Deck 22: The Birth of the Universe

A)Gravity was an extremely weak force at this period in time.
B)Large amounts of matter and antimatter annihilated at this time.
C)There wasn't enough matter present to slow down the expansion at that time.
D)The universe was too small and needed to grow quickly.
E)An enormous amount of energy was released when the strong force froze out from the GUT force.

A)10⁻¹⁰ second
B)10⁻³⁵ second
C)10⁻⁴³ second
D)3 minutes
E)300,000 years

A)what happened the instant after the Big Bang
B)a sudden expansion of the universe after the strong force froze out from the GUT force
C)the expansion of the universe that we still observe today
D)the sudden release of photons when a particle and antiparticle annihilate each other
E)the separation that occurs after two photons collide and create a particle and an antiparticle

A)All the free particles had combined to form the nuclei of atoms.
B)The universe had expanded and cooled to a temperature of about 3,000 K,cool enough for stable,neutral atoms to form.
C)Neutrinos and electrons were finally able to escape the plasma of the early universe and no longer heated the other particles.
D)Photons were finally able to escape the plasma of the early universe and no longer heated the hydrogen and helium ions.
E)No theory can explain this.

A)First there was a Big Bang,then inflation (of space)caused recession (of all matter,away from the Big Bang).
B)First there was inflation,which caused the Big Bang,then recession.
C)First there was a Big Bang.There has not been any inflation yet,but if it comes it will cause recession.

A)the moment of the Big Bang
B)the end of the Planck era
C)during the era of nucleosynthesis
D)the end of the era of nuclei
E)during the era of galaxy formation

A)We do not yet have a theory that links quantum mechanics and general relativity.
B)We do not understand the properties of antimatter.
C)We do not know how much energy existed during that time.
D)It was a time period from which we cannot receive radiation.
E)The Planck era was the time before the Big Bang,and we cannot describe what happened before that instant.

A)one,what we call the "super force"
B)two,gravity and the GUT force
C)two,gravity and the electroweak force
D)three,gravity,the strong force,and the electroweak force
E)all of the above forces

A)these forces are important only at temperatures below the freezing point of water-a temperature that the universe reached at an age of about 10⁻¹⁰ second.
B)"freezing out" was a term coined by particle physicists who think that the Big Bang theory is really cool.
C)prior to this time the electromagnetic and weak forces maintained a single identity,but they possessed separate identities following this time.
D)following this time neither the electromagnetic nor the weak force was ever important in the universe again.
E)quantum fluctuations by high-speed,relativistic particles in a state of false vacuum cause disturbances in the spacetime continuum,leading to the process described in the question this answer refers to.

A)10⁻¹⁰ second
B)0.001 second
C)5 seconds
D)5 minutes
E)5 years

A)1 million years
B)300,000 years
C)300 years
D)3 minutes
E)10⁻¹⁰ second

A)gravity and the weak force
B)gravity and the strong force
C)the strong and weak forces
D)the strong and electromagnetic forces
E)the electromagnetic and weak forces

A)The cosmic background radiation is expected to have a temperature just a few degrees above absolute zero,and its actual temperature turns out to be about 3 K (actually 2.7 K).
B)The cosmic background radiation is expected to have a perfect thermal spectrum,and observations from the COBE spacecraft verify this prediction.
C)The cosmic background radiation is expected to contain spectral lines of hydrogen and helium,and it does.
D)The cosmic background radiation is expected to look essentially the same in all directions,and it does.
E)The cosmic background radiation is expected to have tiny temperature fluctuations at the level of about 1 part in 100,000.Such fluctuations were found in the COBE data.

A)All the elements except hydrogen were produced after the era of nucleosynthesis.
B)We can observe spectra from this era to determine what the primordial mix of the elements was at the beginning of the universe.
C)Except for the small amount of matter produced later by stars,the chemical composition of the universe is the same now as at the end of the era of nucleosynthesis.
D)We can study the processes that occurred during the era of nucleosynthesis to determine how most of the elements in the universe were created.
E)By knowing how much matter was created during the era of nucleosynthesis,we can determine whether the universe is open or closed.

A)before the Big Bang.
B)before the Planck time.
C)after the Planck time.
D)after inflation.
E)after the GUT era.

