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[[Image:M81 wide Galex.jpg|thumb|A [[GALEX]] image of the [[spiral galaxy]] [[Messier 81]] in [[ultraviolet]] light. Credit:GALEX/[[NASA]]/[[JPL]]-[[Caltech]].]]
[[Image:M81 wide Galex.jpg|thumb|A [[GALEX]] image of the [[spiral galaxy]] [[Messier 81]] in [[ultraviolet]] light. Credit:GALEX/[[NASA]]/[[JPL]]-[[Caltech]].]]


'''Ultraviolet astronomy''' is the observation of [[electromagnetic radiation]] at [[ultraviolet]] wavelengths between approximately 10 and 320 nanometres; shorter wavelengths&mdash;higher energy photons&mdash;are studied by [[X-ray astronomy]] and [[gamma ray astronomy]].<ref name="cox2000">{{cite book
'''Ultraviolet astronomy''' is the observation of [[electromagnetic radiation]] at [[ultraviolet]] wavelengths between approximately 10 and 320 [[Nanometre|nanometres]]; shorter wavelengths&mdash;higher energy photons&mdash;are studied by [[X-ray astronomy]] and [[gamma ray astronomy]].<ref name="cox2000">{{cite book
| editor=A. N. Cox
| editor=A. N. Cox
| title=Allen's Astrophysical Quantities
| title=Allen's Astrophysical Quantities
Line 7: Line 7:
| publisher=Springer-Verlag
| publisher=Springer-Verlag
| location=New York
| location=New York
| isbn=0-387-98746-0}}</ref> An ultraviolet light is not visible to the human eye.<ref>{{cite web|url=https://science.ksc.nasa.gov/mirrors/msfc/description/ultraviolet.html}}</ref> Light at these wavelengths is absorbed by the Earth's atmosphere, so observations at these wavelengths must be performed from the upper atmosphere or from space.<ref name="cox2000"/>
| isbn=0-387-98746-0}}</ref> Ultraviolet light is not visible to the [[human eye]].<ref>{{cite web|url=https://science.ksc.nasa.gov/mirrors/msfc/description/ultraviolet.html}}</ref> Most of the light at these wavelengths is absorbed by the Earth's atmosphere, so observations at these wavelengths must be performed from the upper atmosphere or from space.<ref name="cox2000"/>


==Overview==
==Overview==
Ultraviolet line spectrum measurements are used to discern the chemical composition, densities, and temperatures of the [[interstellar medium]], and the temperature and composition of hot young stars. UV observations can also provide essential information about the [[Galaxy formation and evolution|evolution of galaxies]].
Ultraviolet [[Spectral line|line spectrum]] measurements ([[Astronomical spectroscopy|spectroscopy]]) are used to discern the chemical composition, densities, and temperatures of the [[interstellar medium]], and the temperature and composition of hot young stars. UV observations can also provide essential information about the [[Galaxy formation and evolution|evolution of galaxies]].


The ultraviolet [[Universe]] looks quite different from the familiar [[star]]s and [[galaxy|galaxies]] seen in [[visible light]].
The ultraviolet [[universe]] looks quite different from the familiar [[star]]s and [[galaxy|galaxies]] seen in [[visible light]].
Most stars are actually relatively cool objects emitting much of their electromagnetic radiation in the visible or near-infrared part of the spectrum. Ultraviolet radiation is the signature of hotter objects, typically in the early and late stages of their [[stellar evolution|evolution]]. In the Earth's sky seen in ultraviolet light, most stars would fade in prominence. Some very young massive stars and some very old stars and galaxies, growing hotter and producing higher-energy radiation near their birth or death, would be visible. Clouds of gas and dust would block the vision in many directions along the [[Milky Way]].
Most stars are actually relatively cool objects emitting much of their electromagnetic radiation in the visible or near-[[infrared]] part of the spectrum. Ultraviolet radiation is the signature of hotter objects, typically in the early and late stages of their [[stellar evolution|evolution]]. In the Earth's sky seen in ultraviolet light, most stars would fade in prominence. Some very young massive stars and some very old stars and galaxies, growing hotter and producing higher-energy radiation near their birth or death, would be visible. Clouds of gas and dust would block the vision in many directions along the [[Milky Way]].


