Deck 9: Quantum Mechanics: How Can the Electron Behave Like Both a Particle and a Wave

A) experiments testing particle properties
B) experiments testing wave properties
C) double-slit tests
D) tests designed to "trick" the particles into revealing their identity
E) any or all of the experiments listed here would be a correct answer

A) camera light meters
B) fiber optics in some telephone audio systems
C) CAT scans
D) a battery operated flashlight
E) the standard X-ray machine in a small medical office

A) the energy of the object is much greater than the energy of the probe.
B) the energy of the probe is much greater than the energy of the object.
C) the probe and the object have equal amounts of energy.
D) the object moves slowly or not at all.
E) the object absorbs all the energy of the measuring device.

A) proving the existence of the nucleus of the atom.
B) which led to the modern concept of the photon.
C) developing the uncertainty principle.
D) with double-slit experiments.
E) disproving theories of quantum mechanics.

A) positions and velocities of objects when we first start observing them.
B) velocities and positions of objects after they have undergone a change.
C) the sum of an object's position and velocity.
D) the difference between an object's position and velocity.
E) when to start observing an object and how to make those observations.

A) < 66.3 X 10^-39 J-s/kg
B) > 6.63 X 10^-40 m/s
C) > 6.63 X 10^-39 m/s
D) < 6.63 X 10^-40 m/s
E) > 6.63 X 10^-38 m/s

A) try to determine whether an object is a particle or a wave.
B) measure the speed of alpha decay in a radioactive sample.
C) clock the speeds of subatomic particles shot through the slits.
D) find out whether photon emissions can be quantized.
E) try to "trick" quantum particles by varying experiment types.

A) light energy combines with battery energy
B) light energy is converted into electrical current that determines the opening in the lens.
C) light entering the lens is converted to an image on the film.
D) photons are used in an electrochemical process.
E) light energy is reflected by the material it strikes.

A) a CAT-scan does not subject the patient to X-rays.
B) photons are emitted during a CAT scan, but not during an X-ray.
C) only a CAT-scan can produce a three-dimensional image of the interior of the body.
D) only an X-ray can produce sharp images of organs with densities.
E) only a CAT-scan uses gamma rays.

A) is multiplied by Planck's constant.
B) is the subject of Einstein's research.
C) has attributes of a bundle.
D) cannot be seen without a microscope.
E) none of these

A) this is the way Ernest Rutherford interpreted his data.
B) energy levels must be divisible by Planck's constant
C) the velocity of a photon can be quantized.
D) the electron's distance from the nucleus has to satisfy a wave and particle duality.
E) objects in the quantum world behave only according to Newtonian principles.

A) smaller than Planck's constant divided by mass.
B) larger than Planck's constant divided by mass.
C) equal to Planck's constant divided by mass.
D) added to Planck's constant divided by mass.
E) larger than Planck's constant multiplied by mass.

A) distinguish waves from particles.
B) measure the amount of constructive and destructive interference in a wave tank.
C) establish the dual nature of quantum mechanics.
D) quantify how photons act under controlled conditions.
E) all of these

A) predicting future states
B) the Divine Calculator
C) clockwork precision
D) macroscopic
E) all of these

A) Descriptions of quantum objects are given in terms of probabilities.
B) Descriptions of quantum objects are stated with absolute certainty.
C) Descriptions of quantum objects can be given as a precise position and velocity.
D) Descriptions of quantum objects cannot be made at all.
E) Descriptions of quantum objects describe motion, while descriptions of everyday things never do.

A) only when a photon moves between energy levels and absorbs an electron.
B) only when an electron absorbs a photon and reaches a more excited state.
C) whenever an electron moves between energy levels and emits a photon.
D) only when an electron moves two or more energy levels at once.
E) whenever a photon moves more than one energy level at once and emits an electron.

A) The uncertainty principle has been refuted by new evidence.
B) Objects we normally encounter have mass in amounts that make the effects of the uncertainty principle practically non-existent.
C) Planck's constant has been revised to apply to the macroscopic world as well as the atomic world.
D) There is too much uncertainty in the uncertainty principle to give it much thought.
E) The future is determined by a Divine Calculator.

A) Newtonian laws are incontrovertible.
B) the quantum world spins clockwise.
C) there must be an anti-quantum universe.
D) in the quantum world, prediction of the future is a probability.
E) the long-term evolution of physical systems can be predicted.

A) they can move according to Bohr's laws of motion.
B) they must have a precise frequency to stay in a stable orbit.
C) they must have a precise velocity to stay in a stable orbit.
D) they create interference patterns in the dual slit experiment.
E) all of these

A) significant.
B) disconcerting.
C) near zero.
D) to equal Planck's constant.
E) to agree with Maxwell's equations.

A) the Heisenberg
B) uncertainty in position
C) uncertainty in velocity
D) Planck's constant
E) the duality

A) quantum
B) quantum leap
C) quantum mechanics
D) quantum bundle
E) quantum world

A) 1
B) 2
C) 3
D) 1 and 3
E) 1, 2 and 3

A) quantum leap
B) quantum eavesdropper
C) quantum teleportation
D) quantum interception
E) quantum uncertainty