Deck 3: Light and Telescopes

A) longer wavelengths
B) intermediate wavelengths, the green color
C) All wavelengths are deviated by the same amount.
D) shorter wavelengths

A) violet light travels faster than red light, even in a vacuum.
B) violet light has a shorter wavelength than red light.
C) violet light is hotter than red light.
D) photons of violet light have less energy than photons of red light.

A) adds color to the light.
B) subtracts from the light, producing color.
C) causes different wavelengths of light to travel in different directions.
D) causes different parts of the light beam to vibrate at different frequencies.

A) 400 nm to 700 nm.
B) 1 nm to 100 nm.
C) 800 nm to 1900 nm.
D) 90 nm to 130 nm.

A) 1200 nm to 1500 nm
B) 4000 nm to 7000 nm
C) 400 nm to 700 nm
D) 100 nm to 400 nm

A) The two waves would have canceled each other out, and he would have seen nothing. This is why he used only one color.
B) Two patterns would have formed, one on each color, exactly on top of each other.
C) Two similar patterns would have formed, with the light of the shorter wavelength forming the more closely spaced pattern.
D) Two similar patterns would have formed, with the light of the longer wavelength forming the more closely spaced pattern.

A) Albert Einstein
B) Thomas Young
C) Isaac Newton
D) James Clerk Maxwell

A) Thomas Young
B) Isaac Newton
C) Albert Einstein
D) James Clerk Maxwell

A) light striking a metal surface releases electrons from the metal, with violet light producing more energetic electrons than red light.
B) light passing through two narrow, closely spaced slits produces a pattern of light and dark bands on a screen by wave interference.
C) the speed of light in a vacuum is the same for all observers.
D) the speed of light decreases when it enters a denser, transparent medium.

A) red.
B) yellow.
C) white..
D) black (no light).

A) 10-¹² m.
B) 10-⁶ m.
C) 10⁹ m.
D) 10-⁹ m.

A) 500 thousandths of a meter
B) 500 trillionths of a meter (1 trillion = 1,000,000 million)
C) 500 millionths of a meter
D) 500 billionths of a meter (1 billion = 1000 million)

A) demonstrated the wave nature of light by passing light through two slits and obtaining a pattern of bright and dark bands on a screen that he correctly interpreted as interference between the two light beams.
B) proved mathematically that light could be described as oscillating electric and magnetic fields.
C) showed that a prism through which light passed added a spectrum of colors to the light.
D) demonstrated that white light was made up of colors that could be split by a prism and that these colors were not produced by the glass through which the light passed.

A) proved mathematically that light could be described as oscillating electric and magnetic fields.
B) demonstrated that white light was made up of colors that could be split by a prism and that these colors were not produced by the glass through which the light passed.
C) showed that a prism through which light passed added a spectrum of colors to the light.
D) demonstrated the wave nature of light by passing light through two slits and obtaining a pattern of bright and dark bands on a screen that he ascribed to interference between the two beams.

A) red.
B) yellow.
C) white.
D) black (no light).

A) adds color to the light.
B) subtracts from the light to allow the previously masked colors to appear.
C) changes the white light into something completely different so that it could not be re-formed into white light.
D) causes different colors in the white light to be emitted in different directions.

A) travels more quickly (through a vacuum) than red light.
B) has a shorter wavelength than red light.
C) travels more slowly (through a vacuum) than red light.
D) has a longer wavelength than red light.

A) the prism absorbs colors from different parts of the broad beam coming out of the prism, leaving the complementary colors that we see.
B) different colors are caused by multiple reflections within the prism and the resulting interference between the beams.
C) refraction changes the directions of different colors or wavelengths of light.
D) the prism adds colors to different parts of the outgoing and broadly scattered beam.

