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Vacancy-driven non-cubic local structure and magnetic anisotropy tailoring in Fe_xO-Fe_(3-δ)O₄ nanocrystals

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arxiv 2005.07947 v1 pith:EXVGQOIU submitted 2020-05-16 cond-mat.mtrl-sci

Vacancy-driven non-cubic local structure and magnetic anisotropy tailoring in Fe_xO-Fe_(3-δ)O₄ nanocrystals

classification cond-mat.mtrl-sci
keywords propertieslocalcontrolnanocrystalsstructureanisotropyaspiresatomic-scale
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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In contrast to bulk materials, nanoscale crystal growth is critically influenced by size- and shape-dependent properties. However, it is challenging to decipher how stoichiometry, in the realm of mixed-valence elements, can act to control physical properties, especially when complex bonding is implicated by short and long-range ordering of structural defects. Here, solution-grown iron-oxide nanocrystals (NCs) of the pilot wustite system are found to convert into iron-deficient rock-salt and ferro-spinel sub-domains, but attain a surprising tetragonally distorted local structure. Cationic vacancies within chemically uniform NCs are portrayed as the parameter to tweak the underlying properties. These lattice imperfections are shown to produce local exchange-anisotropy fields that reinforce the nanoparticles magnetization and overcome the influence of finite-size effects. The concept of atomic-scale defect control in subcritical size NCs, aspires to become a pathway to tailor-made properties with improved performance for hyperthermia heating over defect-free NCs.

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