide light to a fixed focus with respect to Earth.
C)one curved mirror and one flat mirror at a 45° angle to the curved mirror.
D)only one mirror.

A)It makes the telescope easier to use compared to a prime focus.
B)It introduces the possibility of distortion in the secondary mirror.
C)It decreases the amount of light reaching the objective mirror.
D)It causes a blank spot in the image where the beam has been interrupted by the secondary mirror.

A)Newtonian focus.
B)out-of-focus position.
C)prime focus.
D)Cassegrain focus.

A)about 3%
B)about 44%
C)about 1/6, or 17%
D)about 36%

A)Although the brightness is unaffected, the size of the image will be reduced.
B)A part of the image is missing.
C)Only the brightness is reduced.
D)Depending on which part of the mirror is obscured, the color of the image is affected.

A)A concave primary mirror and concave secondary mirror reflect light back through a hole in the primary mirror.
B)A series of mirrors channel the light to a remote and fixed location.
C)A concave primary mirror and flat, diagonal secondary mirror are used.
D)A concave primary mirror and convex secondary mirror reflect light back through a hole in the primary mirror.

A)fF.
B)f/F.
C)F/f ².
D)F/f.

A)100
B)160
C)10
D)1600

A)elliptical.
B)spherical.
C)perfectly flat and smooth.
D)parabolic.

A)6.0 m.
B)11.0 m.
C)30.0 m.
D)6.5 m.

A)a spherical mirror is used with a correcting lens.
B)a parabolic mirror is used with a correcting lens.
C)an elliptical mirror is used without a correcting lens.
D)an elliptical mirror is used with a correcting lens.

A)diffraction.
B)refraction.
C)reflection.
D)chromatic aberration.

A)larger diameter lenses or mirrors and shorter wavelength light (or other electromagnetic radiation).
B)smaller diameter lenses or mirrors and longer wavelength light (or other electromagnetic radiation).
C)smaller diameter lenses or mirrors and shorter wavelength light (or other electromagnetic radiation).
D)larger diameter lenses or mirrors and longer wavelength light (or other electromagnetic radiation).

A)0.16 m
B)1600 m
C)1.6 m
D)160 m

A)0.00125 arcsec
B)0.125 arcsec
C)12.5 arcsec
D)0.0125 arcsec

A)Adaptive optics can only be used when a bright star is in the field of view.
B)Sunlight reflecting from artificial satellites serves as the target.
C)Adaptive optics can only be used on very powerful telescopes for which even faint stars can be used as targets.
D)Lasers are used to excite sodium atoms in the upper atmosphere to glow and serve as a target.

A)The telescope with 0.1 arcsec has better resolution.
B)The telescope with 0.2 arcsec has better resolution.
C)It really doesn't mean anything, because telescopes are never limited by diffraction.
D)It is relatively unimportant, because angular resolution is only one of many forms of resolution that must be taken into account.

A)They deform the telescope mirror to compensate for turbulence in the atmosphere.
B)They deform the telescope mirror to compensate for the mirror's tendency to sag under its own weight.
C)They add false color to the images.
D)They compensate for Earth's rotation.

A)active optics - the ability to change the shape of the mirror to compensate for sagging and for expansion/contraction as the mirror temperature changes
B)adaptive optics - the ability to change the shape of the mirror to compensate for atmospheric changes that would otherwise distort the image
C)the capability of creating segmented mirrors much larger than any single-piece mirror
D)the ability to build a single mirror that can detect electromagnetic radiation all across the spectrum, from gamma rays to radio waves

A)placing optical telescopes in orbit above the atmosphere
B)building lens telescopes comparable in size to the largest mirror telescopes (approximately 10 m)
C)computer connections allowing radio telescopes thousands of miles apart to be used in unison
D)adaptive optics, allowing the shape of a telescope mirror to be changed rapidly to compensate for atmospheric turbulence

A)antireflective coatings, where the mirror is coated with a substance, such as fluorite, to reduce the amount of reflected light
B)increased size, where mirrors are made far larger than was possible before, e. g., 8 to 10 m in diameter and larger
C)adaptive optics, where the tilt and shape of mirrors in the telescope are changed many times per second to compensate for atmospheric turbulence
D)multiple-mirror telescopes, where several mirrors are mounted together in a single telescope to simulate the performance of a single, very large mirror

A)A single, thin primary mirror that has a 20-m diameter has its shape changed and controlled by a computer.
B)The light from two 10-m telescopes, which are 85 m apart, will eventually be combined into a single image.
C)A dish of mercury 100 m in diameter is rotated and thus forms a very large parabolic mirror.
D)Six thin mirrors with diameters of 10 m are arranged in a circle to simulate a single mirror with a diameter of 30 m.

A)1/20,000 arcsec
B)1/200 arcsec
C)1/2000 arcsec
D)1/5 arcsec (limited by atmospheric turbulence, or "seeing")

A)tarnishing of the mirror surface by air pollution
B)cracking of the mirror by earthquakes
C)bending of the mirror surface from repeated exposure to the cold night air
D)light scattering in the atmosphere from nearby cities

A)0.25 arcsec
B)0.50 arcsec
C)0.75 arcsec
D)1.00 arcsec

A)16.4 m
B)20 m
C)40 m
D)200 m

A)red
B)green
C)blue
D)The resolution is the same all across the visible spectrum.

A)the Gran Telescopio Canarias.
B)the European Southern Observatory.
C)Gemini North.
D)the Keck II telescope on Mauna Kea, Hawaii.

