Chromatography detector - Revision history

Shawndouglas: references

2022-01-10T21:51:10Z

references

← Older revision		Revision as of 21:51, 10 January 2022
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	==References==		==References==
	~~<references />~~		{{Reflist\|colwidth=30em}}

	<!---Place all category tags here-->		<!---Place all category tags here-->
	[[Category:Chromatography]]		[[Category:Chromatography]]
	[[Category:Chromatography laboratory equipment]]		[[Category:Chromatography laboratory equipment]]

Shawndouglas: Updated URLs for 2022

2022-01-10T21:50:21Z

Updated URLs for 2022

Shawndouglas: Added cat

2014-08-04T22:42:19Z

Added cat

← Older revision		Revision as of 22:42, 4 August 2014
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	<references />		<references />

			<!---Place all category tags here-->
	[[Category:Chromatography]]		[[Category:Chromatography]]
			[[Category:Chromatography laboratory equipment]]

Shawndouglas: Added attribution.

2014-04-24T22:18:55Z

Added attribution.

← Older revision		Revision as of 22:18, 24 April 2014
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	* [http://www.chromatography-online.org/2/contents.html Chromatography-Online.org: Gas Chromatography Detectors]		* [http://www.chromatography-online.org/2/contents.html Chromatography-Online.org: Gas Chromatography Detectors]
	* [http://www.chromatography-online.org/5/contents.html Chromatography-Online.org: Liquid Chromatography Detectors]		* [http://www.chromatography-online.org/5/contents.html Chromatography-Online.org: Liquid Chromatography Detectors]

			==Notes==

			A couple elements of this article are reused from [http://en.wikipedia.org/wiki/Chromatography_detector the Wikipedia article].

	==References==		==References==
	~~{{Reflist}}~~		<references />

	[[Category:Chromatography]]		[[Category:Chromatography]]

Shawndouglas: Internal link.

2013-09-13T22:17:15Z

Internal link.

← Older revision		Revision as of 22:17, 13 September 2013
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	* Flame photometric detector: Column eluate is burned in a hydrogen flame. The light of the flame is filtered through an optical filter, allowing the detection of sulfur and phosphorus.		* Flame photometric detector: Column eluate is burned in a hydrogen flame. The light of the flame is filtered through an optical filter, allowing the detection of sulfur and phosphorus.
	* Atomic-emission detector: The column effluent is injected into plasma and the plasma spectrum is recorded. This detector allows for immediate determination of the elements present in the analyte.<ref name="Zall">{{cite journal\|journal=Journal of Analytical Chemistry\|year=2007\|pages=1069–1074\|title=Using gas chromatography with atomic emission detection for determining organic pollutants in water \|author=Vozhdaeva, M. Y., L. G. Tsypysheva, L. I. Kantor, and E. A. Kantor \|url=http://www.springerlink.com/content/dwt287h196g4v622/}}</ref>		* Atomic-emission detector: The column effluent is injected into plasma and the plasma spectrum is recorded. This detector allows for immediate determination of the elements present in the analyte.<ref name="Zall">{{cite journal\|journal=Journal of Analytical Chemistry\|year=2007\|pages=1069–1074\|title=Using gas chromatography with atomic emission detection for determining organic pollutants in water \|author=Vozhdaeva, M. Y., L. G. Tsypysheva, L. I. Kantor, and E. A. Kantor \|url=http://www.springerlink.com/content/dwt287h196g4v622/}}</ref>
	* Mass spectrometry detector: The column effluent is continuously injected into a [[Mass spectrometry\|mass spectrometer]]. This detector allows for immediate determination of the molecular weight of analyte and/or the fragmentation pattern, thus providing a significant amount of information about analyte.		* Mass spectrometry detector: The column effluent is continuously injected into a [[Mass spectrometry\|mass spectrometer]]. This detector allows for immediate determination of the molecular weight of analyte and/or the fragmentation pattern, thus providing a significant amount of [[information]] about analyte.
	* Nitrogen phosphorus detector: This detector is only used only in gas chromatography.		* Nitrogen phosphorus detector: This detector is only used only in gas chromatography.
	* Evaporative light scattering detector: The column effluent is continuously evaporated and the light scattering of the resulting aerosol is measured. This detector is only used in liquid chromatography.<ref>{{cite web_short\|url=http://www.cyberlipid.org/elsd/elsd0001.htm \|title=Light-scattering and Charged Aerosol Detectors \|publisher=CyberLipid.org \|date=31 March 2009\|accessdate=26 October 2011}}</ref>		* Evaporative light scattering detector: The column effluent is continuously evaporated and the light scattering of the resulting aerosol is measured. This detector is only used in liquid chromatography.<ref>{{cite web_short\|url=http://www.cyberlipid.org/elsd/elsd0001.htm \|title=Light-scattering and Charged Aerosol Detectors \|publisher=CyberLipid.org \|date=31 March 2009\|accessdate=26 October 2011}}</ref>

Shawndouglas: Updated article.

