Reflectance based optical fibre sensor for ammonium ion using solid-state Riegler's reagent
A new optical sensor for fast screening of ammonium (NH4+) ion was developed based on immobilisation of p-nitrobenzene-diazonium chloride (Riegler's reagent) onto XAD-7 microbeads. In aqueous solution, the diazonium salt is unstable and will spontaneously decompose at room temperature but we ha...
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my.usim-83892017-02-23T04:50:56Z Reflectance based optical fibre sensor for ammonium ion using solid-state Riegler's reagent Tan Ling, Ling, Musa, Ahmad, Lee Yook, Heng, Optical Sensor Ammonium Ion XAD-7 Beads P-Nitrobenzene-Diazonium Chloride Reflectance Spectrophotometry Optical Fibre A new optical sensor for fast screening of ammonium (NH4+) ion was developed based on immobilisation of p-nitrobenzene-diazonium chloride (Riegler's reagent) onto XAD-7 microbeads. In aqueous solution, the diazonium salt is unstable and will spontaneously decompose at room temperature but we have successfully stabilised this compound via immobilisation using physical adsorption to create a solid-state Riegler's reagent for NH4+ ion determination with a storage period of one month. The quantification of NH4+ ion concentration was possible by using reflectance spectrophotometry method with an optical fibre probe. The solid-state Riegler's reagent based optical sensor yielded a wide linear response range for NH4+ ion of 10-60 ppm and a fast response time of 2 min when compared with many commonly used coloured reagents. The limit of detection (LOD) of the optical NH4+ ion sensor was 7.9 ppm NH4+ ion with optimum response at pH 7. The response of the sensor was reproducible (4.2-5.7% relative standard deviation, n = 3) and can be regenerated using buffer pH 1. Except for Fe3+ ions, most common ions showed no serious interference. The sensor was also used for the determination of NH4+ ion in river water and the results obtained were comparable to those obtained by a standard titrimetric method. (c) 2012 Elsevier B.V. All rights reserved. 2015-06-16T03:49:35Z 2015-06-16T03:49:35Z 2012 Article 0925-4005 http://ddms.usim.edu.my/handle/123456789/8389 en Elsevier Science Sa |
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Optical Sensor Ammonium Ion XAD-7 Beads P-Nitrobenzene-Diazonium Chloride Reflectance Spectrophotometry Optical Fibre |
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Optical Sensor Ammonium Ion XAD-7 Beads P-Nitrobenzene-Diazonium Chloride Reflectance Spectrophotometry Optical Fibre Tan Ling, Ling, Musa, Ahmad, Lee Yook, Heng, Reflectance based optical fibre sensor for ammonium ion using solid-state Riegler's reagent |
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A new optical sensor for fast screening of ammonium (NH4+) ion was developed based on immobilisation of p-nitrobenzene-diazonium chloride (Riegler's reagent) onto XAD-7 microbeads. In aqueous solution, the diazonium salt is unstable and will spontaneously decompose at room temperature but we have successfully stabilised this compound via immobilisation using physical adsorption to create a solid-state Riegler's reagent for NH4+ ion determination with a storage period of one month. The quantification of NH4+ ion concentration was possible by using reflectance spectrophotometry method with an optical fibre probe. The solid-state Riegler's reagent based optical sensor yielded a wide linear response range for NH4+ ion of 10-60 ppm and a fast response time of 2 min when compared with many commonly used coloured reagents. The limit of detection (LOD) of the optical NH4+ ion sensor was 7.9 ppm NH4+ ion with optimum response at pH 7. The response of the sensor was reproducible (4.2-5.7% relative standard deviation, n = 3) and can be regenerated using buffer pH 1. Except for Fe3+ ions, most common ions showed no serious interference. The sensor was also used for the determination of NH4+ ion in river water and the results obtained were comparable to those obtained by a standard titrimetric method. (c) 2012 Elsevier B.V. All rights reserved. |
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Article |
author |
Tan Ling, Ling, Musa, Ahmad, Lee Yook, Heng, |
author_facet |
Tan Ling, Ling, Musa, Ahmad, Lee Yook, Heng, |
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Tan Ling, Ling, |
title |
Reflectance based optical fibre sensor for ammonium ion using solid-state Riegler's reagent |
title_short |
Reflectance based optical fibre sensor for ammonium ion using solid-state Riegler's reagent |
title_full |
Reflectance based optical fibre sensor for ammonium ion using solid-state Riegler's reagent |
title_fullStr |
Reflectance based optical fibre sensor for ammonium ion using solid-state Riegler's reagent |
title_full_unstemmed |
Reflectance based optical fibre sensor for ammonium ion using solid-state Riegler's reagent |
title_sort |
reflectance based optical fibre sensor for ammonium ion using solid-state riegler's reagent |
publisher |
Elsevier Science Sa |
publishDate |
2015 |
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http://ddms.usim.edu.my/handle/123456789/8389 |
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1645152407836950528 |
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13.214268 |