Radiometer: Difference between revisions
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{{for|the specific radiometer that this term often refers to|Crookes radiometer}} | {{for|the specific radiometer that this term often refers to|Crookes radiometer}} | ||
[[Image:Crookes radiometer.jpg|thumb|210px|An example of a [[Crookes radiometer]]. The vanes rotate when exposed to light, with faster rotation for more intense light, providing a quantitative measurement of electromagnetic radiation intensity.]] | [[Image:Crookes radiometer.jpg|thumb|210px|An example of a [[Crookes radiometer]]. The vanes rotate when exposed to light, with faster rotation for more intense light, providing a quantitative measurement of electromagnetic radiation intensity.]] | ||
A '''radiometer | A '''radiometer''' is an instrument for measuring [[radiometry|radiometric]] quantities such as [[radiant flux]] (power), [[irradiance]], or [[radiance]].<ref name="e-ILV">{{cite encyclopedia |author=CIE |title=e-ILV, online version of CIE S 017:2020, International Lighting Vocabulary |edition=2 |url=https://cie.co.at/e-ilv |at=§17-25-006, radiometer |location=Vienna |publisher=[[International Commission on Illumination]] |year=2020 |access-date=19 Dec 2025}}</ref> Definitions typically limit radiometry to [[optical radiation]], but some definitions include other kinds of [[electromagnetic radiation]]. According to at least one instrument manufacturer, radiometers usually measure [[infrared radiation]] or [[ultraviolet|ultraviolet radiation]].<ref>{{cite web|url=http://sensing.konicaminolta.us/2013/11/what-is-the-difference-between-radiometers-spectrometers-and-spectroradiometers|title=What is the difference between radiometers, spectrometers, and spectroradiometers?|first=Konica Minolta|last=Sensing|website=Konica Minolta Sensing Americas|access-date=2014-01-20|archive-url=https://web.archive.org/web/20140203020939/http://sensing.konicaminolta.us/2013/11/what-is-the-difference-between-radiometers-spectrometers-and-spectroradiometers/|archive-date=2014-02-03|url-status=live}}</ref> | ||
[[Microwave radiometer]]s operate in the [[microwave]] wavelengths. A ''[[Roentgen (unit)|roentgenometer]]'' is a radiometer for measuring the intensity of X-rays or gamma radiation. | |||
While the term ''radiometer'' can refer to any device that measures electromagnetic radiation (e.g. light), the term is often used to refer specifically to a [[Crookes radiometer]] ("light-mill"), a device invented in 1873 in which a rotor (having vanes which are dark on one side, and light on the other) in a partial vacuum spins when exposed to light. | While the term ''radiometer'' can refer to any device that measures electromagnetic radiation (e.g. light), the term is often used to refer specifically to a [[Crookes radiometer]] ("light-mill"), a device invented in 1873 in which a rotor (having vanes which are dark on one side, and light on the other) in a partial vacuum spins when exposed to light. | ||
Latest revision as of 17:05, 19 December 2025
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A radiometer is an instrument for measuring radiometric quantities such as radiant flux (power), irradiance, or radiance.[1] Definitions typically limit radiometry to optical radiation, but some definitions include other kinds of electromagnetic radiation. According to at least one instrument manufacturer, radiometers usually measure infrared radiation or ultraviolet radiation.[2]
Microwave radiometers operate in the microwave wavelengths. A roentgenometer is a radiometer for measuring the intensity of X-rays or gamma radiation.
While the term radiometer can refer to any device that measures electromagnetic radiation (e.g. light), the term is often used to refer specifically to a Crookes radiometer ("light-mill"), a device invented in 1873 in which a rotor (having vanes which are dark on one side, and light on the other) in a partial vacuum spins when exposed to light. A common misbelief (one originally held even by Crookes) is that the momentum of the absorbed light on the black faces makes the radiometer operate. If this were true, however, the radiometer would spin away from the non-black faces, since the photons bouncing off those faces impart more momentum than the photons absorbed on the black faces. Photons do exert radiation pressure on the faces, but those forces are dwarfed by other effects. The currently accepted explanation depends on having just the right degree of vacuum, and relates to the transfer of heat rather than the direct effect of photons.[3][4]
A Nichols radiometer demonstrates photon pressure. It is much more sensitive than the Crookes radiometer and it operates in a complete vacuum, whereas operation of the Crookes radiometer requires an imperfect vacuum.
The MEMS radiometer can operate on the principles of Nichols or Crookes and can operate over a wide spectrum of wavelength and particle energy levels.[5]
See also
- Active cavity radiometer
- Bolometer
- Copernicus
- Net radiometer
- Photon rocket
- Pyranometer
- Radiation pressure
- Radiometry
- Solar sail
- Spectroradiometer
References
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