• Ababei, Gabriel
• Ursu, Laura
• Lupu, Nicoleta
• Ardeleanu, Helmina
• Grigoras, Marian
• Angelica, Pricop Daniela
• Creanga, Dorina
• Astefanoaei, Iordana
• Melniciuc-Puica, Nicoleta

Abstract

<jats:p>Among the modern oncological therapies, one of the most promising is based on tumor hyperthermia with magnetic nanoparticles resulting from the crystallization of iron and cobalt oxides. We synthesized core–shell magnetic nanoparticles of perchlorate-CoxFe3−xO4 (x = 0; 0.5; 1.0) via the co-precipitation method and stabilized them in aqueous suspensions. Fine granulation of the dispersed ferrophase was revealed by Transmission Electron Microscopy and Dynamical Light Scattering, with FTIR data detailing the surface-interaction phenomena. X-ray diffractometry revealed specific crystallization features of inverse spinel lattice, providing crystallite size and lattice parameters dependent on the cobalt content. The results of the Vibrating Sample Magnetometry investigations indicated that cobalt doping has reduced the magnetic core size and increased the nanoparticle dimension, which could be the result of crystallization defects at the nanoparticle surface related to the presence of cobalt ions. A mathematical model was applied with a focus on the quantitative description of the temperature distribution around magnetic nanoparticles. Further development of our research will consider new cobalt ferrite nanoparticles with new cobalt contents and different organic coatings to contribute to their biocompatibility and stability in aqueous suspensions, as required by administration in living organisms.</jats:p>

Topics

• nanoparticle
• impedance spectroscopy
• surface
• transmission electron microscopy
• defect
• precipitation
• cobalt
• iron
• crystallization
• biocompatibility
• light scattering