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Enhanced oxidation of nanoparticles through strain-mediated ionic transport.

Nature materials (2013-11-05)
Andrew Pratt, Leonardo Lari, Ondrej Hovorka, Amish Shah, Charles Woffinden, Steve P Tear, Chris Binns, Roland Kröger
RESUMEN

Geometry and confinement effects at the nanoscale can result in substantial modifications to a material's properties with significant consequences in terms of chemical reactivity, biocompatibility and toxicity. Although benefiting applications across a diverse array of environmental and technological settings, the long-term effects of these changes, for example in the reaction of metallic nanoparticles under atmospheric conditions, are not well understood. Here, we use the unprecedented resolution attainable with aberration-corrected scanning transmission electron microscopy to study the oxidation of cuboid Fe nanoparticles. Performing strain analysis at the atomic level, we reveal that strain gradients induced in the confined oxide shell by the nanoparticle geometry enhance the transport of diffusing species, ultimately driving oxide domain formation and the shape evolution of the particle. We conjecture that such a strain-gradient-enhanced mass transport mechanism may prove essential for understanding the reaction of nanoparticles with gases in general, and for providing deeper insight into ionic conductivity in strained nanostructures.

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Sigma-Aldrich
Iron(III) oxide, powder, <5 μm, ≥96%
Sigma-Aldrich
Iron(III) oxide, nanopowder, <50 nm particle size (BET)
Sigma-Aldrich
Iron(III) oxide, ≥99.995% trace metals basis
Sigma-Aldrich
Iron(III) oxide, dispersion, nanoparticles, ≤110 nm particle size, 15 wt. % in ethanol
Sigma-Aldrich
Iron(III) oxide, SAJ first grade, ≥98.0%