A)a very fine grained photographic film that can be "read" electronically
B)an extremely sensitive thermocouple that records the temperature increase every time a photon hits it
C)a spectrometer that has been made especially sensitive by using a grating with over one million lines per centimeter
D)an array of electronic sensors that record the charge buildup due to photon absorption

A)the information on CCDs can be stored electronically.
B)CCDs are much more efficient at recording the light that falls on them.
C)CCDs are cheaper to build.
D)CCDs reduce the diffraction-limited angular resolution.

A)25%
B)50%
C)98%
D)2%

A)The electronic signals from these adjacent pixels will really represent a single signal representing the average intensities of this two-pixel region.
B)The resolution of the picture will improve dramatically.
C)The CCD can no longer be used on this instrument.
D)Only the long-wavelength images will remain sharp.

A)variation of the mass of an object as it moves through space.
B)distribution of light intensity among the various colors.
C)vibration of Earth following an earthquake.
D)brightness of light at one specific color.

A)A prism cannot be used with a CCD detector and a computer.
B)A prism is opaque to ultraviolet light.
C)A prism reduces the light intensity unevenly over the spectrum.
D)A prism does not disperse the colors uniformly.

A)screen placed at the focus of a telescope to provide a calibrated grid on photographs.
B)source of light that provides calibration lines alongside the measured spectrum.
C)piece of glass or metal on which many closely spaced grooves have been cut.
D)prism of very pure glass through which light can pass.

A)The known positions of the neon spectrum lines allow the spectrum to be calibrated so that the wavelengths of the lines from the galaxy can be determined.
B)The emission lines from the laboratory neon will fill in the absorption lines from neon in our atmosphere, thus getting rid of these lines so that they are not confused with lines from the galaxy.
C)The laboratory neon lines show the maximum velocity position of neon. These laboratory neon lines can then be compared with neon lines from the galaxy spectrum so the Doppler shift based on neon can be calculated.
D)The procedure is just a test to assure that the system is working properly without distortion before the galaxy spectrum is analyzed.

A)100
B)1000
C)10,000
D)100,000

A)radio waves have shorter wavelengths.
B)radio waves are electromagnetic, unlike light.
C)light waves are electromagnetic, unlike radio waves.
D)radio waves have lower frequencies.

A)1980.
B)1946.
C)1932.
D)1936.

A)during the 1920s.
B)during the 1980s, with the development of CCD detectors.
C)in the early 1960s, with the development of satellites.
D)in the late 1940s, shortly after World War II.

A)increase the exposure time.
B)observe at a longer wavelength.
C)observe from high mountains where atmospheric distortion is less.
D)make the dish size larger.

A)atmospheric distortion.
B)light pollution.
C)diffraction.
D)cloud cover.

A)the wavelength of radio waves is larger than that of visible light.
B)it is difficult to make a reflector for radio waves since these waves penetrate most materials.
C)Earth's atmosphere disturbs radio waves from space much more than it does visible light.
D)radio wavelengths are smaller than visible wavelengths, making it difficult to produce a reflector sufficiently smooth to produce images.

A)The ratio of wavelength to telescope diameter is larger for the radio telescope.
B)It is difficult to make a radio dish sufficiently smooth to reflect radio waves.
C)Atmospheric turbulence disturbs radio waves more than it does visible light.
D)The ratio of wavelength to telescope diameter is smaller for the radio telescope.

A)They have about the same angular resolution, since angular resolution is limited by turbulence in Earth's atmosphere, not by mirror diameter.
B)The 305-m telescope has much worse angular resolution than the 10-m Keck telescope.
C)It is not possible to compare their angular resolution, since they work in different wavelength ranges.
D)The 305-m telescope has much better angular resolution than the 10-m Keck telescope.

A)a single radio telescope with a 100-m dish
B)two 25-m radio telescopes separated by 200 m
C)two 50-m radio telescopes separated by 200 m
D)two 25-m radio telescopes separated by 380 m

A)radio waves have much longer wavelengths than visible light.
B)optical mirrors suffer from chromatic aberration.
C)angular resolution gets worse as mirror size increases.
D)radio waves have much shorter wavelengths than visible light.

A)to obtain much sharper images of sources
B)to ensure that at least one of the telescopes is in a radio interference-free zone
C)to ensure that observations are uninterrupted by the failure of one or two telescopes
D)to collect more radiation from very faint sources

A)1 arcsec.
B)0.001 arcsec.
C)0.1 arcsec.
D)1 arcmin.

A)85 units.
B)2 units.
C)3 units.
D)27 units.

A)0.02 m
B)0.05 m
C)0.5 m
D)20 m

A)better than that of the radio telescope by a factor of 1000.
B)worse than that of the radio telescope by a factor of 1000.
C)better than that of the radio telescope by a factor of 100,000.
D)worse than that of the radio telescope by a factor of 100,000.

A)neither visible nor IR is emitted by Saturn. What we see is entirely reflected from the Sun.
B)visible radiation is emitted by Saturn but the IR is entirely reflected from the Sun.
C)IR radiation is emitted by Saturn but the visible is entirely reflected from the Sun.
D)both visible and IR are emitted by Saturn in substantial amounts.

A)above most of the moisture in Earth's atmosphere.
B)farther from city lights.
C)closer to the stratospheric ozone layer.
D)above most of the turbulence in Earth's atmosphere.