Deck 5: Radiation and Spectra

A) a charged particle in the nucleus of every atom
B) a kind of magnetic substance found in reflective minerals
C) a self-contained "packet" of electro-magnetic energy
D) a kind of sound that is too high frequency for the human ear to hear
E) you can't fool me. Einstein showed that photons were a mistake - they don't exist.

A) Albert Einstein
B) James Clerk Maxwell
C) Isaac Newton
D) Wilhelm Wien
E) Ludwig Boltzmann

A) yellow-green
B) blue
C) violet
D) red
E) black

A) radio waves
B) visible light waves
C) ultraviolet waves
D) x-rays
E) you can't fool me, all these have the same wavelength

A) x-rays
B) gamma rays
C) infrared waves
D) ultraviolet waves
E) radio waves of the wavelength that carry FM broadcasts

A) the nucleus has an overall positive charge
B) the nucleus takes up a very small amount of space compared to the entire atom
C) the nucleus contains both protons and neutrons
D) the nucleus repels the electrons which move around it
E) the nucleus contains most of the mass of the atom

A) it has a frequency very close to the highest possible frequency for electromagnetic waves
B) it traveled between the transmitter and your radio's antenna at the speed of sound
C) its wavelength is much longer than the wavelength of the light you see reflected from the page of this exam
D) the wave was originally produced by electrons that were not moving (at rest) inside the transmitter
E) the reason that it could reach your radio is because all of space is filled with a medium called the aether in which electromagnetic waves can vibrate

A) the speed of sound
B) the speed of light
C) the speed of electron oscillations
D) the speed with which Mercury orbits the Sun
E) the speed with which weekends seem to pass

A) photons always travel at the speed of light
B) photons each carry a specific amount of energy
C) a photon of visible light cannot pass through the atmosphere of the Earth, and thus cannot be seen at the Earth's surface
D) high energy photons have a high frequency (when thought of as waves)
E) a gamma-ray photon carries more energy than a visible light photon

A) at the speed of sound
B) at the speed of light
C) at the speed of charge
D) at different speeds, depending on the temperature of the atoms that produce them
E) they always have zero speed

A) it is the band of the electromagnetic spectrum with the lowest possible energy and thus easiest to detect
B) it is the only band of the spectrum that can travel through a vacuum
C) it is the band of the spectrum which is the least Doppler shifted coming from the Sun
D) it is a band of the spectrum where the Sun puts out a great deal of energy
E) it is the band of the spectrum where the warm Earth glows the most effectively at night

A) it is the band of the electromagnetic spectrum where each wave or photon has the greatest energy
B) it was first discovered in 1800 in an experiment using sunlight and thermometers
C) unlike light, infrared can never travel as fast as the speed of light
D) while many stars give off infrared, there is nothing on Earth at the right temperature to emit it
E) it is the radiation responsible for giving sunburns (or in large doses, skin cancer)

A) frequency
B) velocity
C) wavelength
D) amplitude
E) you can't fool me; in these waves, the distance between crests is zero

A) increase with distance
B) remain the same
C) decrease as the distance squared
D) change more and more in color (becoming redder)
E) this can't be answered without having more information

A) the ozone layer
B) the ionosphere
C) the region between the Earth and the Sun
D) stratosphere
E) tanning zone

A) it always spreads out at the speed of light
B) it is given off by all objects that are not at a temperature of absolute zero
C) it is typically produced when charged particles oscillate
D) different waves of electromagnetic radiation differ in their wavelength or frequency
E) the radiation consists of tiny charged particles given off by the nuclei of atoms

A) visible light
B) gamma rays
C) radio waves
D) ultraviolet waves
E) you can't fool me, all these have the same frequency

A) a unit of wavelength
B) a unit of frequency
C) a unit of velocity
D) a unit of loudness
E) a well-known car-rental company

A) visible light
B) radio waves
C) infrared
D) x-rays
E) you can't fool me, all of these travel through space at the same speed

A) Solarium
B) Hydrogen
C) Einsteinium
D) Helium
E) Astronomium
Section 5.4: The Structure of the Atom