A) demonstrated the wave nature of light by passing light through two slits and obtaining a pattern of bright and dark bands on a screen that he correctly interpreted as interference between the two light beams.
B) demonstrated that white light was made up of colors that could be split by a prism and that these colors were not produced by the glass through which the light passed.
C) proved mathematically that light could be described as oscillating electric and magnetic fields.
D) showed that a prism through which light passed added a spectrum of colors to the light.

A) 2.56 microseconds
B) 2.56 seconds
C) 1.28 seconds
D) 1.28 milliseconds

A) infinite, traveling through space instantaneously.
B) variable, depending on the speed of its source, but very large (on average, 3 × 10⁸ meters per second).
C) 3 × 10¹⁰ meters per second, independent of the speed of the source.
D) 3 × 10⁸ meters per second, independent of the speed of the source.

A) 5 hours
B) 8 minutes
C) 22 hours
D) 11 hours

A) Calculations from the Saturn data should produce a larger value for the speed of light.
B) Calculations from the Saturn data should produce a smaller value for the speed of light.
C) The times for the Saturn eclipses should show larger discrepancies from the predicted values, but the calculated speed of light should be the same.
D) The times for the Saturn eclipses should show smaller discrepancies from the predicted values, but the calculated speed of light should be the same.

A) X-rays and radio waves always come from different sources.
B) The wavelengths of X-rays and radio waves are very different.
C) The speeds of X-rays and radio waves in outer space are different.
D) Radio waves are always wavelike, whereas X-rays always behave like particles.

A) The dimensions of the solar system, particularly the length of 1 AU, were known only very inaccurately.
B) Telescopes were not good enough at that time to show Jupiter's moons clearly, and accurate timings were not therefore possible.
C) The distance between Earth's orbit and Jupiter's orbit was unknown.
D) The clocks available at that time were not sufficiently accurate.

A) 23 times the diameter
B) 23,077 times the diameter
C) 46 times the diameter
D) 0.043 times the diameter

A) timing eclipses of Jupiter's satellites by the planet, which appeared to occur later, when Earth was farther from Jupiter.
B) opening a shutter on a lantern on a hilltop and measuring the time taken for light from an assistant's shuttered lantern to return.
C) reflecting light from a mirror rotating at a known speed and measuring the angle of deflection of the light beam.
D) measuring how long it took the light to reach Earth from stars located at different distances from Earth.

A) 3 × 10¹⁰ m/sec.
B) 3 × 10⁸ m/sec.
C) 3 × 10¹² m/sec.
D) 3 × 10⁵ m/sec.

A) No time at all-it was Rømer himself who measured this speed accurately!
B) 28 years
C) almost 1000 years
D) more than a century but less than two centuries

A) 52 minutes
B) 35 minutes
C) 60 minutes
D) 43 minutes

A) ultraviolet
B) visible light
C) infrared
D) X-ray

A) He made an error in his experiment because such a speed is considered to be impossible by all previous experiments.
B) This "particle" must have been a photon or quantum of electromagnetic radiation of very high energy in order to have been traveling this fast.
C) This result is acceptable since atomic particles can travel this fast, whereas larger bodies are limited to 3 × 10⁵ m/s-¹.
D) This is an acceptable result for a particle originating from outer space because particle speed from such regions is unlimited.

A) All forms of light are electromagnetic radiation.
B) All forms of light have the same wavelength.
C) All forms of light are ultrasonic radiation.
D) All forms of light have wavelengths between 400 nm and 700 nm.

A) Rømer observed that eclipses of Jupiter's satellites by the planet appeared to occur later, when Earth was farther away from Jupiter, because of the travel time for light over the extra distance.
B) Rømer measured a time delay between the instant that he sent a flash of light to a mirror on a distant hill and the return of the flash after reflection.
C) Rømer carried out a laboratory experiment in which a light beam was sent through an opaque, rotating disk with holes in it and reflected from a distant mirror, where the returning beam did not return through the same hole from which it left because of the travel time for light.
D) Rømer measured a 2-second delay between the time of the outgoing pulse of light sent from Earth to the Moon and the time of the returning light pulse after reflection from the Moon.

