Deck 26: Exploring the Early Universe

A)immediately, as they were a direct product of the Big Bang
B)about 380,000 years later
C)about 400 million years later
D)not until about 3.2 billion years later

A)why is the sky dark at night?
B)why was the density of the universe so close to the critical density just after the Big Bang?
C)why are the four forces (strong, weak, electromagnetic, and gravitational) not unified in the present-day universe?
D)why is the temperature of the cosmic background radiation so smooth (isotropic) around the sky?

A)Observations of the distant universe indicate that the universe is at least moderately flat, yet matter creates lumps in the geometry of spacetime. Therefore it is hard to account for the observed flatness.
B)The density of the universe must have been equal to the critical density to a precision of 50 decimal places in order for us to see the universe we see today. This astounding flatness is hard to account for.
C)The universe appears to have a hyperbolic geometry to within observational error, yet the universe is expanding, and expanding universes have to be flat.
D)The universe appears to be flat to within observational error, yet the universe is expanding, and it is impossible for an expanding universe to be flat.

A)The universe would have expanded very rapidly, and matter would not have clumped together to form galaxies.
B)The universe's mass would have clumped together in a relatively short time and collapsed to a singularity like that from which it emerged.
C)Cosmic inflation would not have occurred.
D)The cosmic microwave background radiation would not have been created.

A)The universe would have expanded very rapidly, and matter would not have clumped together to form galaxies.
B)The universe's mass would have clumped together in a relatively short time and collapsed to a singularity like that from which it emerged.
C)Cosmic inflation would not have occurred.
D)The cosmic microwave background radiation would not have been created.

A)during the Planck time-that is, during the first 10^-43 seconds after the cosmological singularity
B)immediately after the Planck time
C)throughout the first 3 minutes
D)throughout the first 380,000 years

A)It took whatever curvature the early universe had and flattened it.
B)The epoch allowed the early, preinflationary universe to be very small and thus capable of thermal equalization.
C)It permitted matter to move faster than the speed of light for a brief period.
D)It forced the observed density of the universe to be equal to the critical density to great precision.

A)No, unfortunately there is no direct test for inflation.
B)Yes, the temperature of the cosmic microwave background provides a test of cosmic inflation.
C)Yes, the uniformity of the cosmic microwave background provides a test of cosmic inflation.
D)Yes, the polarization of the cosmic microwave background provides a test of cosmic inflation.

A)Yes, but this was before the Planck time, and the laws of physics as we presently understand them, including the laws of special relativity, did not yet apply.
B)No. The universe was so small at the beginning of the inflationary epoch that even an expansion by 50 orders of magnitude did not take it far enough in 10^-32 seconds to exceed the speed of light.
C)The postulate of special relativity was not violated because it was the dimensions of space that were expanding. The postulate applies to objects moving through space.
D)The postulate of special relativity was not violated because the curvature of space was so extreme at this time that the distance objects moved through during this 10^-32 seconds was foreshortened so that the speed was less than the speed of light.

A)Light (the cosmic microwave background radiation) was emitted by the weak interaction.
B)Above this energy matter behaved like radiation: the radiation-dominated era of the early universe.
C)The weak and electromagnetic interactions were unified.
D)The strong force separated from the electromagnetic force.

A)The universe cooled as it expanded, releasing energy.
B)The universe made the transition from the false vacuum to the true vacuum, releasing energy.
C)The particles gained energy in the form of mass from the Higgs field.
D)Gravitons, released by the newly created gravitational field, provided energy.

A)gluons.
B)intermediate vector bosons.
C)gravitons.
D)virtual neutrinos.

A)gluons
B)virtual photons
C)gravitons
D)protons

A)gluons.
B)intermediate vector bosons.
C)gravitons.
D)virtual photons.

A)energy.
B)mass.
C)charge.
D)strangeness.

