Big Bang: Difference between revisions
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<onlyinclude>The '''Big Bang''' is what scientists call the enormous explosion that started time, space, and the universe.<ref>Cambridge. ''Hot Big Bang'' [Online]. Available:http://www.damtp.cam.ac.uk/research/gr/public/bb_home.html</ref> The explosion started out extremely [[density|dense]] and hot, before rapidly cooling down. To this day space remains a few [[kelvin]] above [[absolute zero]] because of the initial [[temperature]] of the Big Bang.<ref name=hist> Cambridge. ''A Brief History of the Universe'' [Online]. Available: http://www.damtp.cam.ac.uk/research/gr/public/bb_history.html</ref> Physicists use this model to explain when the [[fundamental force]]s appear that govern how everything in the universe interacts.</onlyinclude> | <onlyinclude>The '''Big Bang''' is what scientists call the enormous explosion that started time, space, and the universe.<ref>Cambridge. ''Hot Big Bang'' [Online]. Available:http://www.damtp.cam.ac.uk/research/gr/public/bb_home.html</ref> The explosion started out extremely [[density|dense]] and hot, before rapidly cooling down. To this day space remains a few [[kelvin]] above [[absolute zero]] because of the initial [[temperature]] of the Big Bang.<ref name=hist> Cambridge. ''A Brief History of the Universe'' [Online]. Available: http://www.damtp.cam.ac.uk/research/gr/public/bb_history.html</ref> Physicists use this model to explain when the [[fundamental force]]s appear that govern how everything in the universe interacts.</onlyinclude> | ||
Latest revision as of 00:03, 27 September 2021
The Big Bang is what scientists call the enormous explosion that started time, space, and the universe.[1] The explosion started out extremely dense and hot, before rapidly cooling down. To this day space remains a few kelvin above absolute zero because of the initial temperature of the Big Bang.[2] Physicists use this model to explain when the fundamental forces appear that govern how everything in the universe interacts.
This event happened 13.8 billion years ago (see interactive visualization below, or the time scale of the universe)[2]. All energy and mass in the universe was created directly or indirectly as a result of this event.[3] This should not be confused with the explosion of a star 5 billion years ago that created the solar system (please see NASA's birth of worlds).
For more information about the Big Bang please see Space.com's explanation. For information on what the universe looked like for the 'First three minutes' please see hyperphysics, or Weinberg's 'First three minutes'.[4]
For Further Reading
- Time scale of the universe
- Absolute zero
- Planet
- Geologic time scale
- Solar system
- Or explore a random page
References
- ↑ Cambridge. Hot Big Bang [Online]. Available:http://www.damtp.cam.ac.uk/research/gr/public/bb_home.html
- ↑ 2.0 2.1 Cambridge. A Brief History of the Universe [Online]. Available: http://www.damtp.cam.ac.uk/research/gr/public/bb_history.html
- ↑ Cambridge. Four Pillars of Standard Cosmology [Online]. Avaliable: http://www.damtp.cam.ac.uk/research/gr/public/bb_pillars.html
- ↑ "The First Three Minutes" Steven Weinberg, 1993, Basic Books.