Deck 28: The Structure of Space and Time

A)an extremely rapid expansion of the early universe that occurred in an extremely brief period of time.
B)the fact that there is an ever increasing energy cost in order for fusion within stars to occur.
C)the phenomenon of matter within the universe is becoming increasingly disordered.
D)is another way of referring to the Big Bang itself.

A)it takes more energy to create a neutron from a proton than a proton from a neutron.
B)it takes more energy to create a proton from a neutron than a neutron from a proton.
C)the more massive neutrons made better targets for nucleon collisions.
D)the positively charged protons were repelled away from the explosion.

A)this temperature uniformity was achieved in the moments before cosmic inflation.
B)as the universe has had time to cool, the hotter parts transferred their heat to the cooler regions.
C)microwaves can only function at a certain very limited range of temperature.
D)space is a vacuum and thus cannot retain heat very well.

A)faster it is receding from us.
B)more massive it is.
C)more energetic it is.
D)more black holes it contains.

A)uniformly distributed residual radiation that resulted from the Big Bang.
B)pockets of radiation found in certain quadrants of the observable universe.
C)the radiation emitted from galactic nuclei.
D)redshifted microwave radiation being emitted from the center of the universe.

A)the expansion of space itself.
B)the expansion of galaxies.
C)the expansion of red giants.
D)the tendency of light to expand when free of gravitational influences.

A)days.
B)months.
C)year.
D)decades.

A)about 14 billion years ago.
B)at the beginning of time.
C)both of these
D)neither of these

A)a distant star.
B)our physics book.
C)actually, both of these
D)none of these

A)took place within space.
B)marked the beginning of space and time.
C)occurred as a result of disturbances within the Large Magellenic cloud.
D)took place within time.

A)when approaching, lightwaves have higher frequency; when receding their frequency is lower.
B)when approaching, lightwaves have lower frequency; when receding their frequency is higher.
C)the frequency of approaching lightwaves remain constant, while receding lightwaves are invisible.
D)There is no difference

A)14 billion years.
B)7 billion years.
C)21 billion years.
D)6,000 years.

A)never converge.
B)are concentric to each other.
C)are mirror images.
D)eventually meet.

A)at which is receding.
B)at which it is approaching.
C)at which it is spinning.
D)of its fusion.

A)at the tip of your nose.
B)at the center of each galaxy.
C)at some undetermined yet vastly distant point.
D)within an unusually large supernova.

A)Inflation magnified ultrasmall quantum variations in position and momenta.
B)There is evidence of a second, slightly smaller Big Bang that took place very shortly after the initial Big Bang, which would account for the variation in structure.
C)The rapidly cooling universe created massive quantities of hydrogen, and then helium, which interacted with each other to create regions of relative structure.
D)Entropy immediately came into effect, slowing down some areas of expansion, while increasing others.

A)the universe.
B)stars.
C)beauty.
D)galaxies.

A)point in time in which the known (and perhaps knowable)universe came into being.
B)phenomenon of rapid chain reaction supernovae during the first 100 seconds of the universe.
C)time when our Sun will become a nova, rendering Earth into molten lava.
D)end of the universe when simultaneous supernovae will transform the universe into a supergiant black hole.

A)By measuring the rate of expansion of the universe
B)By looking at the age of the oldest stars
C)By measuring the redshift of stars within 360 degrees of the center of our galaxy
D)By measuring the rate of radioactive decay within the farthest galaxies

A)The space through which the light passes is curved.
B)Photons actually have a very small mass, so gravity does have an effect on them.
C)When light interacts with particles, it loses some energy, and thus takes on some mass.
D)Gravity has no effect on light.

A)curved.
B)flat.
C)the shape of a saddle.
D)has yet to be determined, although most astrophysical data points to a flat universe.

A)slows a clock.
B)speeds up a clock.
C)has no effect on the speed of a clock.

A)faster than a person on the top floor.
B)slower than a person on the top floor.
C)at the same speed as a person on the top floor.

A)bound together.
B)independent entities.

A)slower.
B)faster.
C)the same.

A)less than 20 pushups.
B)20 pushups.
C)more than 20 pushups.

A)acceleration.
B)gravitation.
C)space-time geometry.
D)all of these
E)none of these

A)speed up.
B)slow down.
C)fluctuate.
D)Gravity has no measurable effect on time.

