Universe: Difference between revisions

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==Age==
==Age==
Examination of small variations in the microwave background radiation provides information about the nature of the universe, including the age and composition. The age of the universe from the time of the Big Bang, according to current information provided by NASA's WMAP (Wilkinson Microwave Anisotropy Probe), is estimated to be about 13.7 billion years, with a margin of error of about 1 % (± 200 million years). Other methods of estimation give different ages ranging from 11 billion to 20 billion. Most of the estimates cluster in the 13–15 billion year range.
Examination of small variations in the microwave background radiation provides information about the nature of the universe, including the age and composition. The age of the universe from the time of the Big Bang, according to current information provided by NASA's WMAP (Wilkinson Microwave Anisotropy Probe), is estimated to be about 13.7 billion years, with a margin of error of about 1 % (± 200 million years). Other methods of estimation give different ages ranging from 11 billion to 20 billion. Most of the estimates cluster in the 13–15 billion year range.
==Composition==
The currently observable universe appears to have a [[geometrically flat]] space-time containing the equivalent [[mass-energy density]] of 9.9 × 10<sup>-30</sup> grams per cubic centimeter. This mass-energy appears to consist of 73% [[dark energy]], 23% cold [[dark matter]] and 4% [[atoms]]. Thus the density of atoms is on the order of a single hydrogen [[nucleus]] (or atom) for every four cubic meters of volume. The exact nature of dark energy and cold dark matter remain a mystery.
During the early phases of the big bang, equal amounts of matter and [[antimatter]] were formed. However, through a CP-violation, physical processes resulted in an asymmetry in the amount of matter as compared to anti-matter. This asymmetry explains the amount of residual matter found in the universe today, as nearly all the matter and anti-matter would otherwise have annihilated each other when they came into contact.
Prior to the formation of the first stars, the chemical composition of the Universe consisted primarily of hydrogen (75% of total mass), with a lesser amount of helium-4 (4He) (24% of total mass) and trace amounts of the isotopes deuterium (2H), helium-3 (3He) and lithium (7Li). Subsequently the interstellar medium within galaxies has been steadily enriched by heavier elements. These are introduced as a result of supernova explosions, stellar winds and the expulsion of the outer envelope of evolved stars.
The big bang left behind a background flux of photons and neutrinos. The temperature of the background radiation has steadily decreased as the universe expands, and now primarily consists of microwave energy equivalent to a temperature of 2.725 K. The neutrino background is not observable with present-day technology, but is theorized to have a density of about 150 neutrinos per cubic centimeter.


==References==
==References==
<references/>
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Revision as of 15:18, 25 October 2007

The Universe is the summation of all particles and energy that exist and the space-time in which all events occur.

The generally accepted scientific theory which describes the origin and evolution of the Universe is Big Bang Theory. This cosmic explosion, by current estimates, happened between 13-15 billion years ago. [1] The Universe underwent a rapid period of cosmic inflation that flattened out nearly all initial irregularities in the energy density; thereafter the universe expanded and became steadily cooler and less dense. Minor variations in the distribution of mass resulted in hierarchical segregation of the features that are found in the current universe; such as clusters and superclusters of galaxies.

There are more than one hundred billion (1011) galaxies in the Universe[2], each containing hundreds of billions of stars, with each star containing about 1057 atoms of hydrogen.

Etymology

The word "universe" is derived from Old French univers, from Latin universum, which combines uni- ("one") with versus ("turn"), meaning "turned into one".[3] However, different words have been used throughout history to denote "all of space", including the equivalents and variants in various languages of "heavens", "cosmos", and "world". (Although words like "world" and its equivalents in other languages now almost always refer to the planet Earth, they previously referred to everything that exists.)

Formation

According to redshift observations, and Hubble's Law, the universe is expanding. That is, astronomers observe that there is a direct relationship between the distance to a remote object (such as a galaxy) and the velocity with which it is receding. Conversely, if this expansion has continued over the entire age of the universe, then in the past, these distant, receding objects must once have been closer together.

By extrapolating this expansion back in time, one approaches a gravitational singularity where everything in the universe was compressed into an infinitesimal point. This idea gave rise to the Big Bang Theory, which describes the expansion of space from an extremely hot and dense state of unknown characteristics.

Age

Examination of small variations in the microwave background radiation provides information about the nature of the universe, including the age and composition. The age of the universe from the time of the Big Bang, according to current information provided by NASA's WMAP (Wilkinson Microwave Anisotropy Probe), is estimated to be about 13.7 billion years, with a margin of error of about 1 % (± 200 million years). Other methods of estimation give different ages ranging from 11 billion to 20 billion. Most of the estimates cluster in the 13–15 billion year range.

Composition

The currently observable universe appears to have a geometrically flat space-time containing the equivalent mass-energy density of 9.9 × 10-30 grams per cubic centimeter. This mass-energy appears to consist of 73% dark energy, 23% cold dark matter and 4% atoms. Thus the density of atoms is on the order of a single hydrogen nucleus (or atom) for every four cubic meters of volume. The exact nature of dark energy and cold dark matter remain a mystery.

During the early phases of the big bang, equal amounts of matter and antimatter were formed. However, through a CP-violation, physical processes resulted in an asymmetry in the amount of matter as compared to anti-matter. This asymmetry explains the amount of residual matter found in the universe today, as nearly all the matter and anti-matter would otherwise have annihilated each other when they came into contact.

Prior to the formation of the first stars, the chemical composition of the Universe consisted primarily of hydrogen (75% of total mass), with a lesser amount of helium-4 (4He) (24% of total mass) and trace amounts of the isotopes deuterium (2H), helium-3 (3He) and lithium (7Li). Subsequently the interstellar medium within galaxies has been steadily enriched by heavier elements. These are introduced as a result of supernova explosions, stellar winds and the expulsion of the outer envelope of evolved stars.

The big bang left behind a background flux of photons and neutrinos. The temperature of the background radiation has steadily decreased as the universe expands, and now primarily consists of microwave energy equivalent to a temperature of 2.725 K. The neutrino background is not observable with present-day technology, but is theorized to have a density of about 150 neutrinos per cubic centimeter.

References

  1. ^ Britt, Robert Roy (2003-01-03). Age of Universe Revised, Again.[1] space.com. Retrieved on 2007-01-08.
  2. Mackie, Glen (February 1, 2002). To see the Universe in a Grain of Taranaki Sand.[2] Swinburne University. Retrieved on 2006-12-20.
  3. dictionary.reference.com[3]