A)the change of one type of quark into another type of quark into another type of quark by the weak force
B)the interactions of charged particles by the exchange of virtual photons
C)the bonding between quarks by the exchange of gluons
D)the interactions of nuclear particles by the strong force

A)all four
B)everything except gravity
C)the electromagnetic and weak forces
D)the strong and weak forces

A)the gravitational force
B)the weak nuclear force
C)the electromagnetic force
D)the strong nuclear force

A)nuclei
B)nothing
C)the quarks inside protons and neutrons
D)leptons (particles like electrons and neutrinos)

A)electromagnetic force.
B)gravitational force.
C)strong force.
D)weak force.

A)10^-9 m (1 nm, or roughly the size of a hydrogen atom)
B)infinity
C)a few thousand meters, or roughly the size of Earth)
D)10^-15 m (1 fm, or roughly the size of a proton)

A)The range of the strong nuclear force is 10 times smaller than the size of an atomic nucleus.
B)The range of the strong nuclear force is infinite; it has no limit.
C)The range of the strong nuclear force is the same as the size of the nucleus.
D)The range of the strong nuclear force is 10 times larger than the size of an atomic nucleus.

A)t = 0 to 10^-43 second, the Planck time, when gravity "froze out" of the universe
B)t = 0 to 10⁶ years, when radiation dominated the universe
C)t = 0 to 10^-35 second, when the strong nuclear force "froze out" of the universe
D)t = 0 to 1 second, when photons interchanged freely with electron-positron pairs

A)As the universe expanded rapidly, it cooled rapidly. Thereafter it expanded and cooled at a more moderate rate.
B)Because of the incredible speed of the expansion, there was no time for particles to exchange energy. Thus, the temperature remained constant during the expansion.
C)Because of the tremendous amount of energy available, the temperature actually rose during the expansion.
D)The temperature decreased during the expansion and then rose again to essentially the value it had initially.

A)velocity, the more certain you are of its position in space.
B)mass, the less certain you are of its size.
C)position, the more certain you are of its speed and motion.
D)position, the less certain you are of its speed and motion.

A)shorter the time that they can exist.
B)less precisely we know their position.
C)longer the time that they can exist.
D)more precisely we know their position.

A)No, never. Matter is a form of energy, and the spontaneous creation of matter would violate conservation of energy.
B)Yes, but only for extremely short times.
C)Yes, but only if the particles created are electrically neutral.
D)Yes, but only if an equal amount of matter disappears from some other part of the universe.

A)3.5 × 10^-25 s
B)1.1 × 10^-16 s
C)2.2 × 10^-16 s
D)7.0 × 10^-27 s

A)a collection of particles that acts like a single particle
B)any particle that has no mass and is electrically neutral
C)a particle that can never have any detectable effect whatsoever on the real universe
D)a particle that exists for such a short time interval that we cannot detect it by direct measurement

A)the same mass and the same electric charge.
B)the same mass and equal electric charges of opposite sign.
C)equal masses of opposite sign and the same electric charge.
D)equal masses of opposite sign and equal charges of opposite sign.

A)Wolf effect.
B)Rutherford shift.
C)Lamb shift.
D)Einstein effect.

A)They are exactly the same.
B)The particles created by the gamma ray are real. They can last forever if they do not annihilate. The virtual particles must recombine to become part of the vacuum within a very short time. Only under very special circumstances can they become real.
C)The particles created from the vacuum are real. They can last forever if they do not annihilate. The particles created from the gamma ray must recombine within a very short time. Only under very special circumstances can they become real.
D)The virtual particles have positive and negative mass, whereas the particles created by the gamma ray have positive mass.

A)1.533 MeV
B)1.022 MeV
C)0 eV, because it produces a particle-antiparticle pair
D)511 keV

A)2 × 10^-27 kg, about the mass of one hydrogen atom
B)10^-19 kg
C)about 1 kg
D)2 × 10³⁰ kg, about the mass of the Sun

A)It is believed that there are slight differences in mass between matter and antimatter. Thus the inflationary epoch, which gave mass and energy to the universe, created an imbalance of particles.
B)It is believed that there are slight differences in electric charge between matter and antimatter. Thus the inflationary epoch, which gave mass and energy to the universe, created an imbalance of particles.
C)We see only a small part of the universe. The missing antimatter is elsewhere, repelled by the negative mass of normal matter early in the history of the universe.
D)This question is an unsolved mystery of present-day cosmology.