A) energy
B) color
C) wavelength
D) speed

A) Wavelength increases from violet to yellow-green, then decreases again to red.
B) Wavelength decreases from violet to red.
C) Wavelength increases from violet to red.
D) Wavelength depends only on brightness and is independent of color.

A) zero time because light is transmitted instantaneously
B) 2.5 trillionths of a second (2.5 × 10-¹² sec)
C) 2.5 billionths of a second (2.5 nanoseconds)
D) 2.5 millionths of a second (2.5 microseconds)

A) Ole Rømer in 1675
B) Thomas Young in 1801
C) James Clerk Maxwell in 1864
D) Isaac Newton in 1704

A) The later times would still occur when Jupiter is at conjunction and the earlier times when Jupiter is at opposition.
B) The later times would occur when Jupiter is moving westward with respect to the stars and the earlier times when Jupiter is moving eastward with respect to the stars.
C) The later times would occur when Jupiter is moving eastward with respect to the stars and the earlier times when Jupiter is moving westward with respect to the stars.
D) Jupiter in this model is always the same distance from Earth, so no explanation is possible.

A) Newton.
B) Rømer.
C) Young.
D) Einstein.

A) The measured time discrepancy between predicted and measured values for a given eclipse would have been shorter for Saturn.
B) The measured time discrepancy between predicted and measured values for a given eclipse would have been the same for Saturn.
C) The measured time discrepancy between predicted and measured values for a given eclipse would have been longer for Saturn.
D) Rømer could not have made such a measurement because Saturn had not yet been discovered.

A) infrared
B) visible
C) ultraviolet
D) all of them since all electromagnetic photons have the same energy

A) slightly less than six months
B) exactly six months
C) slightly more than six months
D) almost six years

A) visible light, microwave, radio waves, infrared rays
B) radio waves, microwaves, gamma rays, UV radiation
C) visible light, UV radiation, X-rays, gamma rays
D) gamma rays, radio waves, X-rays, infrared rays

A) red
B) yellow
C) green
D) blue

A) The UV photon has 1/10 of the energy of the IR photon.
B) The UV photon has 10 times more energy than the IR photon.
C) The UV photon has 1/100 of the energy of the IR photon.
D) The UV photon has 100 times more energy than the IR photon.

A) The higher-energy photon has the shorter wavelength.
B) The higher-energy photon has the longer wavelength.
C) The two photons have the same wavelength; all photons have the same wavelength, regardless of energy.
D) We cannot say anything; wavelength depends only on color, not on energy.

A) have no wavelength limit, either short or long.
B) have no upper wavelength limit, but waves cannot exist with wavelengths smaller than an atom.
C) have no short wavelength limit, but waves cannot exist with wavelengths longer than about the diameter of Earth.
D) exist only over a wavelength range from infrared to ultraviolet radiation.

A) the wave theory is correct but the particle theory is not.
B) the particle theory is correct but the wave theory is not.
C) neither theory provides a correct description of light.
D) a combination of both theories is necessary to provide a correct description of light.

A) behaves only as a wave.
B) behaves only as a particle.
C) displays behavior of both waves and particles.
D) is completely different from both waves and particles.

A) 40 to 70.
B) 400 to 700.
C) 4000 to 7000.
D) 40,000 to 70,000.

A) red
B) yellow
C) green
D) blue

A) 10-⁶ m.
B) 10-³ m.
C) 10⁶ m.
D) 10-⁹ m.

A) change in the wavelength of peak emission of light when the source temperature changes.
B) increase in the observed wavelength of light if the source of light is moving away from you.
C) increase in the observed wavelength of light if the light source is moving toward you.
D) splitting of spectral lines into two or more wavelengths because the source of the light is in a strong magnetic field.

A) wavelength of the light is increased.
B) wavelength of the light is decreased.
C) intensity of the light is increased.
D) intensity of the light is decreased.

