scholarly journals Features in the Resonance Behavior of Magnetization in Arrays of Triangular and Square Nanodots

Author(s):  
Vitaly A. Orlov ◽  
◽  
Roman Yu. Rudenko ◽  
Vladimir S. Prokopenko ◽  
Irina N. Orlova ◽  
...  

Collective modes of the gyrotropic motion of a magnetic vortex core in ordered arrays of triangular and square ferromagnetic film nanodots have been theoretically investigated. The dispersion relations have been derived. The dipole–dipole interaction of the magnetic moments of the magnetic vortex cores of elements has been taken into account in the approximation of a small shift from the equilibrium position. It is shown that the effective rigidity of the magnetic subsystem of triangular elements is noticeably higher than that of the subsystem of square elements of the same linear sizes. The potential application of the polygonal film nanodisks as nanoscalpels for noninvasive tumor cell surgery is discussed

Author(s):  
T. Ono

This chapter defines a magnetic domain wall (DW) as the transition region where the direction of magnetic moments gradually change between two neighbouring domains. It has been pointed out that ferromagnetic materials are not necessarily magnetized to saturation in the absence of an external magnetic field. Instead, they have magnetic domains, within each of which magnetic moments align. The formation of the magnetic domains is energetically favourable because this structure can lower the magnetostatic energy originating from the dipole–dipole interaction. A magnetic vortex realized in a ferromagnetic disk is a typical example of nonuniform magnetic structure. In very small ferromagnetic systems, where a curling spin configuration has been proposed to occur in place of domains, the formation of DWs is not energetically favored.


2019 ◽  
Vol 945 ◽  
pp. 771-775 ◽  
Author(s):  
V.P. Panaetov ◽  
Denis B. Solovev

Ferromagnetic film can be a matrix for recording information with the help of magnetic moments of electrons. The study of the processes of changing the magnetic structure in an electron-transmission microscope makes it possible to investigate micro magnetic phenomena. In this paper, we investigate the interaction between the vertices of neighboring regions. It is shown how the magnetic structure of the vertices of the domains changes as they approach each other with the help of an increasing constant magnetic field applied along the axis of easy magnetization. The distance was measured between the vertices of the domains. The schemes of distribution of the magnetization vectors between interacting vertices are shown. These schemes are made from experimental images of the magnetic structure. The distances between domain vertices and domain walls were compared on the basis of experimental data. The film thickness is 50 nm; the structure is Ni0.83-Fe0.17. The films were obtained by the method proposed by us. From the experimental results it follows that the interaction of the domain walls is observed at a distance of 20 microns and the interaction of the domain vertices is manifested at a distance of 100 μm.


Author(s):  
Irina V. Tyulkina ◽  
Denis S. Goldobin ◽  
Lyudmila S. Klimenko ◽  
Igor S. Poperechny ◽  
Yuriy L. Raikher

The problem of magnetic transitions between the low-temperature (macrospin ordered) phases in two-dimensional XY arrays is addressed. The system is modelled as a plane structure of identical single-domain particles arranged in a square lattice and coupled by the magnetic dipole–dipole interaction; all the particles possess a strong easy-plane magnetic anisotropy. The basic state of the system in the considered temperature range is an antiferromagnetic (AF) stripe structure, where the macrospins (particle magnetic moments) are still involved in thermofluctuational motion: the superparamagnetic blocking T b temperature is lower than that ( T af ) of the AF transition. The description is based on the stochastic equations governing the dynamics of individual magnetic moments, where the interparticle interaction is added in the mean-field approximation. With the technique of a generalized Ott–Antonsen theory, the dynamics equations for the order parameters (including the macroscopic magnetization and the AF order parameter) and the partition function of the system are rigorously obtained and analysed. We show that inside the temperature interval of existence of the AF phase, a static external field tilted to the plane of the array is able to induce first-order phase transitions from AF to ferromagnetic state; the phase diagrams displaying stable and metastable regions of the system are presented. This article is part of the theme issue ‘Patterns in soft and biological matters’.


2013 ◽  
Vol 1617 ◽  
pp. 193-197
Author(s):  
Mishel Morales Meza ◽  
Paul P. Horley ◽  
Alexander Sukhov

ABSTRACTMagnetic properties at nano-scale provide a whole spectrum of new phenomena that can be beneficial for spintronic devices characterized with ultra-short response time, high sensitivity to magnetic field and miniature size. The properties and stability of a magnetic system can be enhanced by creating ordered arrays of ferromagnetic nano-particles. Here we report a considerable reduction of coercitivity for a magnetic array using triangular, square and hexagonal particle arrangement. The reduction of coercitivity can be explained by fine-tuning of dipole-dipole interaction between magnetic particles, which is to large degree influenced by the number of nearest neighbors and distance between the particles.


2019 ◽  
Vol 61 (10) ◽  
pp. 1783
Author(s):  
А.М. Шутый ◽  
Д.И. Семенцов

The magnetic moment response of a magneto-uniaxial nanoparticle and a flat lattice of similar nanoparticles are being studied under the action of a short Gaussian pulse of a magnetic field in the presence and in the absence of its modulation. The periodic dependence of the final orientation and duration of a response of the magnetic moments on the pulse duration and its peak value have been revealed and analyzed. The effect on processes magnetization reversal of a weak magnetizing field and the deviation of the pulse of field from the transverse orientation has been studied. Have been shown that the influence of the dipole-dipole interaction leads to modulation of the response to the pulse action.