A)only hydrogen
B)only helium
C)hydrogen and helium and trace amounts of deuterium and lithium
D)roughly equal amounts of each of the following: hydrogen,helium,deuterium and lithium
E)nuclei of all the chemical elements

A)The most advanced telescopes are able to see back to this era in the universe.
B)Detectors on Earth have received photons and high-energy particles from this era.
C)Temperatures in the center of the Sun can reproduce the conditions during this era.
D)Particle accelerators on Earth can reach energies equivalent to the high temperatures of this era and have produced particles predicted by the electroweak theory.
E)We have no direct evidence of the electroweak force.

A)It has a temperature of about 3 degrees K above absolute zero.
B)It is the result of a mixture of radiation from many independent sources,such as stars and galaxies.
C)It had a much higher temperature in the past.
D)It was discovered by Penzias and Wilson in the early 1960s.
E)It appears essentially the same in all directions (it is isotropic).

A)They combined in groups to make protons,neutrons,and their antiparticles.
B)They froze out of the soup of particles at the end of the era.
C)They evaporated.
D)They combined in groups to make electrons and neutrinos.
E)They combined in groups to make W and Z bosons.

A)You are plunging into the Sun.
B)You are crossing the event horizon of a black hole.
C)You are being consumed by a "crack" in the universe caused by inflation.
D)You are near the center of a star that has just developed an iron core,leading to a supernova.
E)You are in a medieval torture chamber somewhere in western Europe.

A)both the Big Bang and inflation
B)only the Big Bang,but not inflation
C)not the Big Bang,but inflation
D)neither the Big Bang nor inflation

A)The shock wave of the Big Bang caused ripples that expanded outward with time.
B)The energy released when the strong force froze out of the GUT force caused shock waves that produced ripples in the universe.
C)Matter and antimatter particles that spontaneously formed from high-energy photons caused perturbations in the radiation field.
D)The annihilation of matter and antimatter particles caused tiny explosions that perturbed the radiation field.
E)Quantum mechanics requires that the energy fields at any point in space be continually fluctuating as a result of the uncertainty principle.

A)The overall structure of the universe is very uniform,but the universe must have contained some regions of higher density in order for galaxies to form.
B)The temperature of the universe can be found by taking an average over the entire sky,but individual stars will create peaks in the spectrum over small angles.
C)Dark matter consisting of WIMPs greatly smooths out the spectrum,but the small patches of "light" matter create peaks in the spectrum.
D)The overall structure of the universe is very uniform,but the synthesis of different elements produces varying signatures within the background spectrum.
E)The overall structure of the universe is very uniform,but intervening gas between us and the era of nuclei absorbs wavelengths depending on the composition and redshift of the gas.

A)You are in the center of a star very much like our Sun.
B)You are in the early universe during the era of nucleosynthesis.
C)You are inside a nuclear power plant on Earth.
D)You are in the center of a star much smaller than the Sun.
E)You are in the center of a massive star near the end of its life.

A)You are in the center of a young star.
B)You are in the early universe before the Planck time.
C)You are floating somewhere in the universe near its end,10¹⁰⁰ years from now.
D)You are inside the nucleus of an atom.
E)You are in the universe shortly after inflation.

A)What would it be like to ride on a beam of light?
B)Can we measure the position and momentum of an electron at the same time?
C)How does the Sun produce energy?
D)Why is the sky dark at night?
E)How many stars are in the universe?

A)You are in the center of a star very much like our Sun.
B)You are in the early universe during the era of nucleosynthesis.
C)You are inside a nuclear power plant on Earth.
D)You are in the center of a massive star near the end of its life.
E)You are in the center of a star much smaller than the Sun.

A)stellar nucleosynthesis only.
B)the Big Bang only.
C)stellar nucleosynthesis with a small contribution from the Big Bang.
D)the Big Bang with a small contribution from stellar nucleosynthesis.
E)radioactive decay of heavier elements only.

A)the annihilation of matter and antimatter
B)the separation of the electromagnetic and weak forces
C)the "freezing out" of the strong force from the GUT force
D)the energy released in the fusion of protons and neutrons to produce helium
E)giant quantum fluctuations

A)You are on the surface of Earth.
B)You are on the surface of a planet that is somewhat more massive than Earth.
C)You are on the surface of a white dwarf.
D)You are "on" an accretion disk around a black hole.
E)You are on the surface of a neutron star.