A)effect we witness when a large mass causes a curvature in the shape of spacetime.
B)force of attraction that exists between two objects.
C)effects of the graviton particle.
D)curvature of space caused by objects reaching the speed of light.

A)slower.
B)faster.
C)no difference

A)curves per second the same as the cannonball.
B)follows a straight-line path with no curvature at all.
C)curves half as much as the cannonball.
D)curves slightly, but not as much per second as the cannonball.

A)Spacetime around the Sun would become flatter, and the Earth, with its current momentum, would exit its orbit around the Sun.
B)Spacetime around the Sun would become less flat, and the Earth would go plunging into the Sun.
C)The Earth's orbital distance from the Sun would increase correspondingly.
D)The Earth's orbital distance from the Sun would decrease correspondingly

A)mass.
B)the force of gravity.
C)quantum fluctuations.
D)the vacuum force.

A)the universe is so unbelievably large.
B)mass has the effect of balancing the natural curvature of space-time.
C)space is inherently flat.
D)the universe is so very old.

A)when the elliptical orbits of planets slip forward with each revolution.
B)the process of planetary evolution.
C)the stage before planets stabilize into a stationary orbit.
D)the wobbling of a planet's axis of rotation.

A)study of how space, energy, and mass are related to time.
B)concept that there are no absolutes that can be postulated.
C)idea that space bends in relationship to the square of the mass contained within it.
D)study of wormholes and time travel.

A)equivalence.
B)equality.
C)equanimity.
D)interchangeability.

A)much less than 4.9 m.
B)about 4.9 m.
C)much more than 4.9 m.

A)mass density.
B)energy density.
C)thermal mass.
D)thermal mass fluctuations.

A)accelerating influence of dark energy, causing all matter to become completely ripped apart.
B)phenomenon of dark energy causing the universe to rip into multiple spacetimes.
C)possibility that galactic centers may suddenly implode causing galactic disintegration.
D)phenomenon of dark energy decelerating, causing all matter to disintegrate.

A)passes a massive star.
B)passes through a gravitational field.
C)both of these
D)neither of these

A)within the central supermassive black hole.
B)within the luminescent spiral arms.
C)outside of the luminescent spiral arms.
D)in the form of dark energy.

A)wave frequency.
B)wavelength.
C)both of these
D)neither of these

A)reaching the lowest energy state possible, which will mean the greatest level of entropy.
B)ending after a massive fire.
C)reaching a state where all stars expand and merge into each other.
D)reaching the point where the process of radioactive decay is no longer possible.

A)Mercury moves in the gravitational field of the other planets.
B)Mercury travels faster than any other planet.
C)Mercury is closest to the Sun.
D)the Sun's gravitational field varies along Mercury's orbit.
E)none of these

A)relatively similar speeds at which all stars in a galaxy orbit the galactic nucleus.
B)speed at which galaxies orbit one another within clusters.
C)degree to which galaxy clusters exhibit gravitational lensing effects.
D)All of the above

A)in the exact same fashion as gravity.
B)in the opposite manner of gravity.
C)by absorbing all lightwaves that pass through it.
D)Dark energy does not bend the curvature of spacetime.

A)cannot be seen, felt, or measured.
B)cannot be seen or felt, but can be measured through its gravitational effects.
C)is Dark Energy's complement.
D)is found within a black hole.

A)the possibility that our universe is only a patch of a greater universe and that the process of universe spawning will continue forever.
B)the observation that cosmic inflation could eventually curve back in on itself, causing its opposite: the compression of space.
C)cosmic inflation inflating itself such that its own inflation is self-generating.
D)the presence of a distinct beginning of time.

A)larger than it is now.
B)smaller than it is now.
C)the same as it is now.
D)zero.

A)are near a black hole.
B)are near a very large gravitational field.
C)travel at nearly the speed of light.
D)you can never grow younger.
E)none of these

A)larger than it is now.
B)smaller than it is now.
C)the same as it is now.
D)nonexistent.

A)is the phenomenon responsible for the acceleration of the universe.
B)would be considered to be the opposite of gravity.
C)is energy that exerts an outward pressure, causing spacetime to expand.
D)All of the above

A)growing closer to each other as they encounter the curvature of the universe.
B)accelerating away from each other.
C)slowing in their dispersal due to the effects of gravity.
D)connected to each other by dark energy.