A) a very narrow range
B) two narrow but separate ranges between ultraviolet and infrared radiations, the red and the blue, which mix to give all the other colors
C) about half of the possible range
D) almost the full range between radio waves and X-rays

A) wavelength
B) frequency
C) intensity
D) color

A) All photons have the same energy, regardless of wavelength.
B) The 450-nm photon has the higher energy.
C) The 580-nm photon has the higher energy.
D) The photon from the higher-intensity light source has the higher energy (regardless of wavelength).

A) being in a high gravitational field.
B) being embedded in a cloud of dust and gas.
C) being in an intense magnetic field.
D) moving with respect to the observer.

A) different because X-rays are made up of waves, whereas light is made up of particles.
B) different because X-rays are made up of particles, whereas light is made up of waves.
C) the same thing except that X-rays have longer wavelengths than visible light.
D) the same thing except that X-rays have shorter wavelengths than visible light.

A) much faster than the speed of light
B) at the speed of light, 3 × 10⁸ m/s
C) much slower than the speed of light
D) slightly faster than the speed of light because their wavelength is longer

A) X-rays
B) ultraviolet radiation
C) infrared radiation
D) visible light

A) The time will be identical because both pulses travel at the speed of light.
B) The time will be just a little longer because the high-frequency UV radiation travels faster than the low-frequency radio waves.
C) The time will be much shorter because long-wavelength radiations travel faster.
D) The time will be much longer because radio waves have much longer wavelengths and therefore travel more slowly.

A) radio waves
B) ultraviolet radiation
C) infrared radiation
D) microwaves

A) longer than ultraviolet radiation but shorter than X-rays
B) longer than X-rays but shorter than gamma rays
C) longer than infrared radiation but shorter than radio waves
D) longer than X-rays but shorter than radio waves

A) X-rays
B) ultraviolet radiation
C) infrared radiation
D) gamma rays

A) have the shortest wavelengths of the named electromagnetic waves.
B) are intermediate, between X-rays and ultraviolet radiation.
C) are intermediate, between radio waves and infrared radiation.
D) have the longest wavelengths of the named electromagnetic waves.

A) gamma rays
B) infrared radiation
C) radio waves
D) visible light

A) gamma rays
B) seismic waves
C) microwaves
D) radio waves

A) violet light
B) X-rays
C) ultraviolet radiation
D) gamma rays

A) between radio waves and infrared radiation
B) between infrared and ultraviolet radiation
C) between infrared and microwave radiation
D) between ultraviolet radiation and X-rays

A) Visible light takes up only a very small part of the total range of wavelengths in the electromagnetic spectrum.
B) Visible light takes up the whole electromagnetic spectrum.
C) Visible light takes up most (but not all) of the total range of wavelengths in the electromagnetic spectrum.
D) Visible light is not part of the electromagnetic spectrum.

A) light, radio waves, X-rays, and gamma rays
B) Only light-all other electromagnetic waves travel slower than the speed of light.
C) light, atoms, X-rays, and subatomic particles (e.g., electrons)
D) light, infrared radiation, ultraviolet radiation, and subatomic particles (e.g., electrons)

A) gravitational wave
B) cosmic ray proton
C) microwave
D) sound wave

A) X-rays and visible light.
B) visible light and radio waves.
C) visible light and far-infrared radiation.
D) ultraviolet radiation and radio waves.

A) gamma rays, ultraviolet radiation, radio waves, infrared radiation
B) radio waves, ultraviolet radiation, infrared radiation, gamma rays
C) radio waves, infrared radiation, ultraviolet radiation, gamma rays
D) gamma rays, ultraviolet radiation, infrared radiation, radio waves

A) X-rays
B) radio waves
C) long infrared wavelengths
D) short ultraviolet wavelengths

A) visible light.
B) ultraviolet radiation.
C) infrared radiation.
D) a radio wave.

A) radio waves
B) infrared radiation
C) X-rays
D) visible light