Difference between revisions of "PH sensors"

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Back to [[Instruments and sensors to measure environmental parameters]]
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See also: [[Instruments and sensors to measure environmental parameters]]
 
  
==Introduction==
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==General Description==
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pH measurements are predominantly conducted with pH-sensitive glass electrodes, which have, in general, proven satisfactory in measurements of pH. However, the behaviour of pH-sensitive glass electrodes often falls short of what precision is required.  
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Even with the most careful treatment, the potential of cells containing glass electrodes often drifts slowly with time after such cells were placed in a new solution. Drift of cell potentials is an especially severe problem in investigations dependent on precise observation of small pH differences.
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Measurements involving cells with liquid junctions are subject to further uncertainties due to the dependence of liquid junction potentials upon medium concentration and composition and due to pressure changes in the system.
  
==Principles==
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[[Image:pHfig1.jpg|thumb|250px|left|Fig. 1: pH electrode (Endress & Hauser) and electronic unit (Liquisys)]]
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Ideally, the change in liquid junction potential (residual liquid junction potential) between test solution and standardizing buffer should be small or at least highly reproducible. In practice, systematic errors between many measurements suggest that the reproducibility of the residual liquid junction potential is often poor and that residual liquid junction potentials are dependent on the construction and/or history of the liquid junctions used in various investigations.
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Since pH fluctuations in marine waters are very small, an absolute accuracy of less than 0.1 pH units and a resolution of at least 0.01 pH units is required. For an assessment of the CO<sub>2</sub>/CO<sub>3</sub> systems even a higher accuracy is necessary.
  
==Electrodes==
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==Description of the Sensor==
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One example is a standard pH Glass Electrode, Endress & Hauser Orbisint CPS 11 together with an electronic unit Liquisys M CPM 223. The electrode is fitted with a PTFE diaphragm, is filled with gel and contains an integrated Pt100 temperature sensor for temperature compensation. It is relatively stable against pressure fluctuations within the system. A photo of the system is shown in Fig. 1.
  
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==Calibration==
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For calibration, the standard procedure is applied, using two buffer solutions with pH=7±0.02 and pH=9±0.02 (Titrisol from Merck) which can be traced to SRM (NIST) and PTB (Germany). Temperature corrections of the buffer solution as given by the manufacturer have to be applied.
  
==Optical==
 
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==See also==
 
==See also==
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* [[Instruments and sensors to measure environmental parameters]]
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* [[Ships of opportunity and ferries as instrument carriers]]
  
==References==
 
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{{2Authors
 
 
{{authors
 
 
|AuthorID1=5068
 
|AuthorID1=5068
|AuthorName1=Wikischro
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|AuthorName1=Schroeder, Friedhelm
 
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|AuthorFullName1=Schroeder, Friedhelm
 
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|AuthorFullName2=Prien, Ralf}}
 
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[[Category: Articles by Prien, Ralf]]
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[[Category:Coastal and marine observation and monitoring]]
 
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[[Category:Observation of chemical parameters]]
 
 
 
 
[[Category:Theme 9]]
 
[[Category:Techniques and methods in coastal management]]
 
[[Category:Hydrological processes and water]]
 

Latest revision as of 20:10, 29 June 2019

Back to Instruments and sensors to measure environmental parameters


General Description

pH measurements are predominantly conducted with pH-sensitive glass electrodes, which have, in general, proven satisfactory in measurements of pH. However, the behaviour of pH-sensitive glass electrodes often falls short of what precision is required.

Even with the most careful treatment, the potential of cells containing glass electrodes often drifts slowly with time after such cells were placed in a new solution. Drift of cell potentials is an especially severe problem in investigations dependent on precise observation of small pH differences. Measurements involving cells with liquid junctions are subject to further uncertainties due to the dependence of liquid junction potentials upon medium concentration and composition and due to pressure changes in the system.

Fig. 1: pH electrode (Endress & Hauser) and electronic unit (Liquisys)

Ideally, the change in liquid junction potential (residual liquid junction potential) between test solution and standardizing buffer should be small or at least highly reproducible. In practice, systematic errors between many measurements suggest that the reproducibility of the residual liquid junction potential is often poor and that residual liquid junction potentials are dependent on the construction and/or history of the liquid junctions used in various investigations. Since pH fluctuations in marine waters are very small, an absolute accuracy of less than 0.1 pH units and a resolution of at least 0.01 pH units is required. For an assessment of the CO2/CO3 systems even a higher accuracy is necessary.

Description of the Sensor

One example is a standard pH Glass Electrode, Endress & Hauser Orbisint CPS 11 together with an electronic unit Liquisys M CPM 223. The electrode is fitted with a PTFE diaphragm, is filled with gel and contains an integrated Pt100 temperature sensor for temperature compensation. It is relatively stable against pressure fluctuations within the system. A photo of the system is shown in Fig. 1.

Calibration

For calibration, the standard procedure is applied, using two buffer solutions with pH=7±0.02 and pH=9±0.02 (Titrisol from Merck) which can be traced to SRM (NIST) and PTB (Germany). Temperature corrections of the buffer solution as given by the manufacturer have to be applied.


See also


The main authors of this article are Schroeder, Friedhelm and Prien, Ralf
Please note that others may also have edited the contents of this article.

Citation: Schroeder, Friedhelm; Prien, Ralf; (2019): PH sensors. Available from http://www.coastalwiki.org/wiki/PH_sensors [accessed on 24-11-2024]