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Electrochemical filter to remove oxygen interference locally, rapidly, and temporarily for sensing applications

Electrochemical filter to remove oxygen interference locally, rapidly, and temporarily for sensing applications
Electrochemical filter to remove oxygen interference locally, rapidly, and temporarily for sensing applications
An electrochemical oxygen filter is described that removes efficiently dissolved oxygen from the surface of an electrochemical sensor. Simulations show that 99% of oxygen can be removed in less than 60 s if an electrochemical filter made of a porous electrode is positioned at less than 200 μm from the sensor surface. For an experimental demonstration, the metallic filter was made with either a stainless steel or a platinum grid separated from the sensor by a porous separator. It was combined with a sensor for analysis of paraquat, an herbicide widely used over the world. In aerated solutions, paraquat signal was not distinguished due to the strong interference of oxygen. When using the oxygen filter, paraquat was clearly detected with a better-defined response than the one obtained under a N2 atmosphere that requires a longer time period before analysis.
0003-2700
7425–7429
Etienne, Mathieu
00bf2fdb-3b6b-44d0-8355-075f47d3ed54
Huong Le, Thi Xuan
b99bbf88-94b1-4b3b-b4b8-b5ddb607c23e
Nasir, Tauqir
afe6d658-cc69-4371-8ae6-d722e30352c8
Herzog, Grégoire
4df04404-12ef-4c8d-a992-8f2016518f5e
Etienne, Mathieu
00bf2fdb-3b6b-44d0-8355-075f47d3ed54
Huong Le, Thi Xuan
b99bbf88-94b1-4b3b-b4b8-b5ddb607c23e
Nasir, Tauqir
afe6d658-cc69-4371-8ae6-d722e30352c8
Herzog, Grégoire
4df04404-12ef-4c8d-a992-8f2016518f5e

Etienne, Mathieu, Huong Le, Thi Xuan, Nasir, Tauqir and Herzog, Grégoire (2020) Electrochemical filter to remove oxygen interference locally, rapidly, and temporarily for sensing applications. Analytical Chemistry, 92 (11), 7425–7429. (doi:10.1021/acs.analchem.0c00395).

Record type: Article

Abstract

An electrochemical oxygen filter is described that removes efficiently dissolved oxygen from the surface of an electrochemical sensor. Simulations show that 99% of oxygen can be removed in less than 60 s if an electrochemical filter made of a porous electrode is positioned at less than 200 μm from the sensor surface. For an experimental demonstration, the metallic filter was made with either a stainless steel or a platinum grid separated from the sensor by a porous separator. It was combined with a sensor for analysis of paraquat, an herbicide widely used over the world. In aerated solutions, paraquat signal was not distinguished due to the strong interference of oxygen. When using the oxygen filter, paraquat was clearly detected with a better-defined response than the one obtained under a N2 atmosphere that requires a longer time period before analysis.

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Published date: 28 April 2020

Identifiers

Local EPrints ID: 480620
URI: http://eprints.soton.ac.uk/id/eprint/480620
DOI: doi:10.1021/acs.analchem.0c00395
ISSN: 0003-2700
PURE UUID: 8b1f6a35-f3a1-4ef2-90e0-2084dfda8322
ORCID for Tauqir Nasir: ORCID iD orcid.org/0000-0003-0457-766X

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Date deposited: 08 Aug 2023 16:30
Last modified: 17 Mar 2024 04:02

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Contributors

Author: Mathieu Etienne
Author: Thi Xuan Huong Le
Author: Tauqir Nasir ORCID iD
Author: Grégoire Herzog

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