Space-based solar observatories such as [[Solar Dynamics Observatory|SDO]] and [[Solar and Heliospheric Observatory|SOHO]] use ultraviolet telescopes (called [[Solar Dynamics Observatory#Atmospheric Imaging Assembly (AIA)|AIA]] and [[Extreme ultraviolet Imaging Telescope|EIT]], respectively) to view activity on the Sun and its [[corona]]. Weather satellites such as the [[Geostationary Operational Environmental Satellite|GOES-R]] series also carry [[GOES-16#Sun-facing|telescopes]] for observing the sun in ultraviolet.
The [[Hubble Space Telescope]] and [[Far Ultraviolet Spectroscopic Explorer|FUSE]] have been the most recent major [[space telescope]]s to view the near and far UV [[Electromagnetic spectrum|spectrum]] of the sky, though other UV instruments have flown on [[sounding rockets]] and the [[Space Shuttle]].

The [[Hubble Space Telescope]] and [[Far Ultraviolet Spectroscopic Explorer|FUSE]] have been the most recent major [[space telescope]]s to view the near and far UV [[Electromagnetic spectrum|spectrum]] of the sky, though other UV instruments have flown on smaller observatories such as [[GALEX]], as well as [[sounding rockets]] and the [[Space Shuttle]].


[[Charles Stuart Bowyer]] is generally given credit for starting this field.
[[Charles Stuart Bowyer]] is generally given credit for starting this field.
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*{{flagicon|United States}} - [[Hopkins Ultraviolet Telescope]] (flew in 1990 and 1995)
*{{flagicon|United States}} - [[Hopkins Ultraviolet Telescope]] (flew in 1990 and 1995)
*{{flagicon|Germany}} - [[ROSAT]] XUV<ref>[http://iraf.noao.edu/iraf/ftp/iraf/conf/web/adass_proc/adass_95/staubertr/staubertr.html R. Staubert, H. Brunner,1 H.-C. Kreysing - The German ROSAT XUV Data Center and a ROSAT XUV Pointed Phase Source Catalogue (1996)]</ref> (17-210eV) (30-6&nbsp;nm, 1990-1999)
*{{flagicon|Germany}} - [[ROSAT]] XUV<ref>[http://iraf.noao.edu/iraf/ftp/iraf/conf/web/adass_proc/adass_95/staubertr/staubertr.html R. Staubert, H. Brunner,1 H.-C. Kreysing - The German ROSAT XUV Data Center and a ROSAT XUV Pointed Phase Source Catalogue (1996)]</ref> (17-210eV) (30-6&nbsp;nm, 1990-1999)
*{{flagicon|United States}} - [[Far Ultraviolet Spectroscopic Explorer]] (1999-2007)
*{{flagicon|United States}} - [[Far Ultraviolet Spectroscopic Explorer]] (1999-2007)
*{{flagicon|United States}} - [[Galaxy Evolution Explorer]] (2003-2012)
*{{flagicon|United States}} - [[Galaxy Evolution Explorer]] (2003-2012)
*{{flagicon|Japan}} - [[Hisaki (satellite)|Hisaki]] (130-530&nbsp;nm, 2013 -)
*{{flagicon|Japan}} - [[Hisaki (satellite)|Hisaki]] (130-530&nbsp;nm, 2013 -)
*{{flagicon|China}} - [[Chang'e 3#Lunar-based ultraviolet telescope (LUT) | Lunar-based ultraviolet telescope (LUT)]] (on [[Chang'e 3]] lunar lander, 245-340 &nbsp;nm, 2013 -)
*{{flagicon|China}} - [[Chang'e 3#Lunar-based ultraviolet telescope (LUT) |Lunar-based ultraviolet telescope (LUT)]] (on [[Chang'e 3]] lunar lander, 245-340 &nbsp;nm, 2013 -)
*{{flagicon|India}} - [[Astrosat]] (130-530&nbsp;nm, 2015 -)
*{{flagicon|India}} - [[Astrosat]] (130-530&nbsp;nm, 2015 -)
*{{flagicon|Germany}} - [[Public Telescope|Public Telescope (PST)]]<ref>[http://www.publictelescope.org Public Telescope Project]</ref><ref>[http://www.publictelescope.org/wp-content/uploads/2015/02/2015-02-Popular-Astronomy-UK.pdf The first public space telescope] Popular Astronomy UK</ref><ref>[http://www.spektrum.de/news/ein-privates-weltraumteleskope-fuer-amateure-und-profis/1352064 Ein privates Weltraumteleskope für Amateure und Profis] Spektrum DE</ref> (100-180&nbsp;nm, Launch planned 2019)
*{{flagicon|Germany}} - [[Public Telescope|Public Telescope (PST)]]<ref>[http://www.publictelescope.org Public Telescope Project]</ref><ref>[http://www.publictelescope.org/wp-content/uploads/2015/02/2015-02-Popular-Astronomy-UK.pdf The first public space telescope] Popular Astronomy UK</ref><ref>[http://www.spektrum.de/news/ein-privates-weltraumteleskope-fuer-amateure-und-profis/1352064 Ein privates Weltraumteleskope für Amateure und Profis] Spektrum DE</ref> (100-180&nbsp;nm, Launch planned 2019)
*{{flagicon|United States}} - [[Waypoint-1 satellite|Waypoint-1 SpaceFab.US]](200-950&nbsp;nm EMCCD, Launch planned 2019)<ref>http://www.spacefab.us/space-telescopes.html</ref>
*{{flagicon|United States}} - [[Waypoint-1 satellite|Waypoint-1 SpaceFab.US]] (200-950&nbsp;nm EMCCD, Launch planned 2019)<ref>http://www.spacefab.us/space-telescopes.html</ref>