A) give off more radiation at all wavelengths
B) will have a higher average frequency of radiation
C) will radiate energy at more than one wavelength
D) will give off a continuous spectrum of waves
E) all of the above

A) their mass
B) their temperature
C) their distance from the Earth's center
D) their chemical makeup
E) their size

A) visible light
B) infra-red
C) ultra-violet
D) black light
E) no telescope will be effective if I am in a dark room

A) twice as much energy as the second
B) roughly the same amount of energy as the second
C) half as much energy as the second
D) about 16 times the energy of the second
E) this problem cannot be solved with just the information we were given

A) microwaves
B) radar waves
C) the waves that carry AM or FM broadcasts
D) the sound waves coming from your transistor radio
E) the waves that carry television transmissions

A) is dispersed into different colors
B) is reflected backwards
C) is refracted (bent)
D) is Doppler shifted
E) more than one of the above

A) a Doppler surface
B) an electromagnetic radiator
C) a blackbody
D) a spectrum
E) a vice president

A) It has dark lines in it that allow astronomers to determine what elements are in the star
B) It has bright lines in it which allow astronomers to determine how bright the star is
C) It helped astronomers to understand the rainbows we see on Earth after storms
D) It shows that the stars are transparent; we can see right through them
E) An absorption spectrum is not useful to astronomers at all. When they see one, it means they cannot learn anything about the stars that produced the annoying absorption.

A) heat
B) the Doppler shift
C) spectroscopy
D) reflection
E) rock and roll

A) the two stars have the same total energy flux (luminosity)
B) star B has twice the energy flux (luminosity) that star A has
C) star B has one half the energy flux (luminosity) that star A has
D) star B has 16 times the energy flux (luminosity) that star A has
E) Sorry, professor, we don't have enough information to compare the energy flux (luminosity) of the two stars
Section 5.3: Spectroscopy in Astronomy

A) Yes, because all radio waves do travel at the speed of light and all of them escape from the Earth
B) No, because radio waves travel much slower than the speed of light and will take a very long time to get anywhere
C) No, because radio waves are all absorbed by the ozone layer in the Earth's atmosphere
D) No, because AM radio waves are bounced back or scattered by the ionosphere and don't get into space
E) Yes, because while all radio waves do not escape from the Earth, AM radio waves do

A) a continuous spectrum
B) an absorption spectrum
C) an emission spectrum
D) a Doppler shift
E) all of the above

A) overall color
B) temperature
C) wavelength where maximum energy is emitted
D) atomic ground state
E) none of the above

A) a cube of ice
B) a cube of water
C) a cube of steam
D) a cube of air (on Earth)
E) a cube of the Sun

A) measuring the Doppler shift of its spectral lines
B) making a blackbody curve and finding the wavelength of the peak (maximum)
C) measuring the intensity of radio waves the star gives off
D) measuring how much light the star reflects
E) sending a graduate student with a very long (and durable) thermometer to the star's vicinity

A) a beam of green light
B) TV transmissions bringing us Monday night football
C) the sound of the instructor's voice
D) the waves of a dental x-ray
E) the rays that tan a sunbather on the beach

A) visible light
B) x-rays
C) radar waves
D) ultra-violet
E) none would work

A) motion toward us or away from us
B) overall color
C) magnetic field
D) temperature
E) none of the above

A) a continuous spectrum
B) an absorption spectrum
C) an emission spectrum
D) a Doppler shift
E) more than one of the above

A) the negative and positive charges were all spread out throughout the volume of each atom
B) that the absorption spectrum of gold atoms had more lines than scientists could explain
C) that alpha particles were neutral (demonstrating the existence of neutrons)
D) that the nucleus of an atom was tiny compared to the size of the whole atom
E) it was far better to use cheaper materials than gold for physics experiments

A) some atoms don't have any isotopes
B) each type of atom contains different numbers of neutrons
C) each type of atom shows different absorption or emission spectra
D) most atoms don't have a ground state
E) astronomers have not been able to figure out what atoms stars are made of

A) look at what color light dominates its continuous spectrum
B) listen for coded signals in the radio waves it gives off in the FM band
C) look at the absorption lines in its spectrum
D) send spacecraft like Voyager to examine its make-up from close-up
E) compare visible-light photographs of the star (taken with large telescopes) to those of the Sun.

