Vacancy-Driven Noncubic Local Structure and Magnetic Anisotropy Tailoring in FexO−Fe3−δO4 Nanocrystals

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 impli...

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Veröffentlicht in:	Physical review. X 2019-11, Vol.9 (4)
Hauptverfasser:	Lappas, Alexandros, Antonaropoulos, George, Brintakis, Konstantinos, Vasilakaki, Marianna, Trohidou, Kalliopi N, Iannotti, Vincenzo, Ausanio, Giovanni, Kostopoulou, Athanasia, Abeykoon, Milinda, Robinson, Ian K, Bozin, Emil S
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Sprache:	eng
Schlagworte:	Anisotropy Cations Crystal defects Crystal growth Defects Energy dissipation Energy transfer Heat exchange Heating Hyperthermia Iron Lattice sites Lattice vacancies Magnetic anisotropy Magnetic properties Nanocrystals Nanoparticles Oxidation Parameters Physical properties Single crystals Size effects Stoichiometry Thermal energy Valence Wustite
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container_title	Physical review. X
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creator	Lappas, Alexandros Antonaropoulos, George Brintakis, Konstantinos Vasilakaki, Marianna Trohidou, Kalliopi N Iannotti, Vincenzo Ausanio, Giovanni Kostopoulou, Athanasia Abeykoon, Milinda Robinson, Ian K Bozin, Emil S
description	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 wüstite system are found to convert into iron-deficient rock-salt and ferro-spinel subdomains 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.
doi_str_mv	10.1103/PhysRevX.9.041044
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subjects	Anisotropy Cations Crystal defects Crystal growth Defects Energy dissipation Energy transfer Heat exchange Heating Hyperthermia Iron Lattice sites Lattice vacancies Magnetic anisotropy Magnetic properties Nanocrystals Nanoparticles Oxidation Parameters Physical properties Single crystals Size effects Stoichiometry Thermal energy Valence Wustite
title	Vacancy-Driven Noncubic Local Structure and Magnetic Anisotropy Tailoring in FexO−Fe3−δO4 Nanocrystals
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