Reagent free electrochemical-based detection of silver ions at interdigitated microelectrodes using in-situ pH control

Reagent free electrochemical-based detection of silver ions at interdigitated microelectrodes using in-situ pH control

•Applying 1.65 V to a protonator electrode lowered the pH at the sensor electrode to pH 3, optimal for silver ion detection.•In-situ pH control eliminated the need for the addition of mineral acids to a solution before analysis.•Chlorine present in tap water helped in detection, causing a sharpening...

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Veröffentlicht in:Sensors and actuators. B, Chemical Chemical, 2021-04, Vol.333, p.129531, Article 129531
Hauptverfasser: Wasiewska, Luiza A., Seymour, Ian, Patella, Bernardo, Inguanta, Rosalinda, Burgess, Catherine M., Duffy, Geraldine, O'Riordan, Alan
Format: Artikel
Sprache:eng
Schlagworte:
Calibration
Chemical sensors
Chloride ions
Chlorine
Deposition
Drinking water
Electrodes
Electrolysis
Electrolytes
Interdigitated gold microband electrodes
Local pH control
Mathematical analysis
Microelectrodes
Oxygen production
pH control
Reagents
Silver ions
Sodium acetate
Square wave voltammetry
Stripping
Tap water
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container_end_page
container_issue
container_start_page 129531
container_title Sensors and actuators. B, Chemical
container_volume 333
creator Wasiewska, Luiza A.
Seymour, Ian
Patella, Bernardo
Inguanta, Rosalinda
Burgess, Catherine M.
Duffy, Geraldine
O'Riordan, Alan
description •Applying 1.65 V to a protonator electrode lowered the pH at the sensor electrode to pH 3, optimal for silver ion detection.•In-situ pH control eliminated the need for the addition of mineral acids to a solution before analysis.•Chlorine present in tap water helped in detection, causing a sharpening of the silver stripping peak due to formation of silver chloride.•Detection of 250 nM of silver ions in tap water in less than 3 min was possible without the need for additional electrolytes. Herein we report on the development of an electrochemical sensor for silver ions detection in tap water using anodic sweep voltammetry with in-situ pH control; enabled by closely spaced interdigitated electrode arrays. The in-situ pH control approach allowed the pH of a test solution to be tailored to pH 3 (experimentally determined as the optimal pH) by applying 1.65 V to a protonator electrode with the subsequent production of protons, arising from water electrolysis, dropping the local pH value. Using this approach, an initial proof-of-concept study for silver detection in sodium acetate was undertaken where 1.25 V was applied during deposition (to compensate for oxygen production) and 1.65 V during stripping. Using these conditions, calibration between 0.2 and 10 μM was established with the silver stripping peak ∼0.3 V. The calculated limit of detection was 13 nM. For the final application in tap water, 1.65 V was applied to a protonator electrode for both deposition and stripping of silver. The chloride ions, present in tap water (as a consequence of adding chlorine during the disinfection process) facilitated silver detection and caused the striping peak to shift catholically to ∼0.2 V. The combination of the complexation of silver ions with chloride and in-situ pH control resulted in a linear calibration range between 0.25 and 2 μM in tap water and a calculated limit of detection of 106 nM without the need to add acid or supporting electrolytes.
doi_str_mv 10.1016/j.snb.2021.129531
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Herein we report on the development of an electrochemical sensor for silver ions detection in tap water using anodic sweep voltammetry with in-situ pH control; enabled by closely spaced interdigitated electrode arrays. The in-situ pH control approach allowed the pH of a test solution to be tailored to pH 3 (experimentally determined as the optimal pH) by applying 1.65 V to a protonator electrode with the subsequent production of protons, arising from water electrolysis, dropping the local pH value. Using this approach, an initial proof-of-concept study for silver detection in sodium acetate was undertaken where 1.25 V was applied during deposition (to compensate for oxygen production) and 1.65 V during stripping. Using these conditions, calibration between 0.2 and 10 μM was established with the silver stripping peak ∼0.3 V. The calculated limit of detection was 13 nM. For the final application in tap water, 1.65 V was applied to a protonator electrode for both deposition and stripping of silver. The chloride ions, present in tap water (as a consequence of adding chlorine during the disinfection process) facilitated silver detection and caused the striping peak to shift catholically to ∼0.2 V. 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The in-situ pH control approach allowed the pH of a test solution to be tailored to pH 3 (experimentally determined as the optimal pH) by applying 1.65 V to a protonator electrode with the subsequent production of protons, arising from water electrolysis, dropping the local pH value. Using this approach, an initial proof-of-concept study for silver detection in sodium acetate was undertaken where 1.25 V was applied during deposition (to compensate for oxygen production) and 1.65 V during stripping. Using these conditions, calibration between 0.2 and 10 μM was established with the silver stripping peak ∼0.3 V. The calculated limit of detection was 13 nM. For the final application in tap water, 1.65 V was applied to a protonator electrode for both deposition and stripping of silver. The chloride ions, present in tap water (as a consequence of adding chlorine during the disinfection process) facilitated silver detection and caused the striping peak to shift catholically to ∼0.2 V. 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The combination of the complexation of silver ions with chloride and in-situ pH control resulted in a linear calibration range between 0.25 and 2 μM in tap water and a calculated limit of detection of 106 nM without the need to add acid or supporting electrolytes.</abstract><cop>Lausanne</cop><pub>Elsevier B.V</pub><doi>10.1016/j.snb.2021.129531</doi><orcidid>https://orcid.org/0000-0003-3722-5935</orcidid><oa>free_for_read</oa></addata></record>
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1873-3077
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source Elsevier ScienceDirect Journals Complete
subjects Calibration
Chemical sensors
Chloride ions
Chlorine
Deposition
Drinking water
Electrodes
Electrolysis
Electrolytes
Interdigitated gold microband electrodes
Local pH control
Mathematical analysis
Microelectrodes
Oxygen production
pH control
Reagents
Silver ions
Sodium acetate
Square wave voltammetry
Stripping
Tap water
title Reagent free electrochemical-based detection of silver ions at interdigitated microelectrodes using in-situ pH control
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