2011-10-26T21:21:36Z

Updated article.

← Older revision		Revision as of 21:21, 26 October 2011
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	A '''chromatography detector''' is a device used in [[gas chromatography]] (GC) or [[liquid chromatography]] (LC) to visualize components of the mixture being eluted off the chromatography column.		A '''chromatography detector''' is a device used in [[gas chromatography]] (GC) or [[liquid chromatography]] (LC) to visualize components of the mixture being eluted off the chromatography column.

	There are ~~two general types of~~ detectors: destructive ~~and~~ non-destructive. ~~A destructive detector performs continuous transformation of the column effluent (by burning, evaporating, or mixing with reagents), with a subsequent measurement of some physical~~ property ~~of the resulting material (plasma~~, ~~aerosol~~, ~~or reaction mixture)~~. ~~A non-destructive detector directly measures some property of~~ the ~~column effluent (UV absorption~~, ~~for example) and thus affords for further analyte recovery~~.		There are as many as five ways to classify detectors: concentration vs. mass flow rate; selective vs. universal; destructive vs. non-destructive; bulk property vs. specific property; and analog vs. digital.<ref name="Basic GC">{{cite book\|title=Basic Gas Chromatography \|author=McNair, Harold Monroe and James M. Miller \|chapter=Chapter 7: Detectors \|year=2009\|pages=105–108 \|publisher=John Wiley and Sons \|url=http://books.google.com/books?id=c-91tOmFv28C \|isbn=0470439548}}</ref><ref name="ConceptsContrasts">{{cite book\|title=Chromatography: Concepts and Contrasts \|author=Miller, James M. \|chapter=Chapter 9: Quantitation: Detectors and Methods \|year=2005\|pages=278–284 \|publisher=John Wiley and Sons \|url=http://books.google.com/books?id=22CUlzjAmScC \|isbn=0471472077}}</ref> Of the five classification systems listed, the first three are the most important.<ref name="Basic GC" />

	==Destructive ~~detector~~==		==Concentration vs. mass flow rate==

			This classification differentiates between detectors that measure the concentration of analyte in the carrier gas versus those that take a direct measurement of the absolute amount of analyte regardless of the volume of the carrier gas.<ref name="Basic GC" /><ref name="ConceptsContrasts" />

			==Selective vs. universal==

			This classification differentiates between detectors based on the percentage of analyte capable of being detected by the system. Selective systems will only respond to a particular types or classes of compounds, while a universal system will generally be able to detect all solutes.<ref name="Basic GC" /><ref name="ConceptsContrasts" />

			==Destructive vs. non-destructive==

			A destructive detector performs continuous transformation of the column effluent (by burning, evaporating, or mixing with reagents), with a subsequent measurement of some physical property of the resulting material (plasma, aerosol, or reaction mixture). A non-destructive detector directly measures some property of the column effluent (UV absorption, for example) and thus affords for further analyte recovery.

	Examples of destructive detectors include:		Examples of destructive detectors include:

	* Flame ionization detector: The column effluent is injected into hydrogen flame and the flame conductivity is measured. This detector is only used in gas chromatography.		* Flame ionization detector: The column effluent is injected into hydrogen flame and the flame conductivity is measured. This detector is only used in gas chromatography.
	* Flame photometric detector: Column eluate is burned in a hydrogen flame. The light of the flame is filtered through an optical filter, allowing the detection of sulfur and phosphorus.		* Flame photometric detector: Column eluate is burned in a hydrogen flame. The light of the flame is filtered through an optical filter, allowing the detection of sulfur and phosphorus.
Line 13:		Line 24:
	* Evaporative light scattering detector: The column effluent is continuously evaporated and the light scattering of the resulting aerosol is measured. This detector is only used in liquid chromatography.<ref>{{cite web_short\|url=http://www.cyberlipid.org/elsd/elsd0001.htm \|title=Light-scattering and Charged Aerosol Detectors \|publisher=CyberLipid.org \|date=31 March 2009\|accessdate=26 October 2011}}</ref>		* Evaporative light scattering detector: The column effluent is continuously evaporated and the light scattering of the resulting aerosol is measured. This detector is only used in liquid chromatography.<ref>{{cite web_short\|url=http://www.cyberlipid.org/elsd/elsd0001.htm \|title=Light-scattering and Charged Aerosol Detectors \|publisher=CyberLipid.org \|date=31 March 2009\|accessdate=26 October 2011}}</ref>

