Nader Yaacoub scite author profile

CoFe(2)O(4) nanoparticles (D(NPD) ~6 nm), prepared by a thermal decomposition technique, have been investigated through the combined use of dc magnetization measurements, neutron diffraction, and (57)Fe Mössbauer spectrometry under high applied magnetic field. Despite the small particle size, the value of saturation magnetization at 300 K (M(s) ͠= 70 A m(2) kg(-1)) and at 5 K (M(s) ͠= 100 A m(2) kg(-1)) are rather close to the bulk values, making the samples prepared with this method attractive for biomedical applications. Neutron diffraction measurements indicate the typical ferrimagnetic structure of the ferrites, showing an inversion degree (γ(NPD) = 0.74) that is in very good agreement with cationic distribution established from low temperature (10 K) Mössbauer measurements in high magnetic field (γ(moss) = 0.76). In addition, the in-field Mössbauer spectrum shows the presence of a non-collinear spin structure in both A and B sublattices. The results allow us to explain the high value of saturation magnetization and provide a better insight into the complex interplay between cationic distribution and magnetic disorder in ferrimagnetic nanoparticles.

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Remanence Plots as a Probe of Spin Disorder in Magnetic Nanoparticles

Toro

Vasilakaki

Lee

et al. 2017

Chem. Mater.

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Remanence magnetization plots (e.g., Henkel or δM plots) have been extensively used as a straightforward way to determine the presence and intensity of dipolar and exchange interactions in assemblies of magnetic nanoparticles or single domain grains.Their evaluation is particularly important in functional materials whose performance is strongly affected by the intensity of interparticle interactions, such as patterned recording media and nanostructured permanent magnets, as well as in applications such as hyperthermia and magnetic resonance imaging. Here we demonstrate that δM plots may be misleading when the nanoparticles do not have a homogeneous internal magnetic configuration. Substantial dips in the δM plots of γ-Fe 2 O 3 nanoparticles isolated by thick SiO 2 shells indicate the presence of demagnetizing interactions, usually identified as dipolar interactions. Our results, however, demonstrate that it is the inhomogeneous spin structure of the nanoparticles, as most clearly evidenced by Mössbauer measurements, that has a pronounced effect on the δM plots, leading to features remarkably similar to those produced by dipolar interactions. X-ray diffraction results combined with magnetic characterization indicate that this inhomogeneity is due to the presence of surface structural (and spin) disorder. Monte Carlo simulations unambiguously corroborate the critical role of the internal magnetic structure in the δM plots. Our findings constitute a cautionary tale on the widespread use of remanence plots to assess interparticle interactions, as well as offer new perspectives in the use of Henkel-and δM-plots to quantify the rather elusive inhomogeneous magnetizations states in nanoparticles.Additional information on the δM and the in-field Mössbauer techniques, table with the complete results of the Mössbauer spectra fits, details of the Monte Carlo simulations, FC and ZFC magnetization curves of the VST series (Fig. S1a), Langevin scaling of M(H;T) data measured in VST45 (Fig. S1b), details on the estimate of the "magnetic size" from Langevin fits, δM plots of all the VST series and graphical analysis of the intraparticle and interparticle contributions to the dip (Fig. S2), example of hysteresis loops measured after ZFC and FC (for sample VST17, Fig. S3); X-ray diffraction patterns and lattice parameter across of the maghemite cores of different size (Fig. S4); complete results from Monte Carlo simulations showing the dependence of δM on core anisotropy (Fig. S5), surface anisotropy ( Fig. S6), exchange coupling constant ( Fig. S7) and disordered surface thickness (Fig. S8).

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Size-dependent magnetic properties of CoFe₂O₄nanoparticles prepared in polyol

Artus

Tahar²,

Herbst

et al. 2011

J. Phys.: Condens. Matter

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Highly crystalline CoFe(2)O(4) nanoparticles with different diameters ranging from 2.4 to 6.1 nm have been synthesized by forced hydrolysis in polyol. The size can be controlled through adjusting the nominal water/metal molar ratio. X-ray diffraction, transmission electron microscopy, x-ray absorption spectroscopy and (57)Fe Mössbauer spectrometry were employed to investigate the structure and the microstructure of the particles produced. Magnetic measurements performed on these particles show that they are superparamagnetic with a size-dependent blocking temperature. At 5 K, high saturation magnetization (~85 emu g(-1)) approaching that of the bulk was found for the larger particles, whereas a very large coercivity (14.5 kOe) is observed for the 3.5 nm sized particles.