A)Particles and antiparticles contain a certain amount of mass-energy independent of their temperature whereas the energy of a photon depends on its temperature.
B)Photons contain a certain amount of mass-energy independent of their temperature whereas the energy of particles and antiparticles depend on its temperature.
C)When particles collide, the interaction raises their temperature, but this does not happen when gamma-ray photons interact.
D)When gamma-ray photons collide, the interaction raises their temperature, but this does not happen when particles interact.

A)an unknown number, because the early universe was opaque and we cannot see what conditions were like then
B)1 billion and 1, thus producing the matter we see today
C)10 billion, thus producing the dark matter we see today
D)exactly 1 billion, because protons and antiprotons were created in equal numbers

A)There is perfect symmetry and balance between matter and antimatter.
B)There is a slight imbalance between matter and antimatter, with about one matter particle in excess for every billion matter-antimatter pairs.
C)There is far more matter than antimatter in the universe.
D)There is far more antimatter than matter in the universe.

A)They were created during the cosmic singularity and bounced around until the universe became transparent to radiation.
B)They were given off when the free electrons were captured by protons to form the first hydrogen atoms.
C)As the universe expanded and the radiation cooled, photons no longer had enough energy to create particles by pair production. But particles continued to annihilate and produce additional photons.
D)The "fireball" that we see in the distant past is really a reflection of all the radiation produced before that time bouncing back from the universe in its early opaque state.

A)at the end of the quark confinement
B)at the end of the deuterium bottleneck
C)very recently
D)when the temperature reached the proton threshold

A)Neutrons are much more massive than protons. After the first 2 seconds the temperature of the universe had fallen below the threshold for pair production of neutrons but not of protons.
B)Neutrons, being uncharged, can get close to other particles and annihilate them. Protons, being charged, cannot get close to other particles.
C)Free neutrons decay spontaneously. Free protons are stable.
D)Virtual proton-antiproton pairs were produced during the inflationary period, but neutral neutrons have no antiparticles and thus were not pair produced.

A)Free neutrons decay spontaneously to produce protons, electrons, and neutrinos.
B)The free neutrons interact quickly with the free electrons to produce antiprotons, so there are few neutrons left.
C)The original Big Bang produced only charged particles; hence neutrons were not produced, and those that now exist in the nuclei of atoms have come from proton decay.
D)Free neutrons react readily with free protons to produce high-energy photons, or γ radiation.

A)electron, proton, neutrino, and neutron
B)neutrino, neutron, electron, and proton
C)neutrino, electron, proton, and neutron
D)proton, electron, neutron, and neutrino

A)Deuterium had to form before helium could form, but deuterium is easily destroyed, thus preventing the formation of helium.
B)Deuterium absorbs neutrons efficiently, thus producing heavier and heavier isotopes of hydrogen instead of heavier elements such as helium.
C)Deuterium had to form before helium could form, but deuterium is almost impossible to create, thus preventing the formation of helium.
D)Helium is used up in the formation of deuterium. However, deuterium is difficult to create, thus leaving us with large amounts of helium.

A)by nuclear reactions in the cores of stars, and was then thrown out into space by supernovae
B)by the collision of cosmic rays with hydrogen nuclei in interstellar gas clouds
C)by high-energy processes during the collapse of protogalactic clouds during the formation of galaxies
D)by nuclear reactions during the Big Bang

A)during the first 300,000 years
B)during the first 10^-43 second
C)during the first 10^-6 second
D)during the first 15 minutes

A)1:10
B)1:6
C)1:4
D)1:1

A)less than 3 K-the microwave background is warmer because it received extra energy from the annihilation reaction that produced it.
B)3 K-the expansion of the universe is the same for all particles in it.
C)4 K-the universe was hotter when it became transparent to neutrinos.
D)1,000,000 K-the neutrinos do not interact with matter and therefore have not been redshifted.

