Magnetic field dependent small-angle neutron scattering on a Co nanorod array: evidence for intraparticle spin misalignment

Günther, Annegret; Bick, Jens-Peter; Szary, Philipp; Honecker, Dirk; Dewhurst, C. D.; Keiderling, U.; Feoktystov, Artem; Tschöpe, Andreas; Birringer, R.; Michels, Andreas

doi:10.1107/s1600576714008413

Cited by 33 publications

(40 citation statements)

References 40 publications

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“…Günther et al . 16 have suggested the presence of significant intraparticle spin disorder when analyzing SANS experiments on a Co nanorod array: the strong field dependence of that these authors have observed could not be explained by the standard expression for . Likewise, the polarized SANS experiments on ferromagnetic nanowires by Napolskii et al .…”

Section: Introductionmentioning

confidence: 98%

Small-angle neutron scattering modeling of spin disorder in nanoparticles

Vivas

Yanes

Michels

2017

Sci Rep

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Magnetic small-angle neutron scattering (SANS) is a powerful technique for investigating magnetic nanoparticle assemblies in nonmagnetic matrices. For such microstructures, the standard theory of magnetic SANS assumes uniformly magnetized nanoparticles (macrospin model). However, there exist many experimental and theoretical studies which suggest that this assumption is violated: deviations from ellipsoidal particle shape, crystalline defects, or the interplay between various magnetic interactions (exchange, magnetic anisotropy, magnetostatics, external field) may lead to nonuniform spin structures. Therefore, a theoretical framework of magnetic SANS of nanoparticles needs to be developed. Here, we report numerical micromagnetic simulations of the static spin structure and related unpolarized magnetic SANS of a single cobalt nanorod. While in the saturated state the magnetic SANS cross section is (as expected) determined by the particle form factor, significant deviations appear for nonsaturated states; specifically, at remanence, domain-wall and vortex states emerge which result in a magnetic SANS signal that is composed of all three magnetization Fourier components, giving rise to a complex angular anisotropy on a two-dimensional detector. The strength of the micromagnetic simulation methodology is the possibility to decompose the cross section into the individual Fourier components, which allows one to draw important conclusions regarding the fundamentals of magnetic SANS.

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Section: Introductionmentioning

confidence: 98%

Small-angle neutron scattering modeling of spin disorder in nanoparticles

Vivas

Yanes

Michels

2017

Sci Rep

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“…With typical dimensions of a few tens of nm in cross section, such structures still fit in the framework of nanomaterials (i.e., with two dimensions smaller than ∼ 100 nm). Magnetization reversal in aligned nanowire arrays has been studied using both polarized and unpolarized SANS, and spin misalignment is commonly observed (Grigoryeva et al, 2007;Grutter et al, 2017;Günther et al, 2014;Maurer et al, 2014). However, with a typical nanowire length approaching the micrometer range and usually oriented parallel to the neutron beam, arrays of magnetic nanowires act as a grating, and strong multiple scattering has to be taken into account depending on the nanowire length; this effect is discussed in depth in Grigoriev et al, 2010.…”

Section: Anisotropic Nanostructuresmentioning

confidence: 99%

“…Due to their relatively large volume, nanowires exhibit stable ferromagnetic properties and are mostly multidomain structures. The particle matrix approach is therefore not applicable to nanowires; indeed, micromagnetic simulations (Vivas et al, 2017) and experimental data (Günther et al, 2014) demonstrate strong deviations from the uniform-particle form-factor model.…”

Section: Anisotropic Nanostructuresmentioning

confidence: 99%

Magnetic small-angle neutron scattering

et al. 2019

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Small-angle neutron scattering (SANS) is one of the most important techniques for microstructure determination, being utilized in a wide range of scientific disciplines, such as materials science, physics, chemistry, and biology. The reason for its great significance is that conventional SANS is probably the only method capable of probing structural inhomogeneities in the bulk of materials on a mesoscopic real-space length scale, from roughly 1 − 300 nm. Moreover, the exploitation of the spin degree of freedom of the neutron provides SANS with a unique sensitivity to study magnetism and magnetic materials at the nanoscale. As such, magnetic SANS ideally complements more real-space and surface-sensitive magnetic imaging techniques, e.g., Lorentz transmission electron microscopy, electron holography, magnetic force microscopy, Kerr microscopy, or spinpolarized scanning tunneling microscopy. In this review article we summarize the recent applications of the SANS method to study magnetism and magnetic materials. This includes a wide range of materials classes, from nanomagnetic systems such as soft magnetic Fe-based nanocomposites, hard magnetic Nd−Fe−B-based permanent magnets, magnetic steels, ferrofluids, nanoparticles, and magnetic oxides, to more fundamental open issues in contemporary condensed matter physics such as skyrmion crystals, noncollinar magnetic structures in noncentrosymmetric compounds, magnetic/electronic phase separation, and vortex lattices in type-II superconductors. Special attention is paid not only to the vast variety of magnetic materials and problems where SANS has provided direct insight, but also to the enormous progress made regarding the micromagnetic simulation of magnetic neutron scattering.

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“…Development of a more realistic two-phase model with polydisperse core-shell building blocks is currently underway. The quality of the SANS fit is ambiguous at higher q, and thus we repeated the small-angle measurements using synchrotron x-rays ( If magnetic interactions between nanoparticles are significant the scattering intensity would depend on the magnitude of an applied magnetic field [54][55][56][57] . We subject the solution of the dumbbell nanoparticles into the magnetic field and found no considerable difference between SAXS intensities measured at 0 and 1.2 T for both samples.…”

Section: Resultsmentioning

confidence: 99%

Exchange bias effect inAu-Fe3O4dumbbell nanoparticles induced by the charge transfer from gold

et al. 2015

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We have studied the origin of the exchange bias effect in the Au-Fe 3 O 4 dumbbell nanoparticles in two samples with different sizes of the Au seed nanoparticles (4.1 and 2.7 nm) and same size of Fe 3 O 4 nanoparticles (9.8 nm). The magnetization, small-angle neutron scattering, synchrotron x-ray diffraction and scanning transmission electron microscope measurements determined the antiferromagnetic FeO wüstite phase within Fe 3 O 4 nanoparticles, originating at the interface with the Au nanoparticles. The interface between antiferromagnetic FeO and ferrimagnetic Fe 3 O 4 is giving rise to the exchange bias effect. The strength of the exchange bias fields depends on the interfacial area and lattice mismatch between both phases. We propose that the charge transfer from the Au nanoparticles is responsible for a partial reduction of the Fe 3 O 4 into FeO phase at the interface with Au nanoparticles. The Au-O bonds are formed, presumably across the interface to accommodate an excess of oxygen released during the reduction of magnetite.2

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Magnetic field dependent small-angle neutron scattering on a Co nanorod array: evidence for intraparticle spin misalignment

Cited by 33 publications

References 40 publications

Small-angle neutron scattering modeling of spin disorder in nanoparticles

Small-angle neutron scattering modeling of spin disorder in nanoparticles

Magnetic small-angle neutron scattering

Exchange bias effect inAu-Fe3O4dumbbell nanoparticles induced by the charge transfer from gold

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