A Highly-Sensitive Picric Acid Chemical Sensor Based on ZnO Nanopeanuts

Ibrahim, Ahmed A.; Tiwari, Preeti; Al-Assiri, M.S.; Al‐Salami, A. E.; Umar, Ahmad; Kumar, Rajesh; Kim, S. H.; Ansari, Z. A.; Baskoutas, Sotirios

doi:10.3390/ma10070795

Cited by 39 publications

(13 citation statements)

References 67 publications

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“…Their adverse effects at minute concentrations have produced undesirable consequences for flora and fauna. Scientists have prepared a large number of metal oxide-based chemical sensors due to their potential properties of easy preparation with low processing costs and eco-friendly nature [ 32 ]. Among the different types of metal oxide materials, ZnO is extensively employed for the fabrication of sensors for perilous chemicals.…”

Section: Chemical Sensing Applications Of Zno Nanomaterialsmentioning

confidence: 99%

Chemical Sensing Applications of ZnO Nanomaterials

et al. 2018

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Recent advancement in nanoscience and nanotechnology has witnessed numerous triumphs of zinc oxide (ZnO) nanomaterials due to their various exotic and multifunctional properties and wide applications. As a remarkable and functional material, ZnO has attracted extensive scientific and technological attention, as it combines different properties such as high specific surface area, biocompatibility, electrochemical activities, chemical and photochemical stability, high-electron communicating features, non-toxicity, ease of syntheses, and so on. Because of its various interesting properties, ZnO nanomaterials have been used for various applications ranging from electronics to optoelectronics, sensing to biomedical and environmental applications. Further, due to the high electrochemical activities and electron communication features, ZnO nanomaterials are considered as excellent candidates for electrochemical sensors. The present review meticulously introduces the current advancements of ZnO nanomaterial-based chemical sensors. Various operational factors such as the effect of size, morphologies, compositions and their respective working mechanisms along with the selectivity, sensitivity, detection limit, stability, etc., are discussed in this article.

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Section: Chemical Sensing Applications Of Zno Nanomaterialsmentioning

confidence: 99%

Chemical Sensing Applications of ZnO Nanomaterials

et al. 2018

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“…[42][43][44][45][46][47][48][49][50][51][52][53][54][55][56] Zinc oxide nanomaterials and fluorescent quantum dots were also helpful in PA detection. [57,58] The fluorescent outputs due to the sensing mechanisms were effectively used to prepare logic based devices in some cases. [59,60] Similarly, there are reports on the detection of aliphatic amines (AAs) with low LODs in various samples using different techniques.…”

Section: Introductionmentioning

confidence: 99%

A New Compound for Sequential Sensing of Picric Acid and Aliphatic Amines: Physicochemical Details and Construction of Molecular Logic Gates

Ghosh

Seth

Ghosh

et al. 2021

Chemistry An Asian Journal

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Picric acid (PA) at low concentration is a serious water pollutant. Alongside, aliphatic amines (AAs) add to the queue to pollute surface water. Plenty of reports are available to sense PA with an ultralow limit of detection (LOD). However, only a handful of works are testified to detect AAs. A new fluorescent donor-acceptor compound has been synthesized with inherent intramolecular charge transfer (ICT) character that enables selective and sensitive colorimetric quantitative detection of PA and AAs with low LODs in nonaqueous as well as aqueous solutions. The synthesized compound is based on a hemicyanine skeleton containing two pyridenylmethylamino groups at the donor and a benzothiazole moiety at the acceptor ends. The detailed mechanisms and reaction dynamics are explained spectroscopically along with computational support. The fluorescence property of the detecting compound changes due to protonation of its pyridinyl centers by PA leading to quenching of fluorescence and subsequently de-protonation by AAs to revive the signal. We have further designed logic circuits from the acquired optical responses by sequential interactions.

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“…In the past decades, various approaches have been explored to quantify the picric acid effluents, such as fluorimetry, chemical methods, capillary electrophoresis and spectrophotometry [1][2][3][4][5]. Venkatramaiah et al, have successfully developed a fluorescent chemosensor based on fluoranthene for the detection of picric acid, in which static fluorescence quenching is the dominant process by intercalative interactions between fluoranthene and nitroaromatics [6].…”

Section: Introductionmentioning

confidence: 99%

Quantification of picric acid on nanosphere polypyrrole modified electrode by stripping voltammetric method

et al. 2019

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The electrochemical studies of picric acid were carried out in acidic, neutral and basic buffer media at bare glassy carbon (GC) and polypyrrole modified GC electrode. Cyclic Voltammogram (CV) of picric acid exhibited three reduction peaks at -0.4, -0.8 and -1.5V (vs. Ag/AgCl) and two oxidation peaks at 0.8 and 1.4V (vs. Ag/AgCl). Among the various pH studied, highly sensitive response was observed at pH 1.0. The effect of scan rate was studied between 25 and 500 mVs-1 at the optimal pH.CV results revealed the adsorption-controlled reaction at the electrode surface. The GC electrode was modified with polypyrrole conducting polymer film to enhance the electrocatalytic activity of the reductive species. Atomic force microscopy (AFM) images showed the nanosphere morphology of the polypyrrole film, which was coated uniformly on the electrode surface. Under optimum experimental conditions, the influence of concentration on the stripping signal was studied. The linear range of detection was found between 50 ppb and 250 ppb with the lower limit of detection of 10±3 ppb.

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A Highly-Sensitive Picric Acid Chemical Sensor Based on ZnO Nanopeanuts

Cited by 39 publications

References 67 publications

Chemical Sensing Applications of ZnO Nanomaterials

Chemical Sensing Applications of ZnO Nanomaterials

A New Compound for Sequential Sensing of Picric Acid and Aliphatic Amines: Physicochemical Details and Construction of Molecular Logic Gates

Quantification of picric acid on nanosphere polypyrrole modified electrode by stripping voltammetric method

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