See also [[List of space telescopes#Ultraviolet|List of ultraviolet space telescopes]]
See also [[List of space telescopes#Ultraviolet|List of ultraviolet space telescopes]]

Revision as of 13:33, 7 October 2018

A GALEX image of the spiral galaxy Messier 81 in ultraviolet light. Credit:GALEX/NASA/JPL-Caltech.

Ultraviolet astronomy is the observation of electromagnetic radiation at ultraviolet wavelengths between approximately 10 and 320 nanometres; shorter wavelengths—higher energy photons—are studied by X-ray astronomy and gamma ray astronomy.[1] Ultraviolet light is not visible to the human eye.[2] Most of the light at these wavelengths is absorbed by the Earth's atmosphere, so observations at these wavelengths must be performed from the upper atmosphere or from space.[1]

Overview

Ultraviolet line spectrum measurements (spectroscopy) are used to discern the chemical composition, densities, and temperatures of the interstellar medium, and the temperature and composition of hot young stars. UV observations can also provide essential information about the evolution of galaxies.

The ultraviolet universe looks quite different from the familiar stars and galaxies seen in visible light. Most stars are actually relatively cool objects emitting much of their electromagnetic radiation in the visible or near-infrared part of the spectrum. Ultraviolet radiation is the signature of hotter objects, typically in the early and late stages of their evolution. In the Earth's sky seen in ultraviolet light, most stars would fade in prominence. Some very young massive stars and some very old stars and galaxies, growing hotter and producing higher-energy radiation near their birth or death, would be visible. Clouds of gas and dust would block the vision in many directions along the Milky Way.

Space-based solar observatories such as SDO and SOHO use ultraviolet telescopes (called AIA and EIT, respectively) to view activity on the Sun and its corona. Weather satellites such as the GOES-R series also carry telescopes for observing the sun in ultraviolet.

The Hubble Space Telescope and FUSE have been the most recent major space telescopes to view the near and far UV spectrum of the sky, though other UV instruments have flown on smaller observatories such as GALEX, as well as sounding rockets and the Space Shuttle.

Charles Stuart Bowyer is generally given credit for starting this field.

Andromeda Galaxy - in high-energy X-ray and ultraviolet light (released 5 January 2016).

Ultraviolet space telescopes

Astro 2 UIT captures M101 with ultraviolet shown in purple

See also List of ultraviolet space telescopes

Ultraviolet instruments on planetary spacecraft

  • United States - UVIS (Cassini) - 1997 (at Saturn from 2004-2017)
  • United States - MASCS (MESSENGER) - 2004 (at Mercury from 2011-2015)
  • United States - Alice (New Horizons) - 2006 (Pluto flyby in 2015)
  • United States - UVS (Juno) - 2011 (at Jupiter since 2016)
  • United States - IUVS (MAVEN) - 2013 (at Mars since 2014)

See also

Template:Wikipedia books

References

  1. ^ a b A. N. Cox, ed. (2000). Allen's Astrophysical Quantities. New York: Springer-Verlag. ISBN 0-387-98746-0.
  2. ^ https://science.ksc.nasa.gov/mirrors/msfc/description/ultraviolet.html. {{cite web}}: Missing or empty |title= (help)
  3. ^ R. Staubert, H. Brunner,1 H.-C. Kreysing - The German ROSAT XUV Data Center and a ROSAT XUV Pointed Phase Source Catalogue (1996)
  4. ^ Public Telescope Project
  5. ^ The first public space telescope Popular Astronomy UK
  6. ^ Ein privates Weltraumteleskope für Amateure und Profis Spektrum DE
  7. ^ http://www.spacefab.us/space-telescopes.html
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