Micromagnetic Studies Research Articles

Study on Magnetization Reversal Processes of Anisotropic HDDR Pr2Fe14B-Type Magnetic Materials

The magnetization reversal processes of hydrogenation–disproportionation–desorption–recombination (HDDR) anisotropic Pr–Fe–B magnetic powders were systematically investigated. It is found that with the increase of external magnetic field, the magnetization first increases rapidly, and then increases slowly, and finally increases rapidly again. The increasing trend of coercivity with the increase of external magnetic field is just opposite to that mentioned above. Further micromagnetic simulation studies suggest that the coercivity is mainly controlled by the nucleation of reversed domain, and this is also indicated by the subsequent investigation for the evolution of the magnetic domain under the magnetic field.

Micromagnetic simulation of vortex core polarity in bi-component magnetic nanodisks

The nucleation and management of the vortex state in magnetic nanostructures has received a lot of interest in recent decades, with potential applications in logic networks and non-volatile magnetic random-access memory. Because of their potential use in magnetic memory, magnetic vortex structures are of considerable technical importance. Investigation of bi-component magnetic nanodisks as prospective storage systems, in both single and coupled configurations, has been performed, where the information unit is represented by vortex core polarity. The work mainly engages in magnetic nanodisks of permalloy and iron having a diameter of 200 nm and a thickness of 40 nm. The potential of adjusting the polarity of the vortex core by the application of a magnetic field using micromagnetic simulations has been illustrated. Micromagnetic simulation studies show that bi-material structures are important not just for fundamental research but also for data storage.

XDWM: A 2D Domain Wall Memory

Domain-Wall Memory (DWM) structures typically bundle nanowires shifted together for parallel access. Ironically, this organization does not allow the natural shifting of DWM to realize \textit{logical shifting} within data elements. We describe a novel 2-D DWM cross-point (X-Cell) that allows two individual nanowires placed orthogonally to share the X-Cell. Each nanowire can operate independently while sharing the value at the X-Cell. Using X-Cells, we propose an orthogonal nanowire in the Y dimension overlaid on a bundle of X dimension nanowires for a cross-DWM or XDWM. We demonstrate that the bundle shifts correctly in the X-Direction, and that data can be logically shifted in the Y-direction providing novel data movement and supporting processing-in-memory. We conducted studies on the requirements for physical cell dimensions and shift currents for XDWM. Due to the non-standard domain, our micro-magnetic studies demonstrate that XDWM introduces a shift current penalty of 6.25% while shifting happens in one nanowire compared to a standard nanowire. We also demonstrate correct shifting using nanowire bundles in both the X- and Y- dimensions. Using magnetic simulation to derive the values for SPICE simulation we show the maximum leakage current between nanowires when shifting the bundle together is $\le3$% indicating that sneak paths are not problematic for XDWM.

Isolated skyrmion, skyrmion lattice and antiskyrmion lattice creation through magnetization reversal in Co/Pd nanostructure

Skyrmion and antiskyrmion spin textures are axisymmetric inhomogeneous localized objects with distinct chirality in magnetic systems. These spin textures are potential candidates for the next generation energy-efficient spintronic applications due to their unique topological properties. Controlled and effective creation of the spin textures is required to use in conventional and neuromorphic computing applications. Here we show by micromagnetic simulations creating an isolated skyrmion, skyrmion lattice and antiskyrmion lattice through the magnetization reversal in Co/Pd multilayer nanostructure using spin-polarized current. The spin textures' stability depends on the spin-polarized current density, current pulse width, and Dzyaloshinskii–Moriya interaction (DMI). Antiskyrmions are evolved during the formation of a single skyrmion and skyrmion lattice. Skyrmion and antiskyrmion lattices together are observed for lower pulse width, 0.05 ns. Our micromagnetic studies suggest that the two distinct lattice phases' evolution could help to design the topological spin textures-based devices.

