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Optimisation of the Flame Spheroidisation Process for the Rapid Manufacture of Fe3O4-Based Porous and Dense Microspheres

Molinar-Díaz, Jesús; Woodliffe, John Luke; Steer, Elisabeth; Morley, Nicola A.; Brown, Paul D.; Ahmed, Ifty

Optimisation of the Flame Spheroidisation Process for the Rapid Manufacture of Fe3O4-Based Porous and Dense Microspheres Thumbnail


Authors

John Luke Woodliffe

Elisabeth Steer

Nicola A. Morley



Contributors

Igor Djerdj
Editor

Abstract

The rapid, single-stage, flame-spheroidisation process, as applied to varying Fe3O4:CaCO3 powder combinations, provides for the rapid production of a mixture of dense and porous ferromagnetic microspheres with homogeneous composition, high levels of interconnected porosity and microsphere size control. This study describes the production of dense (35–80 µm) and highly porous (125–180 µm) Ca2Fe2O5 ferromagnetic microspheres. Correlated backscattered electron imaging and mineral liberation analysis investigations provide insight into the microsphere formation mechanisms, as a function of Fe3O4/porogen mass ratios and gas flow settings. Optimised conditions for the processing of highly homogeneous Ca2Fe2O5 porous and dense microspheres are identified. Induction heating studies of the materials produced delivered a controlled temperature increase to 43.7 °C, indicating that these flame-spheroidised Ca2Fe2O5 ferromagnetic microspheres could be highly promising candidates for magnetic induced hyperthermia and other biomedical applications.

Citation

Molinar-Díaz, J., Woodliffe, J. L., Steer, E., Morley, N. A., Brown, P. D., & Ahmed, I. (2023). Optimisation of the Flame Spheroidisation Process for the Rapid Manufacture of Fe3O4-Based Porous and Dense Microspheres. Molecules, 28(6), Article 2523. https://doi.org/10.3390/molecules28062523

Journal Article Type Article
Acceptance Date Mar 7, 2023
Online Publication Date Mar 9, 2023
Publication Date Mar 9, 2023
Deposit Date Apr 3, 2023
Publicly Available Date Apr 6, 2023
Journal Molecules
Electronic ISSN 1420-3049
Publisher MDPI
Peer Reviewed Peer Reviewed
Volume 28
Issue 6
Article Number 2523
DOI https://doi.org/10.3390/molecules28062523
Keywords Magnetite, magnetic particles, porous microspheres, calcium ferrites, flame spheroidisation, ceramics, magnetic hyperthermia
Public URL https://nottingham-repository.worktribe.com/output/18529720
Publisher URL https://www.mdpi.com/1420-3049/28/6/2523

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