Study on the Indirect Electrochemical Detection of Ammonium Ion with In Situ Electrogenerated Hypobromous Acid

Takahashi, Miki; Nakamura, Kenta; Jin, Jiye

doi:10.1002/elan.200804311

Cited by 10 publications

(3 citation statements)

References 25 publications

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“…Traditional pulse voltammetric methods can be applied for the modulator or for the sensor electrode, and in the future, new types of customized pulse sequences will be desirable for the junction sensor electrode. The determination of glucose has been selected here to highlight the potential and importance of this experimental tool and further applications will include, for example, determining organohalides, ammonia, buffer capacity, or p K A values in aqueous media. The miniaturization of junction sensors and the optimization of the interelectrode gap will be of considerable practical importance in electroanalysis.…”

Section: Resultsmentioning

confidence: 99%

Pulse-Voltammetric Glucose Detection at Gold Junction Electrodes

Rassaei

Marken

2010

Anal. Chem.

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A novel glucose sensing concept based on the localized change or "modulation" in pH within a symmetric gold-gold junction electrode is proposed. A paired gold-gold junction electrode (average gap size ca. 500 nm) is prepared by simultaneous bipotentiostatic electrodeposition of gold onto two closely spaced platinum disk electrodes. For glucose detection in neutral aqueous solution, the potential of the "pH-modulator" electrode is set to -1.5 V vs saturated calomel reference electrode (SCE) to locally increase the pH, and simultaneously, either cyclic voltammetry or square wave voltammetry experiments are conducted at the sensor electrode. A considerable improvement in the sensor electrode response is observed when a normal pulse voltammetry sequence is applied to the modulator electrode (to generate "hydroxide pulses") and the glucose sensor electrode is operated with fixed bias at +0.5 V vs SCE (to eliminate capacitive charging currents). Preliminary data suggest good linearity for the glucose response in the medically relevant 1-10 mM concentration range (corresponding to 0.18-1.8 g L(-1)). Future electroanalytical applications of multidimensional pulse voltammetry in junction electrodes are discussed.

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Section: Resultsmentioning

confidence: 99%

Pulse-Voltammetric Glucose Detection at Gold Junction Electrodes

Rassaei

Marken

2010

Anal. Chem.

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“…Although almost no electrochemical oxidation of ammonium occurs at a high positive potential, it can be achieved via indirect measurements. Takahashi et al [99] proposed an indirect electrochemical method for determining ammonia nitrogen concentrations. The detection principle of this method is that bromine (Br 2 ) is generated by the anode, which can be hydrolyzed into hypobromic acid (HBrO) in the phosphoric acid buffer solution at pH 7.…”

Section: Voltammetric Methodsmentioning

confidence: 99%

Electrochemical monitoring of marine nutrients: From principle to application

Hong

Pan

Han

2021

TrAC Trends in Analytical Chemistry

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“…At this potential, thermodynamically, 23 a wide range of oxidants can be formed concomitantly in seawater at the carbon wire electrode. This includes, for example, the oxidation of chloride to dichlorine, 24 bromide to hypobromous acid, 25 and water to hydrogen peroxide or hydroxide radicals and protons. 26 The reaction of the oxidants with the phytoplankton results in a sharp drop in the chl-a fluorescence signal after a delay in the onset of the applied potential due to the finite time required for the oxidants to diffuse over tens to hundreds of microns in distance and to penetrate the membranes to reach the chlorophyll in the cell.…”

Section: ■ Introductionmentioning

confidence: 99%

Rapid Opto-electrochemical Differentiation of Marine Phytoplankton

Yang

Batchelor‐McAuley

et al. 2022

ACS Meas. Sci. Au

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The use of electro-generated oxidants in seawater facilitates the discrimination of different plankton groups via monitoring the decay in real time of their chlorophyll-a (chl-a) fluorescence signals following potentiostatic initiation of electrolysis in their vicinity (Yang, M. et al. Chem. Sci.2019, 10(34), 7988−7993). In this paper, we explore the sensitivity of phytoplankton to different chemical species produced at various potentials in seawater. At low potentials, the oxidation of ca. millimolar bromide naturally present in seawater to hypobromous acid 'switches-off' the chl-a signal of individual Chlamydomonas concordia cells (green algae) located on the electrode surface within tens of seconds of the potential onset. At higher oxidative potentials, the oxidation of chloride and water produces oxidants (Cl 2 , OH, H 2 O 2 , etc.) that are also lethal to the plankton. To deconvolute the contributions to the response from the chemical identity of the oxidant and the amount of charge delivered to 'titrate' the individual living plankton using the loss of fluorescence as the 'end point', we introduce a ramped galvanostatic method. This approach enabled the controlled injection of charge applied to a bespoke electrochemical cell in which the plankton are immobilized on an electrode surface for rapid and sensitive measurement. It is shown that the number of moles (charge) of oxidants required to react leading to chl-a switch-off is independent of the chemical identity of the electro-generated oxidant(s) among hypobromous acid, chlorine, or water-derived oxidants. Comparative experiments between C. concordia and Emiliania huxleyi (where the latter are encapsulated by extracellular plates of calcium carbonate) show that significantly different amounts of absolute charge (moles of electro-generated oxidants) are required in each case to 'switch-off' the chl-a signal. The method provides the basis for a tool that could distinguish between different plankton cells within ca. 2 min including the setup time.

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Study on the Indirect Electrochemical Detection of Ammonium Ion with In Situ Electrogenerated Hypobromous Acid

Cited by 10 publications

References 25 publications

Pulse-Voltammetric Glucose Detection at Gold Junction Electrodes

Pulse-Voltammetric Glucose Detection at Gold Junction Electrodes

Electrochemical monitoring of marine nutrients: From principle to application

Rapid Opto-electrochemical Differentiation of Marine Phytoplankton

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