posted on 2014-08-05, 00:00authored bySébastien Abramson, Vincent Dupuis, Sophie Neveu, Patricia Beaunier, David Montero
Magnetic cobalt ferrite/silica microparticles
having both an original
morphology and an anisotropic nanostructure are synthesized through
the use of an external magnetic field and nanoparticles characterized
by a high magnetic anisotropy. The association of these two factors
implies that the ESE (emulsion and solvent evaporation) sol–gel
method employed here allows the preparation of silica microellipsoids
containing magnetic nanoparticles aggregated in large chains. It is
clearly shown that without this combination, microspheres characterized
by an isotropic distribution of the magnetic nanoparticles are obtained.
While the chaining of the cobalt ferrite nanoparticles inside the
silica matrix is related to the increase of their magnetic dipolar
interactions, the ellipsoidal shape of the microparticles may be explained
by the elongation of the sol droplets in the direction of the external
magnetic field during the synthesis. Because of their highly anisotropic
structure, these microparticles exhibit permanent magnetic moments,
which are responsible, at a larger scale, for the existence of strong
magnetic dipolar interactions. Therefore, when they are dispersed
in water, the microellipsoids self-assemble into large and irregular
chains. These interactions can be reinforced by the use of external
magnetic field, allowing the preparation of very large permanent chains.
This research illustrates how nanostructured particles exhibiting
complex architectures can be elaborated through simple, fast, and
low-cost methods, such as the use of external fields in combination
with soft chemistry.