Characterisation of porous ceramic plugs for use in electrochemical sensors

In electrochemical sensors like pH-, reference- or ion-selective electrodes a porous ceramic plug (or diaphragm) maintains the conducting junction with the test solution. These liquid junctions should have a resistance as low as possible meanwhile avoiding leakage through the junction. Five porous m...

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Veröffentlicht in:	Journal of materials science 2002-09, Vol.37 (18), p.3973-3979
Hauptverfasser:	BOSCH, R. W, STRAETMANS, S, VAN DYCK, S
Format:	Artikel
Sprache:	eng
Schlagworte:	Analytical chemistry Chemical sensors Chemistry Cross-disciplinary physics: materials science rheology Electrochemical methods Electrolytes Exact sciences and technology Intrusion Leakage Magnesium Materials science Materials testing Mathematical analysis Methods of materials testing and analysis Physical properties Physics Plugs Pore size distribution Porosity Zirconium oxides
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container_end_page	3979
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container_title	Journal of materials science
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creator	BOSCH, R. W STRAETMANS, S VAN DYCK, S
description	In electrochemical sensors like pH-, reference- or ion-selective electrodes a porous ceramic plug (or diaphragm) maintains the conducting junction with the test solution. These liquid junctions should have a resistance as low as possible meanwhile avoiding leakage through the junction. Five porous magnesium stabilised zirconium oxide plugs with different porosity's and pore size (distribution) were investigated as liquid junctions. The physical properties of these porous plugs were investigated with SEM and Mercury Intrusion Porosimetry. Important working conditions of these porous plugs are the resistance of the porous plug filled with an electrolyte and the contamination speed through these porous plugs, both for the test solution as the reference solution. The first property was measured by a 4-wire resistance measurement. The second property was measured by measuring the flow through rate of the reference electrolyte through the plug. It was shown that an optimal plug i.e., low leakage and high conductivity through the membrane, had a high porosity and relative small pores (0.25 μm). A simple mathematical model based on the Hagen-Poiseuille equation was developed to describe the porous plug characteristics. It was shown that mathematical calculation of the porous plug resistance was in good agreement with experimental results.
doi_str_mv	10.1023/A:1019636429110
format	Article
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W ; STRAETMANS, S ; VAN DYCK, S</creator><contributor>WCA</contributor><creatorcontrib>BOSCH, R. W ; STRAETMANS, S ; VAN DYCK, S ; WCA</creatorcontrib><description>In electrochemical sensors like pH-, reference- or ion-selective electrodes a porous ceramic plug (or diaphragm) maintains the conducting junction with the test solution. These liquid junctions should have a resistance as low as possible meanwhile avoiding leakage through the junction. Five porous magnesium stabilised zirconium oxide plugs with different porosity's and pore size (distribution) were investigated as liquid junctions. The physical properties of these porous plugs were investigated with SEM and Mercury Intrusion Porosimetry. Important working conditions of these porous plugs are the resistance of the porous plug filled with an electrolyte and the contamination speed through these porous plugs, both for the test solution as the reference solution. The first property was measured by a 4-wire resistance measurement. The second property was measured by measuring the flow through rate of the reference electrolyte through the plug. It was shown that an optimal plug i.e., low leakage and high conductivity through the membrane, had a high porosity and relative small pores (0.25 μm). A simple mathematical model based on the Hagen-Poiseuille equation was developed to describe the porous plug characteristics. 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Important working conditions of these porous plugs are the resistance of the porous plug filled with an electrolyte and the contamination speed through these porous plugs, both for the test solution as the reference solution. The first property was measured by a 4-wire resistance measurement. The second property was measured by measuring the flow through rate of the reference electrolyte through the plug. It was shown that an optimal plug i.e., low leakage and high conductivity through the membrane, had a high porosity and relative small pores (0.25 μm). A simple mathematical model based on the Hagen-Poiseuille equation was developed to describe the porous plug characteristics. 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The physical properties of these porous plugs were investigated with SEM and Mercury Intrusion Porosimetry. Important working conditions of these porous plugs are the resistance of the porous plug filled with an electrolyte and the contamination speed through these porous plugs, both for the test solution as the reference solution. The first property was measured by a 4-wire resistance measurement. The second property was measured by measuring the flow through rate of the reference electrolyte through the plug. It was shown that an optimal plug i.e., low leakage and high conductivity through the membrane, had a high porosity and relative small pores (0.25 μm). A simple mathematical model based on the Hagen-Poiseuille equation was developed to describe the porous plug characteristics. 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subjects	Analytical chemistry Chemical sensors Chemistry Cross-disciplinary physics: materials science rheology Electrochemical methods Electrolytes Exact sciences and technology Intrusion Leakage Magnesium Materials science Materials testing Mathematical analysis Methods of materials testing and analysis Physical properties Physics Plugs Pore size distribution Porosity Zirconium oxides
title	Characterisation of porous ceramic plugs for use in electrochemical sensors
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