High-Yield Production of Nano-Lateral Size Graphene Oxide by High-Power Ultrasonication

Overview

Journal Materials (Basel)

Publisher MDPI

Date 2021 Apr 30

PMID 33921291

Citations 1

Authors

Licinia Timochenco

Raquel Costa-Almeida

Diana Bogas

Filipa A L S Silva

Joana Silva

Andre Pereira

Fernao D Magalhaes

Artur M Pinto

Affiliations

Soon will be listed here.

Abstract

Nanographene oxide (GOn) constitutes a nanomaterial of high value in the biomedical field. However, large scale production of highly stable aqueous dispersions of GOn is yet to be achieved. In this work, we explored high-power ultrasonication as a method to reduce particle size of GO and characterized the impact of the process on the physicochemical properties of the material. GOn was obtained with lateral dimensions of 99 ± 43 nm and surface charge of -39.9 ± 2.2 mV. High-power ultrasonication enabled an improvement of stability features, particularly by resulting in a decrease of the average particle size, as well as zeta potential, in comparison to GO obtained by low-power exfoliation and centrifugation (287 ± 139 nm; -29.7 ± 1.2 mV). Remarkably, GOn aqueous dispersions were stable for up to 6 months of shelf-time, with a global process yield of 74%. This novel method enabled the production of large volumes of highly concentrated (7.5 mg mL) GOn aqueous dispersions. Chemical characterization of GOn allowed the identification of characteristic oxygen functional groups, supporting high-power ultrasonication as a fast, efficient, and productive process for reducing GO lateral size, while maintaining the material's chemical features.

Citing Articles

New MoS/Tegafur-Containing Pharmaceutical Formulations for Selective LED-Based Skin Cancer Photo-Chemotherapy.

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PMID: 38543254 PMC: 10974967. DOI: 10.3390/pharmaceutics16030360.

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