control of graphene oxide dispersions with a small impedance sensor.

Nanotechnology

Research Unit of Advanced Materials, Department of Financial Engineering, School of Engineering, University of the Aegean, 41 Kountouriotou str., 821 32 Chios, Greece.

Published: November 2021

AI Article Synopsis

  • Carbon-based nanomaterials (CBNs) like graphene and carbon nanotubes have superior properties that make them useful in various applications, particularly in cementitious materials.
  • A new method using electrical impedance spectroscopy (EIS) with an impedance sensor has been proposed to quickly evaluate and quantify graphene oxide (GO) dispersions, addressing the lack of established characterization protocols.
  • The study found that optimal GO concentration (around 0.15 wt%) facilitates better dispersion and conductivity when ultrasonicated at specific energy levels (30 to 65 kJ), making the method valuable for in-field applications in construction.

Article Abstract

Carbon-based nanomaterials (CBNs), such as graphene and carbon nanotubes, display advanced physical and chemical properties, which has led to their widespread applications. One of these applications includes the incorporation of CBNs into cementitious materials in the form of aqueous dispersions. The main issue that arises in this context is that currently no established protocol exists as far as characterizing the dispersions. In the present article, an innovative method for quick evaluation and quantification of graphene oxide (GO) dispersions is proposed. The proposed method is electrical impedance spectroscopy (EIS) with an impedance sensor. The novelty lies on the exploitation of a small sensor for on-site (field) direct dielectric measurements with the application of alternating current. Five different concentrations of GO dispersions were studied by applying EIS and for various accumulated ultrasonic energies. The low GO concentration leads to high impedance values due to low formed current network. Two opposing mechanisms were revealed during the accumulation of ultrasonic energy, that are taking place simultaneously: breakage of the agglomerates that facilitates the flow of the electric current due to the formation of a better dispersed network, nevertheless the surface hydrophilic structure of the GO is damaged with the high accumulated ultrasonic energy. The dielectric measurements were exploited to express an appropriate quantitative 'quality index' to facilitate with the dispersion control of the nanostructures. An intermediate concentration of GO is suggested (about 0.15 wt% of the binder materials) to be optimal for the specific engineering application, ultrasonicated at approximately 30 to 65 kJ. The investigated methodology is highly novel and displays a high potential to be applied in-field applications where CBNs must be incorporated in building materials.

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Source
http://dx.doi.org/10.1088/1361-6528/ac2dc8DOI Listing

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