In this contribution we hope to illustrate with preliminary measurements some of the ways in which nuclear-electron double resonance experiments can yield information of value to the chemist. The magnetic coupling between a paramagnetic electron of spin S and a nucleus of spin I may be described (Abragam 1961) by the spin Hamiltonian H s, I = γ e γ n I [3r(S. r)/ r 5 – S/ r 3 + 16 π /3 S| ψ e (0)| 2 ], where γ e , γ n are the electron and nuclear gyromagnetic ratios respectively, r is the vector radius joining I and S and | ψ e (0)| 2 is a measure of the overlap between the electron and nuclear wave functions. The first two terms describe the magnetic dipole-dipole interaction dominant at large interspin distances, and the third covers any short-range scalar or contact interactions. In non-viscous solutions of free radicals the rapid relative motion of the spins causes the Hamiltonian to become time dependent. If the motion is quite random the dipolar terms become entirely time dependent and are significant only in electron-nucleus relaxation phenomena. The scalar term, on the other hand, may not be completely averaged and can thus cause both relaxation phenomena and paramagnetic shifts in the nuclear resonance spectrum of the solvent (Bloembergen 1957). Thus the dynamic parts of both the scalar and the dipolar interactions are effective in producing mutual relaxation of the spins. Just which of the possible two spin processes is the most effective can be found by expanding the time-dependent Hamiltonian from equation (1) into its component spin operators and finding their relative spectral densities (Abragam 1955,1961). The dipole-dipole part of the Hamiltonian then becomes H d.d ( t ) = [ J 1 S z I z + J 2 {S + I_ + S_I + } + J 3 { S z I + + I z S + } ( A ) ( B ) ( C ) + J 3 { S z I_ + I z S_} + J 4 {S + I + } + J 4 {S_I_}] σ 1 /< r 3 SI >, ( D ) ( E ) ( F ) and the scalar part becomes H sc . ( t ) = [ J 5 S z I z + J 6 {S + I_ + S_I + }] σ 2 | ψ e (0)| 2 , where < r 3 SI > is the mean value of the cube of the electron-nuclear distance, σ1 and σ2 are proportionality constants, the J ’s are the spectral densities, S z , I z are the z components of the spin operators and S + I + ; S_I_ are the raising and lowering operators for the electron and nuclear spins respectively. For a white spectrum of relative motions between the spins, terms E and F are not the most important for dipolar coupling. This leads to the established reversal of nuclear polarization in Overhauser experiments between nuclei with positive magnetic moments and electrons (Richards & White 1962 a, b ). Under the same conditions a dominant scalar coupling leads to an enhancement of the nuclear polarization because of its different relaxation operators.


2019 ◽  
Vol 10 ◽  
pp. 305-314 ◽  
Author(s):  
Nikolai A Usov ◽  
Mikhail S Nesmeyanov ◽  
Elizaveta M Gubanova ◽  
Natalia B Epshtein

The low frequency hysteresis loops and specific absorption rate (SAR) of assemblies of magnetite nanoparticles with cubic anisotropy are calculated in the diameter range of D = 20–60 nm taking into account both thermal fluctuations of the particle magnetic moments and strong magneto–dipole interaction in assemblies of fractal-like clusters of nanoparticles. Similar calculations are also performed for assemblies of slightly elongated magnetite nanoparticles having combined magnetic anisotropy. A substantial dependence of the SAR on the nanoparticle diameter is obtained for all cases investigated. Due to the influence of the magneto–dipole interaction, the SAR of fractal clusters of nanoparticles decreases considerably in comparison with that for weakly interacting nanoparticles. However, the ability of magnetic nanoparticle assemblies to generate heat can be improved if the nanoparticles are covered by nonmagnetic shells of appreciable thickness.


1977 ◽  
Vol 32 (11) ◽  
pp. 1263-1265 ◽  
Author(s):  
K. U. Buckler ◽  
J. Kronenbitter ◽  
. Lutz ◽  
A. Nollle

Abstract The NMR signals of 123Te and 125Te have been observed in solutions of K2TeO3 and Na2TeO3 in D2O. In these solutions the ratios of Larmor frequencies ν(125Te)/ν(123Te), ν(125Te)/v(2H) and ν(125Te)/ν(23Na) have been determined with high accuracy. With the measured chemical shifts of 2H, 23Na, 125Te relative to infinitely diluted solutions the ratios of the Larmor frequencies are extrapolated and values of the magnetic moments are given. The relaxation times T1 and T2 are very different for 125Te in TeO32-: a ratio T1/T2 of 8.2 ± 0.4 has been found. No nuclear Overhauser effect due to dipole-dipole interaction of 125Te with the water protons has been detected.


2020 ◽  
Vol 10 (1) ◽  
Author(s):  
Wataru Koshibae ◽  
Naoto Nagaosa

AbstractThe magnetic skyrmion is a topological magnetic vortex, and its topological nature is characterized by an index called skyrmion number which is a mapping of the magnetic moments defined on a two-dimensional space to a unit sphere. In three-dimensions, a skyrmion, i.e., a vortex penetrating though the magnet naturally forms a string, which terminates at the surfaces of the magnet or in the bulk. For such a string, the topological indices, which control its topological stability are less trivial. Here, we study theoretically, in terms of numerical simulation, the dynamics of current-driven motion of a skyrmion string in a film sample with the step edges on the surface. In particular, skyrmion–antiskyrmion pair is generated by driving a skyrmion string through the side step with an enough height. We find that the topological indices relevant to the stability are the followings; (1) skyrmion number along the developed surface, and (2) the monopole charge in the bulk defined as the integral over the surface enclosing a singular magnetic configuration. As long as the magnetic configuration is slowly varying, the former is conserved while its changes is associated with nonzero monopole charge. The skyrmion number and the monoplole charge offer a coherent understanding of the stability of the topological magnetic texture and the nontrivial dynamics of skyrmion strings.


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