	~~==Non~~-destructive ~~detector==~~		Examples of non-destructive detectors include:

	~~Examples of non-destructive detectors include:~~
	* Ultraviolet detector: This detector works on either a fixed or variable wavelength. The UV absorption of the effluent is continuously measured at single or multiple wavelengths. A diode array detector (DAD or PDA) is an example of an ultraviolet detector. Ultraviolet detectors are typically the most popular detectors for liquid chromatography.<ref>{{cite web_short\|url=http://www.reachdevices.com/Commercial_UV_detectors.html \|title=Comparative table of commercial UV detectors \|publisher=REACH Devices \|date=09 October 2011\|accessdate=26 October 2011}}</ref>		* Ultraviolet detector: This detector works on either a fixed or variable wavelength. The UV absorption of the effluent is continuously measured at single or multiple wavelengths. A diode array detector (DAD or PDA) is an example of an ultraviolet detector. Ultraviolet detectors are typically the most popular detectors for liquid chromatography.<ref>{{cite web_short\|url=http://www.reachdevices.com/Commercial_UV_detectors.html \|title=Comparative table of commercial UV detectors \|publisher=REACH Devices \|date=09 October 2011\|accessdate=26 October 2011}}</ref>
	* Thermal conductivity detector: This detector measures the thermal conductivity of the effluent and is only used in gas chromatography.		* Thermal conductivity detector: This detector measures the thermal conductivity of the effluent and is only used in gas chromatography.

Shawndouglas: Updated article.

2011-10-26T20:02:30Z

Updated article.

← Older revision		Revision as of 20:02, 26 October 2011
Line 1:		Line 1:
	A '''chromatography detector''' is a device used in [[gas chromatography]] (GC) or [[liquid chromatography]] (LC) to visualize components of the mixture being eluted off the chromatography column.		A '''chromatography detector''' is a device used in [[gas chromatography]] (GC) or [[liquid chromatography]] (LC) to visualize components of the mixture being eluted off the chromatography column.

			There are two general types of detectors: destructive and non-destructive. A destructive detector performs continuous transformation of the column effluent (by burning, evaporating, or mixing with reagents), with a subsequent measurement of some physical property of the resulting material (plasma, aerosol, or reaction mixture). A non-destructive detector directly measures some property of the column effluent (UV absorption, for example) and thus affords for further analyte recovery.

			==Destructive detector==

			Examples of destructive detectors include:
			* Flame ionization detector: The column effluent is injected into hydrogen flame and the flame conductivity is measured. This detector is only used in gas chromatography.
			* Flame photometric detector: Column eluate is burned in a hydrogen flame. The light of the flame is filtered through an optical filter, allowing the detection of sulfur and phosphorus.
			* Atomic-emission detector: The column effluent is injected into plasma and the plasma spectrum is recorded. This detector allows for immediate determination of the elements present in the analyte.<ref name="Zall">{{cite journal\|journal=Journal of Analytical Chemistry\|year=2007\|pages=1069–1074\|title=Using gas chromatography with atomic emission detection for determining organic pollutants in water \|author=Vozhdaeva, M. Y., L. G. Tsypysheva, L. I. Kantor, and E. A. Kantor \|url=http://www.springerlink.com/content/dwt287h196g4v622/}}</ref>
			* Mass spectrometry detector: The column effluent is continuously injected into a [[Mass spectrometry\|mass spectrometer]]. This detector allows for immediate determination of the molecular weight of analyte and/or the fragmentation pattern, thus providing a significant amount of information about analyte.
			* Nitrogen phosphorus detector: This detector is only used only in gas chromatography.
			* Evaporative light scattering detector: The column effluent is continuously evaporated and the light scattering of the resulting aerosol is measured. This detector is only used in liquid chromatography.<ref>{{cite web_short\|url=http://www.cyberlipid.org/elsd/elsd0001.htm \|title=Light-scattering and Charged Aerosol Detectors \|publisher=CyberLipid.org \|date=31 March 2009\|accessdate=26 October 2011}}</ref>