A) the cloud is much hotter than hydrogen on Earth
B) the cloud is much cooler than hydrogen on Earth
C) the cloud is moving toward us
D) the cloud is moving away from us
E) none of the above can be concluded from this observation.

A) It helped Rutherford explain the workings of the atomic nucleus
B) Balmer's experiments with these lines helped prove Wien's Law
C) When electrons change levels to produce the Balmer series, the emitted light is in the visible part of the spectrum, so the lines were easy to see with our eyes
D) The Balmer series of lines can only be observed from outer space; so the competition to see these lines led to the space race
E) Mr. Balmer never got the Nobel prize, which made everyone in the field of spectroscopy so angry, they worked extra hard

A) the wavelengths of the Balmer lines of hydrogen
B) the intensity of the red and blue light from the same star
C) the changes in the radar gun used by his local police officers when they pointed at speeding cars
D) the changes in the colors of a rainbow when the clouds were moving fast
E) the properties of sound waves coming from a group of musicians on a moving, open railroad car

A) helium
B) hydrogen
C) uranium
D) carbon
E) silicon

A) give off a photon of energy
B) lose its electric charge
C) absorb a photon of energy
D) wait until the atom has changed into another atom with more protons
E) get a permission slip from Niels Bohr

A) red-shifted (shifted toward the red end of the light spectrum)
B) blue-shifted (shifted toward the blue or violet end of the light spectrum)
C) yellow-shifted (shifted so all the colors become a little bit yellower)
D) become darker and darker (like a blackbody)
E) you can't fool me, the Doppler effect only applies to motions on Earth, not to the motions of the stars and galaxies

A) ionized
B) excited
C) in its ground state
D) red shifted
E) over the hill

A) J. J. Thomson
B) Niels Bohr
C) Ernest Rutherford
D) Albert Einstein
E) Christian Doppler

A) the energy of a wave to the number of protons in the nucleus of the atom that emitted it
B) the frequency of a wave to its energy (when thought of as a photon)
C) the maximum energy emitted by a blackbody to its temperature
D) the energy emitted by a star to its temperature
E) the Doppler shift of a light source to its speed
Section 5.5: Formation of Spectral Lines

A) all elements have the same lines, but they are Doppler shifted by different amounts
B) in some elements, electrons can only move to odd numbered levels, in others only to even numbered ones
C) in heavier elements, diffraction spreads out the lines that the atom produces, making the colors different
D) because the spacing of the energy levels is different in different atoms
E) because some atoms do not have a ground state, while others have three or four

A) molecules
B) electron pairs
C) isotopes
D) ions
E) re-runs

A) as big as the entire stadium (and very thinly spread out)
B) as big as the space filled by all the negative charges (that's why the atom is neutral)
C) very small (perhaps the size of a soccer ball) and in the middle
D) an extremely thin layer spread completely around the outer walls of the stadium
E) this question cannot be answered (even roughly) without knowing how many electrons the atom has

A) a photon is given off
B) the color of the wave involved shifts to the red
C) a photon is absorbed
D) another electron from the lower level takes its place
E) nothing happens; electrons can only go from a lower level to a higher level

A) the electron orbit with the lowest possible amount of energy
B) a place in the atom where the electric charge cancels out
C) the energy level from which it is most easy for an electron to escape
D) when the atoms has been ripped apart into the particles that made it up
E) the state an electron is in when it has absorbed three or more different photons

A) have only protons, no neutrons at all
B) soon be used in industry to make new kinds of plastics
C) have one of the smallest nuclei known
D) only remain stable for an extremely small fraction of a second
E) eventually be found in the Sun (with very high quality spectrometers)

A) send an electron from the ground state to an excited state
B) have all the electrons in the atom drop down to the lowest available orbits
C) add more neutrons to its nucleus
D) remove one or more electrons from the atom
E) send the atom to Bayonne, New Jersey
Section 5.6: The Doppler Effect