A)the cosmic background radiation and the high helium content of the universe
B)the cosmic background radiation and the expansion of the universe
C)the cosmic background radiation and the near-critical density of the universe
D)the predominance of matter over antimatter and the near-critical density of the universe
E)the predominance of matter over antimatter and the large scale structure of galaxies

A)You are on an asteroid near the center of a galaxy,heading in toward a massive black hole.
B)You have been shrunk in size and are riding a grain of interstellar dust that is carrying you on an orbit about our very own Sun.
C)You are riding a jet of gas from a quasar that is headed in the direction of an ordinary star.
D)You are on comet Hale-Bopp,circa May 1997.
E)You are at Disneyland on the Moon,riding the new "wild and wet" roller coaster.

A)You are in the universe during its first 300,000 years.
B)You are in the universe more than 10¹⁰⁰ years in the future.
C)You are in an accretion disk around a supermassive black hole.
D)You are in the central regions of a quasar.
E)You are where the Sun should be located,but about 5 billion years from now.

A)The background radiation came from the heat of the universe,with a peak corresponding to the temperature of the universe.
B)The spectrum of pure hydrogen is a perfect thermal radiation spectrum.
C)The spectrum of 75 percent hydrogen and 25 percent helium is a perfect thermal radiation spectrum.
D)The light from all the stars and gas in the sky averaged over the entire universe is a perfect thermal radiation spectrum.
E)It doesn't predict that the cosmic background radiation should have a perfect thermal radiation spectrum.

A)You are in the universe when it was about 200 million years old,just before galaxies began forming.
B)You are in the center of the Milky Way Galaxy,looking outward into the Local Group.
C)You are somewhere between the Andromeda and Milky Way galaxies in the Local Group.
D)You are in intergalactic space within a rich cluster of thousands of galaxies.
E)You are in the outskirts of a galaxy whose nucleus is a powerful quasar.

A)darkness of the night sky
B)recession speeds of far away galaxies relative to close ones
C)observed helium abundance in the universe
D)relative motions of galaxies in the Local Group

A)380,000 years after the Big Bang.
B)one ten-billionth of a second after the Big Bang.
C)10-45 seconds after the Big Bang.
D)10 billion years ago.

A)These two forces first became distinct at this time.
B)These forces are important only at temperatures below the freezing point of water-a temperature that the universe reached at an age of about at 10⁻³⁸ second.
C)Freezing out was a term coined by particle physicists who think that the Big Bang theory is really cool.
D)Following this time,neither the strong nor electroweak forces were ever important in the universe again.

A)It is the time at which inflation is thought to have occurred.
B)Before it,conditions were so extreme that our current understanding of physics is insufficient to predict what might have occurred.
C)It is the time when the cosmic microwave background was released.
D)It is the amount of time required for two protons to fuse to make deuterium.

A)What would it be like to ride on a beam of light?
B)How many stars are in the universe?
C)Can we measure the position and momentum of an electron at the same time?
D)Why is the sky dark at night?

A)strong force,weak force,electromagnetic force,gravity.
B)strong force,weak force,electric force,magnetic force.
C)nuclear force,electromagnetic force,gravity,tidal force.
D)nuclear force,gravity,electric force,magnetic force.

A)We do not know how hot or dense the universe was during that time.
B)We do not understand the properties of antimatter.
C)We do not yet have a theory that links quantum mechanics and general relativity.
D)The Planck era was the time before the Big Bang,and we cannot describe what happened before that instant.

A)the total amount of mass in the universe.
B)the density of ordinary (baryonic)matter in the universe.
C)the acceleration of the universe.
D)the current age of the universe.

A)3K
B)300K
C)3000K
D)The universe cannot be said to have a single temperature.

A)the expansion of the universe that we still observe today
B)the sudden release of photons when a particle and antiparticle annihilate one another
C)a sudden and extremely rapid expansion of the universe that occurred in a tiny fraction of a second during the universe's first second of existence
D)quantum fluctuations by high speed,relativistic particles in a state of false vacuum that caused disturbances in the space-time continuum leading to the process described in the question to which this answer refers

A)unify gravity with the strong and weak forces.
B)unify the electromagnetic and weak forces.
C)unify all four forces together.
D)unify the strong force with the electromagnetic and weak forces.