A)The neutrino-antineutrino background "escaped" from the primordial fireball long before the CMB. Thus, it has been cooling for a longer time and it should be at a lower temperature.
B)The neutrino-antineutrino background is constantly undergoing annihilation, which produces high-energy gamma rays and heat. Thus, the temperature should be higher than the CMB.
C)The threshold temperature of the neutrino is the highest of any pair of production particles. Thus, the temperature should be higher than the CMB.
D)The neutrino-antineutrino background was produced at an earlier, hotter time in the history of the universe. Thus, this background should be hotter than the CMB.

A)With the formation of the first stars, nucleosynthesis had a confined, uninterrupted space in which to produce both deuterium and hydrogen.
B)The formation of deuterium requires the strong force, and this did not separate out from the other forces until sometime after the cosmic singularity. When it did, the deuterium bottleneck ended.
C)As the universe expanded, its photons cooled, lost energy, and eventually became unable to disrupt deuterium.
D)As the universe expanded, the protons and neutrons cooled, lost energy, and were eventually able to stick together without bouncing apart.

A)They annihilated to produce protons and antiprotons.
B)They are still present as a cosmic background.
C)They were absorbed by matter, giving it some of the additional energy required for inflationary expansion.
D)They were absorbed by neutrons to form protons and electrons.

A) Because it is a particle with mass, its speed is governed by the temperature of its surroundings because it will always be in thermal equilibrium.
B) Because it is a particle with mass, its speed must be less than the speed of light, c.
C) Its speed must be faster than the speed of light, because this is the only way that a lepton can have mass.
D) Because of its nature, a neutrino can only exist when it is traveling at the speed of light, just like photons of electromagnetic radiation.

A)The existence of galaxies shows empirically that these density fluctuations must have been present. Theoretically the early universe was expected to be perfectly smooth.
B)These fluctuations are required by the Heisenberg uncertainty principle.
C)Mutual gravitational attraction will always lead to lumpiness, even in a distribution that is perfectly uniform.
D)This is related to the imbalance of matter and antimatter. This led to nonuniform annihilation reactions, and gravitational attraction led to collapse and lumpiness.

A)the maximum distance over which a temperature fluctuation can occur in a "connected" universe
B)the minimum diameter of a density fluctuation that can collapse gravitationally to form a galaxy or other astronomical object
C)the minimum distance over which a temperature fluctuation can occur in a "connected" universe
D)the maximum diameter of a density fluctuation that can collapse gravitationally to form a galaxy or other astronomical object

A)The Jeans length would decrease to 0.4 ly.
B)The Jeans length would increase to 1.6 ly.
C)The Jeans length would increase to 1.1 ly.
D)The Jeans length would decrease to 0.6 ly.

A)a spiral galaxy
B)a Population III star
C)an open cluster
D)a globular cluster

A)small because ρ_m was large.
B)small because m was large.
C)large because m was small.
D)unaffected by the composition of the material.

A)The Jeans length for these numbers is about 100 ly. Matter will not begin clumping together because there is not enough mass in the fluctuation of 10 ly to overcome the gas pressure.
B)The Jeans length for these numbers is about 100 ly. Matter will begin clumping together since this is within the Jeans limit.
C)The Jeans length for these numbers is about 1 ly. Matter will not begin clumping together because there is not enough mass in the fluctuation to overcome the gas pressure.
D)The Jeans length for these numbers is about 1 ly. Matter will begin clumping together since this is within the Jeans limit.

A)The first generation of stars had lower metallicity than the present generation, but in each era the formation of large stars and small stars was equally likely.
B)It is easier to make a gas and dust cloud collapse when the metal content is low. Thus, even small stars could be formed in the early universe, but large stars were a rarity.
C)It is harder to make a gas and dust cloud collapse when the metal content is low. Thus, even small stars could be formed in the early universe, but large stars were a rarity.
D)It is harder to make a gas and dust cloud collapse when the metal content is low. Thus, large stars were more likely to be formed in the early universe, but small stars were a rarity.