			==Non-destructive detector==

			Examples of non-destructive detectors include:
			* Ultraviolet detector: This detector works on either a fixed or variable wavelength. The UV absorption of the effluent is continuously measured at single or multiple wavelengths. A diode array detector (DAD or PDA) is an example of an ultraviolet detector. Ultraviolet detectors are typically the most popular detectors for liquid chromatography.<ref>{{cite web_short\|url=http://www.reachdevices.com/Commercial_UV_detectors.html \|title=Comparative table of commercial UV detectors \|publisher=REACH Devices \|date=09 October 2011\|accessdate=26 October 2011}}</ref>
			* Thermal conductivity detector: This detector measures the thermal conductivity of the effluent and is only used in gas chromatography.
			* Fluorescence detector: Using the principle of [[fluorescence spectroscopy]], this detector irradiates effluent with a light of set wavelength and measures the fluorescence of the effluent at a single or multiple wavelength. It's only used in liquid chromatography.
			* Electron capture detector: This is the most sensitive detector known. Allows for the detection of organic molecules containing halogen, nitro groups, etc.
			* Conductivity monitor: This detector continuously measures the conductivity of the effluent. Used only in liquid chromatography when conductive eluates (water or alcohols) are used.<ref>{{cite web_short\|url=http://www.chromatography-online.org/HPLC/Electrical-Conductivity/rs29.html \|title=Liquid Chromatography: Electrical Conductivity \|publisher=Chromatography-Online.org \|accessdate=26 October 2011}}</ref>
			* Refractive index detector: This detector continuously measures the refractive index of the effluent, and it's used only in liquid chromatography. The lowest sensitivity of all detectors. Useful when nothing else works and at high analyte concentrations.
			* Radio flow detector: This detector measures radioactivity of the effluent. This detector can be destructive if a [[Liquid scintillation counting\|scintillation cocktail]] is continuously added to the effluent.
			* Chiral detector: This detector continuously measures the [[Optical activity\|optical angle of rotation]] of the eluent. Used only in liquid chromatography when chiral compounds are being analyzed.

			==Further reading==

			* [http://www.chromatography-online.org/2/contents.html Chromatography-Online.org: Gas Chromatography Detectors]
			* [http://www.chromatography-online.org/5/contents.html Chromatography-Online.org: Liquid Chromatography Detectors]

			==References==
			{{Reflist}}

			[[Category:Chromatography]]

Shawndouglas: Created stub.

2011-09-23T19:19:10Z

Created stub.

New page

A '''chromatography detector''' is a device used in [[gas chromatography]] (GC) or [[liquid chromatography]] (LC) to visualize components of the mixture being eluted off the chromatography column.

← Older revision		Revision as of 21:50, 10 January 2022
Line 1:		Line 1:
	A '''chromatography detector''' is a device used in [[gas chromatography]] (GC) or [[liquid chromatography]] (LC) to visualize components of the mixture being eluted off the chromatography column.		A '''chromatography detector''' is a device used in [[gas chromatography]] (GC) or [[liquid chromatography]] (LC) to visualize components of the mixture being eluted off the chromatography column.

	There are as many as five ways to classify detectors: concentration vs. mass flow rate; selective vs. universal; destructive vs. non-destructive; bulk property vs. specific property; and analog vs. digital.<ref name="Basic GC">{{cite book\|title=Basic Gas Chromatography \|author=McNair, Harold Monroe and James M. Miller \|chapter=Chapter 7: Detectors \|year=2009\|pages=105–108 \|publisher=John Wiley and Sons \|url=~~http~~://books.google.com/books?id=c-91tOmFv28C \|isbn=0470439548}}</ref><ref name="ConceptsContrasts">{{cite book\|title=Chromatography: Concepts and Contrasts \|author=Miller, James M. \|chapter=Chapter 9: Quantitation: Detectors and Methods \|year=2005\|pages=278–284 \|publisher=John Wiley and Sons \|url=~~http~~://books.google.com/books?id=22CUlzjAmScC \|isbn=0471472077}}</ref> Of the five classification systems listed, the first three are the most important.<ref name="Basic GC" />		There are as many as five ways to classify detectors: concentration vs. mass flow rate; selective vs. universal; destructive vs. non-destructive; bulk property vs. specific property; and analog vs. digital.<ref name="Basic GC">{{cite book \|title=Basic Gas Chromatography \|author=McNair, Harold Monroe and James M. Miller \|chapter=Chapter 7: Detectors \|year=2009\|pages=105–108 \|publisher=John Wiley and Sons \|url=https://books.google.com/books?id=c-91tOmFv28C \|isbn=0470439548}}</ref><ref name="ConceptsContrasts">{{cite book \|title=Chromatography: Concepts and Contrasts \|author=Miller, James M. \|chapter=Chapter 9: Quantitation: Detectors and Methods \|year=2005\|pages=278–284 \|publisher=John Wiley and Sons \|url=https://books.google.com/books?id=22CUlzjAmScC \|isbn=0471472077}}</ref> Of the five classification systems listed, the first three are the most important.<ref name="Basic GC" />

