Journal
NANOSCALE
Volume 12, Issue 25, Pages 13626-13636Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/d0nr02069a
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Funding
- CNPq
- Fulbright Commission
- CONICET [PIP 0333, 0093]
- ANPCyT [PICT 2017-4519]
- Universidad Nacional de La Plata of Argentina [UNLP X786, X760]
- FAPERJ [E-26/010.000978/2019, E-26/010.001550/2019]
- U.S. Department of Energy, Office of Basic Energy Sciences, Division of Materials Sciences and Engineering [DE-FG02-07ER46438]
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Magnetite (Fe3O4) nanoparticles are one of the most studied nanomaterials for different nanotechnological and biomedical applications. However, Fe(3)O(4)nanomaterials gradually oxidize to maghemite (gamma-Fe2O3) under conventional environmental conditions leading to changes in their functional properties that determine their performance in many applications. Here we propose a novel strategy to control the surface chemistry of monodisperse 12 nm magnetite nanoparticles by means of a 3 nm-thick Zn-ferrite epitaxial coating in core/shell nanostructures. We have carried out a combined Mossbauer spectroscopy, dc magnetometry, X-ray photoelectron spectroscopy and spatially resolved electron energy loss spectroscopy study on iron oxide and Fe3O4/Zn(0.6)Fe(2.4)O(4)core/shell nanoparticles aged under ambient conditions for 6 months. Our results reveal that while the aged iron oxide nanoparticles consist of a mixture of gamma-Fe(2)O(3)and Fe3O4, the Zn-ferrite-coating preserves a highly stoichiometric Fe(3)O(4)core. Therefore, the aged core/shell nanoparticles present a sharp Verwey transition, an increased saturation magnetization and the possibility of tuning the effective anisotropy through exchange-coupling at the core/shell interface. The inhibition of the oxidation of the Fe(3)O(4)cores can be accounted for in terms of the chemical nature of the shell layer and an epitaxial crystal symmetry matching between the core and the shell.
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