Diverging geometric and magnetic size distributions of iron oxide nanocrystals
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2011
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Abstract
An important reason to prepare magnetic nanoparticles of uniform size and shape is to ensure uniform magnetic properties. However, here, we demonstrate that magnetic iron oxide crystals of 20 nm or less with a low polydispersity of the geometric size can nevertheless have a strikingly broad distribution of the magnetic dipole moment. A comparative study was performed on nanoparticles with near-perfect crystallinity, twinning defects, or a high density of dislocations. Size, shape, and crystal defects were characterized with electron microscopy and X-ray diffraction, and magnetic dipole moments were determined from magnetization curves of dilute colloidal dispersions. The largest divergence was found for spherical particles with 3.5% geometric size polydispersity and 35% magnetic size polydispersity due to crystal lattice defects that disrupt single-domain magnetic spin coupling. This is in stark contrast with the usual implicit assumption that uniform size and shape guarantee welldefined magnetic properties of the individual particles.
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Luigjes, B, Woudenberg, S M C, de Groot, R, Meeldijk, J D, Torres Galvis, H M, de Jong, K P, Philipse, A P & Erné, B H 2011, 'Diverging geometric and magnetic size distributions of iron oxide nanocrystals', Journal of Physical Chemistry C, vol. 115, no. 30, pp. 14598-14605. https://doi.org/10.1021/jp203373f