Redshift: Difference between revisions
imported>Thomas Simmons No edit summary |
imported>Ro Thorpe mNo edit summary |
||
Line 3: | Line 3: | ||
'''Redshift''' is a term commonly used in [[Astronomy]] and [[Physics]] to refer to the [[phenomenon]] by which [[electromagnetic radiation| electromagnetic radiation's]] observed [[wavelength]] increases, thereby causing an apparent decrease in the observed [[frequency]]. Generally, redshift occurs for one (or both) of two reasons: | '''Redshift''' is a term commonly used in [[Astronomy]] and [[Physics]] to refer to the [[phenomenon]] by which [[electromagnetic radiation| electromagnetic radiation's]] observed [[wavelength]] increases, thereby causing an apparent decrease in the observed [[frequency]]. Generally, redshift occurs for one (or both) of two reasons: | ||
1. The distance between the source and the observer of the electromagnetic radiation is increasing, thus causing an apparent increase in wavelength. This is commonly referred to as the [[Doppler | 1. The distance between the source and the observer of the electromagnetic radiation is increasing, thus causing an apparent increase in wavelength. This is commonly referred to as the [[Doppler effect]]. | ||
2. The observer is in a stronger [[gravitation| gravitational field]] than the source, and the wavelength's increase can be attributed to [[Special_relativity#Time_dilation| gravitational time dilation]] as predicted by [[Albert Einstein]] in his Theory of [[Special Relativity]]. | 2. The observer is in a stronger [[gravitation| gravitational field]] than the source, and the wavelength's increase can be attributed to [[Special_relativity#Time_dilation| gravitational time dilation]] as predicted by [[Albert Einstein]] in his Theory of [[Special Relativity]]. | ||
There is, naturally, an opposite effect observed when the change in wavelength is a decrease, and this is commonly referred to as [[ | There is, naturally, an opposite effect observed when the change in wavelength is a decrease, and this is commonly referred to as [[blueshift]]. | ||
z is the symbol designating the amount of redshift. The most distant known galaxies and quasars have values of z = 6 or greater.<ref>[http://universe.nasa.gov/resources/glossary.html#Quantum%20Mechanics Glossary of terms] Beyond Einstein, NASA</ref> | z is the symbol designating the amount of redshift. The most distant known galaxies and quasars have values of z = 6 or greater.<ref>[http://universe.nasa.gov/resources/glossary.html#Quantum%20Mechanics Glossary of terms] Beyond Einstein, NASA</ref> |
Revision as of 17:29, 7 June 2009
Redshift is a term commonly used in Astronomy and Physics to refer to the phenomenon by which electromagnetic radiation's observed wavelength increases, thereby causing an apparent decrease in the observed frequency. Generally, redshift occurs for one (or both) of two reasons:
1. The distance between the source and the observer of the electromagnetic radiation is increasing, thus causing an apparent increase in wavelength. This is commonly referred to as the Doppler effect.
2. The observer is in a stronger gravitational field than the source, and the wavelength's increase can be attributed to gravitational time dilation as predicted by Albert Einstein in his Theory of Special Relativity.
There is, naturally, an opposite effect observed when the change in wavelength is a decrease, and this is commonly referred to as blueshift.
z is the symbol designating the amount of redshift. The most distant known galaxies and quasars have values of z = 6 or greater.[1]
References
- ↑ Glossary of terms Beyond Einstein, NASA