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Enhancing the magnetic anisotropy of maghemite nanoparticles via the surface coordination of molecular complexes

et al. 2015

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Superparamagnetic nanoparticles are promising objects for data storage or medical applications. In the smallest—and more attractive—systems, the properties are governed by the magnetic anisotropy. Here we report a molecule-based synthetic strategy to enhance this anisotropy in sub-10-nm nanoparticles. It consists of the fabrication of composite materials where anisotropic molecular complexes are coordinated to the surface of the nanoparticles. Reacting 5 nm γ-Fe2O3 nanoparticles with the [CoII(TPMA)Cl2] complex (TPMA: tris(2-pyridylmethyl)amine) leads to the desired composite materials and the characterization of the functionalized nanoparticles evidences the successful coordination—without nanoparticle aggregation and without complex dissociation—of the molecular complexes to the nanoparticles surface. Magnetic measurements indicate the significant enhancement of the anisotropy in the final objects. Indeed, the functionalized nanoparticles show a threefold increase of the blocking temperature and a coercive field increased by one order of magnitude.

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Evolution of the magnetic structure with chemical composition in spinel iron oxide nanoparticles

et al. 2015

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Magnetic properties of iron oxide nanoparticles with spinel structure are strictly related to a complex interplay between cationic distribution and the presence of a non-collinear spin structure (spin canting). With the aim to gain better insight into the effect of the magnetic structure on magnetic properties, in this paper we investigated a family of small crystalline ferrite nanoparticles of the formula CoxNi1-xFe2O4 (0 ≤x≤ 1) having equal size (≈4.5 nm) and spherical-like shape. The field dependence of magnetization at low temperatures indicated a clear increase of magnetocrystalline anisotropy and saturation magnetization (higher than the bulk value for CoFe2O4: ∼130 A m(2) kg(-1)) with the increase of cobalt content. The magnetic structure of nanoparticles has been investigated by Mössbauer spectroscopy under an intense magnetic field (8 T) at a low temperature (10 K). The magnetic properties have been explained in terms of an evolution of the magnetic structure with the increase of cobalt content. In addition a direct correlation between cationic distribution and spin canting has been proposed, explaining the presence of a noncollinear spin structure in terms of superexchange interaction energy produced by the average cationic distribution and vacancies in the spinel structure.

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Annealing Effect on the Magnetic Properties of Polyol-made Ni−Zn Ferrite Nanoparticles

Beji

Smiri²,

Yaacoub

et al. 2010

Chem. Mater.

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The effects of annealing on the magnetic properties of nanocrystalline Ni 1-x Zn x Fe 2 O 4 (x = 0.2, 0.4) have been studied. The as-prepared x = 0.2 and 0.4 samples with the particle size of about 6 nm present a relatively low blocking temperature of about 47 and 53 K, respectively, as derived from the peak of the zero-field-cooled direct current (dc) susceptibility measurements. The particle size significantly increases after annealing. Up to the annealing temperature of 800 °C, the blocking temperature is found to increase with increasing particle size, whereas the effective anisotropy constant exhibits a maximum for an annealing temperature of 400 °C. The latter effect is attributed to two antagonist contributions: the first one is related to the partial densification of the particles which introduces canting in the crystal interfaces while the second one is related to the size increase of the particles which reduces the surface anisotropy contribution.

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Optimising the magnetic performance of Co ferrite nanoparticles via organic ligand capping

et al. 2018

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Gold–iron oxide dimers for magnetic hyperthermia: the key role of chloride ions in the synthesis to boost the heating efficiency

et al. 2017

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Nader Yaacoub

Cationic distribution and spin canting in CoFe₂O₄nanoparticles

Remanence Plots as a Probe of Spin Disorder in Magnetic Nanoparticles

Size-dependent magnetic properties of CoFe₂O₄nanoparticles prepared in polyol

Enhancing the magnetic anisotropy of maghemite nanoparticles via the surface coordination of molecular complexes

Evolution of the magnetic structure with chemical composition in spinel iron oxide nanoparticles

Annealing Effect on the Magnetic Properties of Polyol-made Ni−Zn Ferrite Nanoparticles

Optimising the magnetic performance of Co ferrite nanoparticles via organic ligand capping

Gold–iron oxide dimers for magnetic hyperthermia: the key role of chloride ions in the synthesis to boost the heating efficiency

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Nader Yaacoub

Cationic distribution and spin canting in CoFe2O4nanoparticles

Remanence Plots as a Probe of Spin Disorder in Magnetic Nanoparticles

Size-dependent magnetic properties of CoFe2O4nanoparticles prepared in polyol

Enhancing the magnetic anisotropy of maghemite nanoparticles via the surface coordination of molecular complexes

Evolution of the magnetic structure with chemical composition in spinel iron oxide nanoparticles

Annealing Effect on the Magnetic Properties of Polyol-made Ni−Zn Ferrite Nanoparticles

Optimising the magnetic performance of Co ferrite nanoparticles via organic ligand capping

Gold–iron oxide dimers for magnetic hyperthermia: the key role of chloride ions in the synthesis to boost the heating efficiency

Contact Info

Product

Resources

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Cationic distribution and spin canting in CoFe₂O₄nanoparticles

Size-dependent magnetic properties of CoFe₂O₄nanoparticles prepared in polyol