	==Concentration vs. mass flow rate==		==Concentration vs. mass flow rate==
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	* Flame ionization detector: The column effluent is injected into hydrogen flame and the flame conductivity is measured. This detector is only used in gas chromatography.		* Flame ionization detector: The column effluent is injected into hydrogen flame and the flame conductivity is measured. This detector is only used in gas chromatography.
	* Flame photometric detector: Column eluate is burned in a hydrogen flame. The light of the flame is filtered through an optical filter, allowing the detection of sulfur and phosphorus.		* Flame photometric detector: Column eluate is burned in a hydrogen flame. The light of the flame is filtered through an optical filter, allowing the detection of sulfur and phosphorus.
	* Atomic-emission detector: The column effluent is injected into plasma and the plasma spectrum is recorded. This detector allows for immediate determination of the elements present in the analyte.<ref name="Zall">{{cite journal~~\|journal=Journal of Analytical Chemistry\|year=2007\|pages=1069–1074~~\|title=Using gas chromatography with atomic emission detection for determining organic pollutants in water \|author=Vozhdaeva, M. Y., L. G. Tsypysheva, L. I. Kantor, and E. A. Kantor \|~~url~~=~~http://www.springerlink~~.~~com/content/dwt287h196g4v622~~/}}</ref>		* Atomic-emission detector: The column effluent is injected into plasma and the plasma spectrum is recorded. This detector allows for immediate determination of the elements present in the analyte.<ref name="Zall">{{cite journal \|title=Using gas chromatography with atomic emission detection for determining organic pollutants in water \|journal=Journal of Analytical Chemistry \|author=Vozhdaeva, M. Y., L. G. Tsypysheva, L. I. Kantor, and E. A. Kantor \|volume=61 \|issue=11 \|pages=1069–1074 \|year=2007 \|doi=10.1134/S1061934807110111}}</ref>
	* Mass spectrometry detector: The column effluent is continuously injected into a [[Mass spectrometry\|mass spectrometer]]. This detector allows for immediate determination of the molecular weight of analyte and/or the fragmentation pattern, thus providing a significant amount of [[information]] about analyte.		* Mass spectrometry detector: The column effluent is continuously injected into a [[Mass spectrometry\|mass spectrometer]]. This detector allows for immediate determination of the molecular weight of analyte and/or the fragmentation pattern, thus providing a significant amount of [[information]] about analyte.
	* Nitrogen phosphorus detector: This detector is only used only in gas chromatography.		* Nitrogen phosphorus detector: This detector is only used only in gas chromatography.
	* Evaporative light scattering detector: The column effluent is continuously evaporated and the light scattering of the resulting aerosol is measured. This detector is only used in liquid chromatography.<ref>{{cite ~~web_short~~\|url=~~http~~://~~www~~.~~cyberlipid~~.~~org~~/~~elsd~~/~~elsd0001.htm~~ \|title=Light-scattering and Charged Aerosol Detectors \|publisher=CyberLipid.org \|date=31 March 2009\|accessdate=~~26 October 2011~~}}</ref>		* Evaporative light scattering detector: The column effluent is continuously evaporated and the light scattering of the resulting aerosol is measured. This detector is only used in liquid chromatography.<ref>{{cite web \|url=https://cyberlipid.gerli.com/techniques-of-analysis/fractionation-complex-extracts/light-scattering-detector/ \|title=Light-scattering and Charged Aerosol Detectors \|publisher=CyberLipid.org \|date=31 March 2009 \|accessdate=10 January 2022}}</ref>

	Examples of non-destructive detectors include:		Examples of non-destructive detectors include:

