Deck 4: Spectroscopy: The Inner Workings of Atoms

A) Newton.
B) Fraunhofer.
C) Kirchhoff.
D) Bohr.
E) Einstein.

A) protons.
B) neutrons.
C) positrons.
D) electrons.
E) mesons.

A) an analysis of the way in which atoms absorb and emit light
B) a study of the geometry of rainbows
C) an observational technique to measure the brightness of light at different colors
D) the use of CCDs to capture light more efficiently than with photographic film
E) a method to freeze atmospheric turbulence for better resolution

A) a series of bright, colored lines.
B) an unbroken rainbow of colors.
C) a rainbow, but with some dark lines mixed in.
D) a rainbow with some bright lines on top of the continuum.
E) a very redshifted rainbow due to the expansion of the universe.

A) proton.
B) electron.
C) neutron.
D) atom.
E) neutrino.

A) Kirchhoff.
B) Bohr.
C) Fraunhofer.
D) Newton.
E) Mendeleev.

A) a continuum, strongest in the color red.
B) a few bright lines against a dark background.
C) a few dark lines in the continuum.
D) a continuum, but with both bright and dark lines mixed in.
E) not in the visible portion of the spectrum.

A) proton.
B) ion.
C) neutrino.
D) neutron.
E) lepton.

A) positron.
B) proton.
C) neutron.
D) neutrino.
E) alpha particle.

A) a continuous spectrum, with the peak giving the temperature of the filament.
B) an emission spectrum, with bright lines due to ionized tungsten.
C) an absorption spectrum, with dark lines due to the solid filament.
D) a continuum, with bright tungsten lines added.
E) a continuum, with dark lines of tungsten and argon as well.

A) positrons
B) electrons
C) protons
D) neutrons
E) neutrinos

A) hydrogen.
B) helium.
C) solarium.
D) technetium.
E) aluminum.

A) radio
B) infrared
C) visible
D) ultraviolet
E) X-ray

A) radio
B) infrared
C) visible
D) ultraviolet
E) X-ray

A) emission lines from hot gases in the chromosphere of the Sun.
B) emission sections of the continuous spectrum of the photosphere.
C) Zeeman lines around sunspots due to their strong magnetic fields.
D) absorption lines due to the thin outer layer above the photosphere.
E) redshifted lines due to the Sun's rotation.

A) a continuous spectrum, since the neon is hot enough to glow.
B) a few bright emission lines, telling us the gas is neon.
C) a continuum, with dark lines identifying the neon atoms that are present.
D) a lot of random bright red lines due to the motion of the hot atoms.
E) nothing visible to us, but a lot of infrared lines as heat.

A) sunlight
B) a rainbow
C) a neon light
D) a fluorescent light
E) a glowing nebula, such as M-42

A) density of the hot medium.
B) thermal motion of the hot atoms.
C) rotation of the star.
D) magnetic fields of the star.
E) All of the above

A) only make transitions between orbitals of specific energies.
B) are not confined to specific orbits.
C) are spread uniformly through a large, positive mass.
D) can be halfway between orbits.
E) move from orbit to orbit in many small steps.

A) 10.2 eV.
B) 12.1 eV.
C) 12.75 eV.
D) 13.1 eV.
E) 13.6 eV.

A) Molecules have two or more atoms.
B) Molecules can vibrate and rotate as well.
C) Molecules are heavier than atoms.
D) Molecules are the basis of life.
E) Most of the universe is made of molecules, not individual atoms.

A) their rapid rotation.
B) temperature variations.
C) their magnetic fields.
D) their radial velocity.
E) a Doppler shift.

A) blue shifted by 1%.
B) redshifted by 1%.
C) not affected, as c is constant regardless of the direction of motion.
D) blue shifted out of the visible spectrum into the ultraviolet.
E) redshifted out of the visible into the infrared.

A) visible light spectrometers.
B) radio or microwave telescopes.
C) high energy observatories like Chandra, in orbit above our atmosphere.
D) ultraviolet balloons flying above the ozone layer.
E) infrared telescopes on mountaintops.

A) have a high intensity.
B) have a low intensity.
C) have a long wavelength.
D) have a short wavelength.
E) None of the above.

A) Doppler effect.
B) Second Law of Kirchhoff.
C) Zeeman effect.
D) photoelectric effect.
E) polarization of sunlight.

A) 0.7 eV.
B) 1.9 eV.
C) 2.6 eV.
D) 2.9 eV.
E) 3.4 eV.

A) fingerprints also consist of individual lines that make a pattern.
B) both are unique to their source.
C) both can be easily categorized.
D) both are characteristic of the individual that produced them.
E) All of these are correct.

A) Because of the larger number of electrons and corresponding energy levels, more transitions are possible.
B) Because of the larger number of electrons, there are many ionization levels possible.
C) Because of the larger number protons, the amount of force holding the electrons to the atom can vary between different iron atoms.
D) Because of the atom's larger size, it will be hit by more photons in a beam of light.

A) level 2 to level 3.
B) level 2 to level 4.
C) level 3 to level 2.
D) level 4 to level 2.
E) None of the above.

A) 10.2 eV.
B) 12.1 eV.
C) 12.75 eV.
D) 13.1 eV.
E) 13.6 eV.

A) a red emission line.
B) a blue green absorption line.
C) a violet emission line.
D) an infrared emission line.
E) an ultraviolet absorption line.

A) This is an example of the photoelectric effect.
B) This is an example of the Doppler effect.
C) The second law of Kirchhoff explains this.
D) The star is not rotating.
E) The star has a radial velocity towards us.

A) protons escaping from the nuclei of atoms at tremendous temperatures.
B) electrons being stripped off the outer electron shell for hot atoms.
C) positrons being added to the atomic nucleus at great energies.
D) positrons being added to the electron clouds, destroying the electrons.
E) electrons being added to the cloud, giving them a surplus over protons.

A) taken away a proton from the nucleus.
B) added a positron to the nucleus.
C) added a positron to the outer electron shell.
D) added an electron to the outer electron shell.
E) None of these; only positive ions can exist in nature.

A) a red emission line.
B) a blue green absorption line.
C) a violet emission line.
D) an infrared emission line.
E) an ultraviolet absorption line.

A) any level to level 2.
B) level 2 to any level.
C) any level to level 1.
D) level 1 to any level.
E) any level to level 3.

A) the source is approaching us at 1 % of the speed of light.
B) the source is approaching us at 0.1 % of the speed of light.
C) the source is receding from us at 10% of the speed of light.
D) the source is getting 1% hotter as we watch.
E) the source is spinning very rapidly, at 1% of the speed of light.

A) its temperature
B) its radial motion
C) its chemical composition
D) whether it has a strong magnetic field
E) All of the above