BigBang Theory?
Virtually all astronomers and cosmologists agree the universe began with a “big bang” — a powerful genesis of space-time that sent matter and energy reeling outward.
The evidence is clear, ranging from the underpinnings of Albert Einstein’s general theory of relativity, to the detection of the cosmic microwave background by Arno Penzias and Robert Wilson in the 1960s.
The Big Bang model is typically broken down into a few key eras and events. Standard cosmology, the set of ideas that are most reliable in helping decipher the universe’s history, applies from the present time back to about a hundredth of second after the Big Bang. But before then, particle physics and quantum cosmology ruled the universe.
When the large Bang occurred, matter, energy, space, and time were all formed, and therefore the universe was infinitely dense and incredibly hot.
“What came before the Big Bang?”
is outside the realm of science because it can’t be answered by scientific means. In fact, science says little about the way the universe behaved until some 10–43 second after the large Bang, when the Grand Unification Epoch began (and lasted only until about 10–35 second). Matter and energy were interchangeable and in equilibrium during this period, and the weak and strong nuclear forces and electromagnetism were all equivalent.
The universe cooled rapidly because it blew outward, however, and by 10–35 second after the large Bang. During this wild period, cosmic strings, monopoles, and other exotic species likely came to be. As sensational as inflation sounds, it explains several observations that would otherwise be difficult to reconcile. After inflating, the universe bogged down its expansion rate but continued to grow, because it does still. It also cooled significantly, allowing for the formation of matter — first neutrinos, electrons, quarks, and photons, followed by protons and neutrons. Likewise, antiparticles were produced in abundance, carrying the opposite charge of their corresponding particles (positrons along with electrons, for example).
As time went on and particles’ rest-mass energy was greater than the thermal energy of the universe, many were annihilated with their partners, producing gamma rays in the process.
At a key moment about one second after the Big Bang, nucleosynthesis took place and created deuterium along with the light elements helium and lithium. After some 10,000 years, the temperature of the universe cooled to the point where massive particles contributed more to the universe’s overall energy density than light and other radiation, which had dominated until then. This turned on gravity as a key player, and therefore the little irregularities within the density of matter were magnified into structures because the universe expanded.
Astronomical Society of the Pacific
The relic radiation of the Big Bang decoupled (picture heavy traffic suddenly clearing) nearly 400,000 years later, creating the resonant echo of radiation observed by Penzias and Wilson with their radio telescope. This decoupling moment witnessed the universe changing from opaque to transparent. Matter and radiation were finally separate.
Observational astronomers consider much of the history of the first universe the province of particle physicists, describing what happened up to the formation of galaxies, stars, and black holes as “a lot of messy physics.” They are more interested in how the first astronomical objects, the large-scale inhabitants of the universe, came to be about 1 billion years after the Big Bang. But before these astronomers can gain a clear picture of that process, they need to consider the role of the wild card — dark matter.
The evidence is clear, ranging from the underpinnings of Albert Einstein’s general theory of relativity, to the detection of the cosmic microwave background by Arno Penzias and Robert Wilson in the 1960s.
The Big Bang model is typically broken down into a few key eras and events. Standard cosmology, the set of ideas that are most reliable in helping decipher the universe’s history, applies from the present time back to about a hundredth of second after the Big Bang. But before then, particle physics and quantum cosmology ruled the universe.
When the large Bang occurred, matter, energy, space, and time were all formed, and therefore the universe was infinitely dense and incredibly hot.
“What came before the Big Bang?”
is outside the realm of science because it can’t be answered by scientific means. In fact, science says little about the way the universe behaved until some 10–43 second after the large Bang, when the Grand Unification Epoch began (and lasted only until about 10–35 second). Matter and energy were interchangeable and in equilibrium during this period, and the weak and strong nuclear forces and electromagnetism were all equivalent.
The universe cooled rapidly because it blew outward, however, and by 10–35 second after the large Bang. During this wild period, cosmic strings, monopoles, and other exotic species likely came to be. As sensational as inflation sounds, it explains several observations that would otherwise be difficult to reconcile. After inflating, the universe bogged down its expansion rate but continued to grow, because it does still. It also cooled significantly, allowing for the formation of matter — first neutrinos, electrons, quarks, and photons, followed by protons and neutrons. Likewise, antiparticles were produced in abundance, carrying the opposite charge of their corresponding particles (positrons along with electrons, for example).
As time went on and particles’ rest-mass energy was greater than the thermal energy of the universe, many were annihilated with their partners, producing gamma rays in the process.
At a key moment about one second after the Big Bang, nucleosynthesis took place and created deuterium along with the light elements helium and lithium. After some 10,000 years, the temperature of the universe cooled to the point where massive particles contributed more to the universe’s overall energy density than light and other radiation, which had dominated until then. This turned on gravity as a key player, and therefore the little irregularities within the density of matter were magnified into structures because the universe expanded.
Astronomical Society of the Pacific
The relic radiation of the Big Bang decoupled (picture heavy traffic suddenly clearing) nearly 400,000 years later, creating the resonant echo of radiation observed by Penzias and Wilson with their radio telescope. This decoupling moment witnessed the universe changing from opaque to transparent. Matter and radiation were finally separate.
Observational astronomers consider much of the history of the first universe the province of particle physicists, describing what happened up to the formation of galaxies, stars, and black holes as “a lot of messy physics.” They are more interested in how the first astronomical objects, the large-scale inhabitants of the universe, came to be about 1 billion years after the Big Bang. But before these astronomers can gain a clear picture of that process, they need to consider the role of the wild card — dark matter.
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