Electrical Impedance Spectroscopy for Real-Time Monitoring of the Life Cycle of Graphene Nanoplatelets Filters for Some Organic Industrial Pollutants

Miele, Gianfranco; Bellucci, Stefano; Cataldo, Antonino; Tinno, Alessio Di; Ferrigno, Luigi; Maffucci, Antonio; Micheli, Laura; Sibilia, Sarah

doi:10.1109/tim.2021.3089247

Cited by 11 publications

(7 citation statements)

References 34 publications

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“…Taking advantage of electrical properties, these nanocomposites could operate as sensors for environmental pollutants. In our previous works, we produced a graphene-based device able to retain and detect organic pollutants in water [ 56 , 57 , 58 ]. Furthermore, by modulating the rheological properties, the nanocomposites could play a role as an epidermal drug release system.…”

Section: Discussionmentioning

confidence: 99%

MacGyvered Multiproperty Materials Using Nanocarbon and Jam: A Spectroscopic, Electromagnetic, and Rheological Investigation

Cataldo

Pietra

Zappelli

et al. 2022

JFB

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As part of a biopolymer matrix, pectin was investigated to obtain an engineered jam, due to its biodegradability. Only a few examples of pectin-based nanocomposites are present in the literature, and even fewer such bionanocomposites utilize nanocarbon as a filler—mostly for use in food packaging. In the present paper, ecofriendly nanocomposites made from household reagents and displaying multiple properties are presented. In particular, the electrical behavior and viscoelastic properties of a commercial jam were modulated by loading the jam with carbon nanotubes and graphene nanoplates. A new nanocomposite class based on commercial jam was studied, estimating the percolation threshold for each filler. The electrical characterization and the rheological measurements suggest that the behavior above the percolation threshold is influenced by the different morphology—i.e., one-dimensional or two-dimensional—of the fillers. These outcomes encourage further studies on the use of household materials in producing advanced and innovative materials, in order to reduce the environmental impact of new technologies, without giving up advanced devices endowed with different physical properties.

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Section: Discussionmentioning

confidence: 99%

MacGyvered Multiproperty Materials Using Nanocarbon and Jam: A Spectroscopic, Electromagnetic, and Rheological Investigation

Cataldo

Pietra

Zappelli

et al. 2022

JFB

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“…This article [6] proposed a similar approach, emphasizing the smart monitoring of the life cycle of the same kind of graphene nanoplatelets-based filters for water remediation in the presence of pollutants. The measurement technique was based on suitable figures of merit, analyzing the time variation of the electrical impedance frequency spectrum.…”

Section: Introductionmentioning

confidence: 99%

Decontamination of surface water from organic pollutants using graphene membranes

Bellucci

2023

CAN

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In this paper, we deal with one of the most urgent and relevant topics nowadays, i.e., water pollution. The problem is finding a valid candidate for the absorption and removal of different kinds of pollutants commonly found in water. There are already some indications about graphene oxide as a potential candidate. In the present work, we take a step forward to show how graphene nanoplatelets (rather than the oxide form of this material) are capable of decontaminating water. In this starting step, we use a specific substance as a model pollutant, i.e., acetonitrile, leaving for the future steps, to extend the analysis to additional types of pollutants. In addition to laboratory-produced graphene nanoplatelets, we already examined in the past; now we wish to consider also commercially available ones, so that the new results will not be bound to a laboratory (low technology readiness level) material, but will become interesting also from the industrial point of view, thanks to the scalability of the nanoplatelets production. For this aim, we compare the performance of two types of filters based on two classes of nanomaterials, i.e., those produced by microwave and ultrasound assisted exfoliation, already analyzed in our earlier works, with those commercially distributed by an Italian company, i.e., NANESA, http://www.nanesa.com/. The latter is an innovative SME involved in the production of graphene-based nanomaterials. We focus here in the graphene nanoplatelets, commercially available in industrial batches (GXNan grades). The present study leads to determine which filtering membrane, among the various types of commercial graphene considered, shows the greatest stability, and the lack of breakage of the membrane, concentrating on such accessory features, given that all types of graphene showed excellent adsorption properties.

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“…Systems based on optical methods [23]- [25], radio-frequency resonators [26], [27], and electrochemical impedance spectroscopy (EIS) [28] (sometimes integrating computer vision technology [29], [30]), have been published as well. EIS was also proposed for real-time monitoring of pollutants in graphene filters [31], and capacitive measurement for particle detection in lubricating oil [32]. High Frequency Impedance Spectroscopy (HFIS) with nanoelectrodes (NE) array [33]- [36] is a still largely unexplored (bio)sensing technology, with demonstrated capability to di- rectly detect by purely electrical means single NP as small as 40 nm diameter on top of bovine serum albumin immobilization layer [33].…”

Section: Introductionmentioning

confidence: 99%

Toward Continuous Nano-Plastic Monitoring in Water by High Frequency Impedance Measurement With Nano-Electrode Arrays

2023

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We explore the potentiality of high frequency impedance measurements with CMOS nano-electrode arrays for nano-plastic pollutant particles monitoring in water. This technology offers benefits as nano-scale resolution, high parallelization, scalability, label-free single particle detection, and automatic measurements without operator intervention. Simple models are proposed for size and concentration estimation. The former integrates measurements of adjacent electrodes and shows uncertainty comparable to the nominal one with mean prediction error lower than 45 % down to 50 nm radius. The latter accounts for noise in the definition of the sensing volume. We report a worst-case concentration error lower than a factor 1.7 under stationary and continuous flow, which demonstrates the potential of this technology for automated measurements.

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Electrical Impedance Spectroscopy for Real-Time Monitoring of the Life Cycle of Graphene Nanoplatelets Filters for Some Organic Industrial Pollutants

Cited by 11 publications

References 34 publications

MacGyvered Multiproperty Materials Using Nanocarbon and Jam: A Spectroscopic, Electromagnetic, and Rheological Investigation

MacGyvered Multiproperty Materials Using Nanocarbon and Jam: A Spectroscopic, Electromagnetic, and Rheological Investigation

Decontamination of surface water from organic pollutants using graphene membranes

Toward Continuous Nano-Plastic Monitoring in Water by High Frequency Impedance Measurement With Nano-Electrode Arrays

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