Difference between revisions of "Hale 1983 POS Stability"
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|journal=Springer | |journal=Springer | ||
|abstract=[[File:Gnaiger&Forstner POS 1983.jpg|right|140px|link=Gnaiger 1983 Springer POS|Gnaiger 1983 Springer POS]] | |abstract=[[File:Gnaiger&Forstner POS 1983.jpg|right|140px|link=Gnaiger 1983 Springer POS|Gnaiger 1983 Springer POS]] | ||
An ideal polarographic oxygen sensor (POS) exhibits a time-independent relationship between the current it delivers, throughout its specified operating temperature range, and the activity of oxygen contacting its membrane. All applications of POS require stability in some measure, and long-term monitoring applications demand stability over periods up to 1 year. | |||
In: [[Gnaiger 1983 Springer POS |Gnaiger E, Forstner H, eds (1983) Polarographic Oxygen Sensors. Aquatic and Physiological Applications. Springer, Berlin, Heidelberg, New York:370 pp.]] | In: [[Gnaiger 1983 Springer POS |Gnaiger E, Forstner H, eds (1983) Polarographic Oxygen Sensors. Aquatic and Physiological Applications. Springer, Berlin, Heidelberg, New York:370 pp.]] | ||
|Links=' | |Links=' | ||
Revision as of 18:47, 17 February 2020
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Abstract:
An ideal polarographic oxygen sensor (POS) exhibits a time-independent relationship between the current it delivers, throughout its specified operating temperature range, and the activity of oxygen contacting its membrane. All applications of POS require stability in some measure, and long-term monitoring applications demand stability over periods up to 1 year.
Labels:
HRR: Theory
POS 1983