A)The cosmic microwave background itself caused the reionization of hydrogen and helium.
B)Large, hot Population III stars emitted enough high-energy radiation during their lifetimes to cause reionization.
C)The intense background of neutrinos and antineutrinos released much earlier than the cosmic microwave background radiation had enough energy to cause reionization.
D)The explosions of giant Population III stars would cause a shower of high-speed particles that could result in reionization.

A)These stars were almost pure hydrogen and helium, and such stars use only the hydrogen fusion reaction. Therefore, we expect their lifetimes were long.
B)These stars were characterized by almost zero metallicity, and such stars require large masses to collapse. With these large masses, we expect that their lifetimes were long.
C)These stars were characterized by almost zero metallicity, and such stars require large masses and consequently high central temperatures to collapse. With high central temperatures, we expect their lifetimes were short.
D)Since they were formed as early as 400 million years after the Big Bang, and we still find large numbers of them currently in existence, we know that their lifetimes are extremely long.

A)In both cases, galaxies form by the breakup of larger objects, but the breakup occurs faster if the dark matter is hot than if it is cold.
B)With cold dark matter, galaxies form by the breakup of larger objects, whereas with hot dark matter galaxies form through the merger of smaller objects.
C)In both cases, galaxies form through the merger of smaller objects, but the merger occurs faster if the dark matter is cold than if it is hot.
D)With cold dark matter, galaxies form through the merger of smaller objects, whereas with hot dark matter, galaxies form by the breakup of larger objects.

A)In those regions where the density is larger the gas pressure will also be larger, and the gas will be less likely to collapse.
B)In those regions where the density is larger the Jeans length is smaller, meaning that smaller regions of the gas are likely to collapse.
C)The Jeans length must be calculated for the entire cloud. Density fluctuations within the cloud have no effect.
D)The likelihood of gravitational collapse cannot be calculated from the information given.

A)long filaments of galaxies.
B)individual spiral galaxies.
C)individual elliptical galaxies.
D)globular clusters.

A)whether dark matter is hot or cold, cold dark matter resulting in the top-down scenario
B)whether dark matter is hot or cold, hot dark matter resulting in the top-down scenario
C)whether neutrinos have mass, massless neutrinos resulting in the top-down scenario
D)whether the early universe had an abundance or a scarcity of metals, an abundance resulting in the bottom-up scenario

A)Some of the dimensions of spacetime are hidden.
B)Massive particles are predicted-perhaps giving a clue to dark matter.
C)String theories can include quantum gravity.
D)String theory has been discredited in favor of M-theory.

A)In three space dimensions the trajectory of an object influenced by gravity appears straight, and in the multidimensional space of the Kaluza-Klein theory it appears straight.
B)Many of the additional dimensions cancel out, leaving us with a simpler system than we had originally.
C)Some dimensions in the multidimensional theory may not be observable because they are coiled tightly.
D)We may be able to account for the existence of dark matter and dark energy.

A)The theories have at least four space dimensions.
B)The dimensions we cannot see are curled tightly into loops.
C)Different loop vibrations correspond to particles with different masses.
D)In the new theories, gravitation no longer has an effect on space.

A)No, this was not really necessary. Witten was attempting to recast the theory to make its connections with general relativity more apparent.
B)Yes, this was necessary. Mistakes had been found in the earlier theory, and additional dimensions seemed the easiest way to fix these.
C)Yes, this was necessary. Between Kaluza and Witten, two additional forces had been discovered, and the natural solution was to add more dimensions to the theory.
D)Yes, this was necessary. Witten's extra dimensions were specifically an attempt to account for dark matter.

A)there are 11 dimensions, including two time dimensions (essentially "forward" and "backward").
B)all of the dimensions are coiled up tightly like coiled strings.
C)the 11 dimensions include several dimensions that ought to be observable at very low temperatures.
D)seven dimensions are coiled tightly like coiled strings.

A)They are not actually particles, but just points in space.
B)Extremely high energies are needed to create these particles.
C)The fundamental strings that make up these particles vibrate at frequencies we cannot detect.
D)The particles do not exist in three-dimensional space.