A)(1)the theory correctly predicts that the universe should be expanding;(2)the theory predicts the existence of and the specific characteristics of the observed cosmic microwave background.
B)(1)the theory predicts the episode of inflation that we think occurred in the early universe;(2)the theory predicts the existence of large quantities of dark matter.
C)(1)the theory correctly predicts that the universe should be expanding;(2)the theory correctly predicts the observed ratio of spiral to elliptical galaxies in the universe.
D)(1)the theory predicts the existence of and the specific characteristics of the observed cosmic microwave background;(2)the theory correctly predicts the observed overall chemical composition of the universe.

A)1 force that represented the unification of all four forces that operate today
B)3 forces: gravity,the strong force,and the electroweak force
C)2 forces: the strong force and the electroweak force
D)2 forces: gravity and a single force that later became the strong,weak,and electromagnetic forces

A)The universe began with the forces unified.During the first fraction of a second,the forces separated and there was a brief but important episode of inflation.Subatomic particles of both matter and antimatter then began to appear from the energy present in the universe.Most of the particles annihilated to make photons,but some became protons,neutrons,electrons,and neutrinos.The protons and neutrons underwent some fusion during the first three minutes,thereby determining the basic chemical composition of the universe.
B)An episode of what we call inflation initiated the event of the Big Bang.Once the Big Bang got underway,particles and forces began to appear one by one.The forces produced protons,which fused to make hydrogen and helium until the universe was about 380,000 years old.Then gravity began to act,turning the hydrogen and helium into galaxies.
C)Forces and various subatomic particles began to appear during the first second after the Big Bang.For reasons not understood,the particles were all made of ordinary matter and none were made of antimatter,thus explaining why we live in a universe made of matter.The particles underwent some fusion for the first 380,000 years after the Big Bang,at which time the first stars were born.
D)The Big Bang began with the initiation of what we call inflation,which gradually slowed to the current expansion rate of the universe.Forces came to exist for a different reason,having to do with quantum fluctuations in the space-time continuum.Particles came to exist as a result of cracks made when forces froze.Once there were particles,gravity brought them together to make stars,and the stars then turned the particles into hydrogen,helium,and other elements.

A)Inflation predicts that the early universe should have regions of enhanced density that could have acted as "seeds" for the formation of galaxies and large structures.
B)The universe should be geometrically "flat" (in the four dimensions of spacetime).
C)Inflation predicts that the temperature of the cosmic microwave background should be almost (but not exactly)the same everywhere.
D)Inflation predicts that the entire universe must be far larger than the observable universe.

A)the fact that the temperature of the cosmic microwave background is almost the same everywhere
B)the fact that about 25% of the ordinary matter in the universe consists of helium
C)the existence of the cosmic microwave background
D)the fact that the universe is expanding

A)We look all the way to the cosmological horizon,where we can see the actual conditions that prevailed all the way back to the first instant of the Big Bang.
B)The conditions in the very early universe must have been much like those found in stars today,so we learn about them by studying stars.
C)We work backward from current conditions to calculate what temperatures and densities must have been when the observable universe was much smaller in size.
D)We can only guess at the conditions,since we have no way to calculate or observe what they were.

A)They add further support to the idea that dark matter really exists and is made of non-ordinary (nonbaryonic)matter,such as WIMPs.
B)They do not support the conclusion that dark matter is the dominant form of matter in the universe.
C)They tell us that dark matter probably exists,but that it must be made of ordinary (baryonic)matter in the form of MACHOs.
D)They tell us that dark matter was produced during the era of nuclei.

A)They can form a complete atom.
B)The combined mass of the two particles is completely transformed into energy (photons).
C)They fuse to make a heavier particle.
D)The question makes no sense,since antimatter does not really exist.

A)Its spectrum corresponds to a temperature of just under 3 degrees above absolute zero.
B)With the exception of very small variations,it appears essentially the same in all directions in which we look into space.
C)It is the result of a mixture of radiation from many independent sources,such as stars and galaxies.
D)It is thought to be radiation that began its journey to our telescopes when the universe was about 380,000 years old.

A)the electromagnetic and weak forces into the electroweak force.
B)the strong,weak,and electromagnetic forces into the GUT force.
C)the unification of all four forces into a single "superforce."
D)the strong and weak forces into the combined nuclear force.

A)Our universe is flat.
B)Prior to the Planck time,our universe sprouted from another universe.
C)The universe is 14 billion years old.
D)The expansion of the universe is now accelerating.