Role of Oxygen Defects on the Magnetic Properties of Ultra-Small Sn1−xFexO2 Nanoparticles

Kelsey Dodge, Jordan Chess, Josh Eixenberger, Gordon Alanko, Charles B. Hanna, Alex Punnoose

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21 Scopus citations

Abstract

Although the role of oxygen defects in the magnetism of metal oxide semiconductors has been widely discussed, it is been difficult to directly measure the oxygen defect concentration of samples to verify this. This work demonstrates a direct correlation between the photocatalytic activity of Sn 1-xFexO2 nanoparticles and their magnetic properties. For this, a series of ∼2.6 nm sized, well characterized, single-phase Sn1-xFexO2 crystallites with x 0-0.20 were synthesized using tin acetate, urea, and appropriate amounts of iron acetate. X-ray photoelectron spectroscopy confirmed the concentration and 3 oxidation state of the doped Fe ions. The maximum magnetic moment/Fe ion, μ, of 1.6 × 10-4 μB observed for the 0.1 Fe doped sample is smaller than the expected spin-only contribution from either high or low spin Fe3 ions, and μ decreases with increasing Fe concentration. This behavior cannot be explained by the existing models of magnetic exchange. Photocatalytic studies of pure and Fe-doped SnO2 were used to understand the roles of doped Fe3 ions and of the oxygen vacancies and defects. The photocatalytic rate constant k also showed an increase when SnO2 nanoparticles were doped with low concentrations of Fe3, reaching a maximum at 0.1 Fe, followed by a rapid decrease of k for further increase in Fe. Fe doping presumably increases the concentration of oxygen vacancies, and both Fe3 ions and oxygen vacancies act as electron acceptors to reduce e--h recombination and promote transfer of electrons (and/or holes) to the nanoparticle surface, where they participate in redox reactions. This electron transfer from the Fe3 ions to local defect density of states at the nanoparticle surface could develop a magnetic moment at the surface states and leads to spontaneous ferromagnetic ordering of the surface shell under favorable conditions. However, at higher doping levels, the same Fe3 ions might act as recombination centers causing a decrease of both k and magnetic moment μ.

Original languageAmerican English
Article number17B504
JournalJournal of Applied Physics
Volume113
Issue number17
DOIs
StatePublished - 7 May 2013

EGS Disciplines

  • Physics

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