Deck 9: The Atom

A) is less than the speed of light.
B) is equal to the speed of light.
C) is greater than the speed of light.
D) Any of these choices could be correct, depending on its frequency.

A) associated with all particles.
B) never associated with stationary particles.
C) never associated with charged particles.
D) never associated with uncharged particles.

A) less than the speed of light.
B) equal to the speed of light.
C) greater than the speed of light.
D) Any of these choices could be correct, depending on the frequency.

A) are called photons.
B) have random energies.
C) have energies that depend upon the intensity of the light.
D) have energies that depend upon the frequency of the light.

A) longer its wavelength.
B) higher its speed.
C) more precisely its position can be determined.
D) more precisely its momentum can be determined.

A) The electron has less energy than the photon energy of the gamma ray.
B) The electron has the same energy as the photon energy of the gamma ray.
C) The electron has more energy than the photon energy of the gamma ray.
D) Any of these choices could be correct, depending on the wavelength.

A) electromagnetic waves of very short wavelength.
B) electromagnetic waves of very long wavelength.
C) matter waves of very short wavelength.
D) matter waves of very long wavelength.

A) The electron has the higher speed.
B) The proton has the higher speed.
C) They have the same speed.
D) Any of the choices is true, depending on the wavelength.

A) are the same for all elements.
B) are random.
C) are different for each element.
D) are different in the emission and absorption spectra of an element.

A) frequency.
B) wavelength.
C) speed.
D) charge.

A) moving bodies would have longer wavelengths.
B) moving bodies would have lower speeds.
C) the uncertainty principle would be less significant.
D) photons would have higher energies.

A) the ball is uncharged.
B) the matter waves are moving too fast.
C) the frequency of the matter waves is too low.
D) the wavelength of the matter waves is too short.

A) interference
B) blackbody radiation
C) the photoelectric effect
D) X-ray production

A) frequency of the light.
B) wavelength of the light.
C) intensity of the light.
D) speed of the light.

A) Under the same circumstances, black objects emit the least radiation.
B) The higher an object's temperature, the longer the predominant wavelength of its radiation.
C) The higher an object's temperature, the more radiation it emits.
D) The higher an object's temperature, the higher the speed of the radiation it emits.

A) no charge.
B) charges smaller than ±e, like quarks.
C) charges of ±e.
D) charges whose magnitudes depends on their speeds.

A) wavelength.
B) speed.
C) energy.
D) number.

A) theory and experiment agree.
B) it is in accord with common sense.
C) it was revealed to Einstein in a dream.
D) photons have actually been seen.

A) only the position of a particle.
B) only the momentum of a particle.
C) either the position or the momentum of a particle.
D) both the position and the momentum of a particle.

A) have no magnetic properties.
B) have the same magnetic behavior as particles of iron.
C) behave like tiny bar magnets of different strengths.
D) behave like tiny bar magnets of the same strength.

A) 1.
B) 2.
C) 3.
D) 4.

A) 10^-8 s.
B) 1 s.
C) 10 s.
D) 1 min.

A) decreases with increasing quantum numbers.
B) increases with increasing quantum numbers.
C) is the same for all quantum numbers.
D) shows no regularities.

A) the region around the nucleus in which it is most likely to be found.
B) the path it follows around the nucleus.
C) its de Broglie wave.
D) its angular momentum.

A) atoms can contain electrons.
B) atomic electrons are in motion.
C) atoms can emit electromagnetic waves.
D) atoms can be stable.

A) 1.
B) 2.
C) 3.
D) 4.

A) is a hot object surrounded by a hot atmosphere.
B) is a hot object surrounded by a cool temperature.
C) is a cool object surrounded by a hot temperature.
D) is a cool object surrounded by a cool atmosphere.

A) 1.
B) 2.
C) always equal to n, the principal quantum number.
D) always equal to 2n.

A) leaves the atom.
B) collides with another of its electrons.
C) shifts to a lower energy level.
D) shifts to a higher energy level.

A) have different wavelengths.
B) have different speeds.
C) are in step with one another.
D) spread out to form a wide beam.

A) is 0.
B) is 1.
C) depends on the orbit size.
D) depends on the electron speed.

A) Bohr principle.
B) de Broglie principle.
C) exclusion principle.
D) uncertainty principle.

A) coherent.
B) incoherent.
C) quantized.
D) diffracted.

A) 0.
B) 1.
C) 2.
D) 3.

A) the de Broglie wavelength of its electron equals its orbit diameter.
B) the de Broglie wavelength of its electron equals its orbit circumference.
C) its electron has left the atom.
D) its electron is at rest.

A) lines are evenly spaced.
B) excited electrons all started from the same energy level.
C) excited electrons all return to the same energy level.
D) excited electrons leave the atoms.

A) only one electron.
B) two electrons with spins in the same direction.
C) two electrons with spins in opposite directions.
D) any number of electrons.

A) a line spectrum.
B) an emission spectrum.
C) an absorption spectrum.
D) photons.

A) gamma rays.
B) x-rays.
C) ultraviolet light.
D) infrared light.

A) 6.6 × 10^-24 m/s.
B) 3.8 × 10³ m/s.
C) 7.3 × 10⁶ m/s.
D) 10¹⁰ m/s.

A) is spherical in shape.
B) is shaped like a doughnut.
C) has two lobes.
D) has six lobes.

A) 5.9 × 10^-56 m.
B) 1.5 × 10^-19 m.
C) 7.3 × 10^-12 m.
D) 1.4 × 10¹¹ m.

A) 4.4 × 10^-48 Hz.
B) 10^-19 Hz.
C) 10¹⁵ Hz.
D) 10¹⁹ Hz.

A) 1.1 × 10^-48 J.
B) 1.3 × 10^-27 J.
C) 4 × 10^-19 J.
D) 1.7 × 10^-15 J.