	* Ultraviolet detector: This detector works on either a fixed or variable wavelength. The UV absorption of the effluent is continuously measured at single or multiple wavelengths. A diode array detector (DAD or PDA) is an example of an ultraviolet detector. Ultraviolet detectors are typically the most popular detectors for liquid chromatography.<ref>{{cite ~~web_short~~\|url=http://www.reachdevices.com/Commercial_UV_detectors.html \|title=Comparative table of commercial UV detectors \|publisher=REACH Devices \|date=09 October 2011\|accessdate=~~26 October 2011~~}}</ref>		* Ultraviolet detector: This detector works on either a fixed or variable wavelength. The UV absorption of the effluent is continuously measured at single or multiple wavelengths. A diode array detector (DAD or PDA) is an example of an ultraviolet detector. Ultraviolet detectors are typically the most popular detectors for liquid chromatography.<ref>{{cite web \|url=http://www.reachdevices.com/Commercial_UV_detectors.html \|archiveurl=https://web.archive.org/web/20160206123453/http://www.reachdevices.com/Commercial_UV_detectors.html \|title=Comparative table of commercial UV detectors \|publisher=REACH Devices \|date=09 October 2011 \|archivedate=06 February 2016 \|accessdate=10 January 2022}}</ref>
	* Thermal conductivity detector: This detector measures the thermal conductivity of the effluent and is only used in gas chromatography.		* Thermal conductivity detector: This detector measures the thermal conductivity of the effluent and is only used in gas chromatography.
	* Fluorescence detector: Using the principle of [[fluorescence spectroscopy]], this detector irradiates effluent with a light of set wavelength and measures the fluorescence of the effluent at a single or multiple wavelength. It's only used in liquid chromatography.		* Fluorescence detector: Using the principle of [[fluorescence spectroscopy]], this detector irradiates effluent with a light of set wavelength and measures the fluorescence of the effluent at a single or multiple wavelength. It's only used in liquid chromatography.
	* Electron capture detector: This is the most sensitive detector known. Allows for the detection of organic molecules containing halogen, nitro groups, etc.		* Electron capture detector: This is the most sensitive detector known. Allows for the detection of organic molecules containing halogen, nitro groups, etc.
	* Conductivity monitor: This detector continuously measures the conductivity of the effluent. Used only in liquid chromatography when conductive eluates (water or alcohols) are used.<ref>{{cite ~~web_short~~\|url=http://www.chromatography-online.org/HPLC/Electrical-Conductivity/rs29.html \|title=Liquid Chromatography: Electrical Conductivity \|publisher=Chromatography-Online.org \|accessdate=~~26 October 2011~~}}</ref>		* Conductivity monitor: This detector continuously measures the conductivity of the effluent. Used only in liquid chromatography when conductive eluates (water or alcohols) are used.<ref>{{cite web \|url=http://www.chromatography-online.org/HPLC/Electrical-Conductivity/rs29.html \|archiveurl=https://web.archive.org/web/20120312011151/http://www.chromatography-online.org/HPLC/Electrical-Conductivity/rs29.html \|title=Liquid Chromatography: Electrical Conductivity \|publisher=Chromatography-Online.org \|archivedate=12 March 2012 \|accessdate=10 January 2022}}</ref>
	* Refractive index detector: This detector continuously measures the refractive index of the effluent, and it's used only in liquid chromatography. The lowest sensitivity of all detectors. Useful when nothing else works and at high analyte concentrations.		* Refractive index detector: This detector continuously measures the refractive index of the effluent, and it's used only in liquid chromatography. The lowest sensitivity of all detectors. Useful when nothing else works and at high analyte concentrations.
	* Radio flow detector: This detector measures radioactivity of the effluent. This detector can be destructive if a [[Liquid scintillation counting\|scintillation cocktail]] is continuously added to the effluent.		* Radio flow detector: This detector measures radioactivity of the effluent. This detector can be destructive if a [[Liquid scintillation counting\|scintillation cocktail]] is continuously added to the effluent.
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	==Further reading==		==Further reading==

	* [http://www.chromatography-online.org/2/contents.html Chromatography-Online.org: Gas Chromatography Detectors]		* [https://web.archive.org/web/20110722014959/http://www.chromatography-online.org/2/contents.html Chromatography-Online.org: Gas Chromatography Detectors] (Archived)
	* [http://www.chromatography-online.org/5/contents.html Chromatography-Online.org: Liquid Chromatography Detectors]		* [https://web.archive.org/web/20120323191635/http://www.chromatography-online.org/5/contents.html Chromatography-Online.org: Liquid Chromatography Detectors] (Archived)

	==Notes==		==Notes==

	A couple elements of this article are reused from [~~http~~://en.wikipedia.org/wiki/Chromatography_detector the Wikipedia article].		A couple elements of this article are reused from [https://en.wikipedia.org/wiki/Chromatography_detector the Wikipedia article].

	==References==		==References==