Unidirectional emission and reconfigurability of channeled spin waves from a vortex core in a teardrop-shaped nanopatch

We propose the design of a teardrop-shaped magnetic patch as a unidirectional magnetically driven spin wave emitter capable of operating in a wide range of frequencies. We explore its potential through micromagnetic studies in line with vibrational sample magnetometry measurements and ferromagnetic resonance experiments. The proposed system is based on the excitation of a vortex core, acting as a source of spin waves, and a single Bloch domain wall, as a channel for the confinement and propagation of the mode in a sufficiently thick magnetic patch in the single magnetic vortex (SMV) state. The novelty consists in the reconfigurability and simplicity of the system, that is operational without the need of external saturating fields, retaining a single Bloch domain wall and a movable single vortex core. This allows significant suppression of the wave emission by means of an external bias field, which in turn allows a controllable valvelike effect. Following our proposed strategy for cultivating a single vortex core in the shape, and after a thorough micromagnetic study of the most prominent magnetization dynamics in the patch, we show that the SMV state can be obtained in a thick enough (80 nm) teardrop-shaped patch. Micromagnetic results show the potential of this simple structure as a tunable and unidirectional spin wave emitter. Experimental results also suggest that the required magnetic configuration has been experimentally obtained in the structure, in good agreement with micromagnetic simulations.

Voltage-controllable magnetic skyrmion dynamics for spiking neuron device applications

Voltage-controlled magnetic skyrmions have attracted special attention because they satisfy the requirements for well-controlled high-efficiency and energy saving for future skyrmion-based neuron device applications. In this work, we propose a compact leaky-integrate-fire (LIF) spiking neuron device by using the voltage-driven skyrmion dynamics in a multiferroic nanodisk structure. The skyrmion dynamics is controlled by well tailoring voltage-induced piezostrains, where the skyrmion radius can be effectively modulated by applying the piezostrain pulses. Like the biological neuron, the proposed skyrmionic neuron will accumulate a membrane potential as skyrmion radius is varied by inputting the continuous piezostrain spikes, and the skyrmion radius will return to the initial state in the absence of piezostrain. Therefore, this skyrmion radius-based membrane potential will reach a definite threshold value by the strain stimuli and then reset by removing the stimuli. Such the LIF neuronal functionality and the behaviors of the proposed skyrmionic neuron device are elucidated through the micromagnetic simulation studies. Our results may benefit the utilization of skyrmionic neuron for constructing the future energy-efficient and voltage-tunable spiking neural networks.

Optimizing machine learning models for granular NdFeB magnets by very fast simulated annealing

The macroscopic properties of permanent magnets and the resultant performance required for real implementations are determined by the magnets’ microscopic features. However, earlier micromagnetic simulations and experimental studies required relatively a lot of work to gain any complete and comprehensive understanding of the relationships between magnets’ macroscopic properties and their microstructures. Here, by means of supervised learning, we predict reliable values of coercivity (μ0Hc) and maximum magnetic energy product (BHmax) of granular NdFeB magnets according to their microstructural attributes (e.g. inter-grain decoupling, average grain size, and misalignment of easy axes) based on numerical datasets obtained from micromagnetic simulations. We conducted several tests of a variety of supervised machine learning (ML) models including kernel ridge regression (KRR), support vector regression (SVR), and artificial neural network (ANN) regression. The hyper-parameters of these models were optimized by a very fast simulated annealing (VFSA) algorithm with an adaptive cooling schedule. In our datasets of randomly generated 1,000 polycrystalline NdFeB cuboids with different microstructural attributes, all of the models yielded similar results in predicting both μ0Hc and BHmax. Furthermore, some outliers, which deteriorated the normality of residuals in the prediction of BHmax, were detected and further analyzed. Based on all of our results, we can conclude that our ML approach combined with micromagnetic simulations provides a robust framework for optimal design of microstructures for high-performance NdFeB magnets.

3D Ferrimagnetic Device for Multi-Bit Storage and Efficient In-Memory Computing

In this letter, we propose a 3D spintronic device stacked by ferrimagnetic (FIM) alloy CoTb layers with a thickness gradient for realizing multi-bit storage and efficient in-memory computing (IMC). Firstly, spin-orbit torque (SOT) induced multi-level magnetization switching of a Pt/CoTb/W/CoTb/Pt stack is experimentally achieved and micromagnetically modeled. Furthermore, a 3D-FIM IMC device with multiple ferrimagnetic layers is constructed and analyzed. Its functionalities of ultra-dense storage and reconfigurable logic are both validated through micromagnetic studies. Due to the ultra-fast dynamics near the compensation point, this 3D-FIM IMC device can operate with ultra-low energy consumption (~18 aJ) and ultra-high speed (~25 ps).

Influence of angular orientation, shape, and arrangement of antidots on magnetic reversal in thin films with perpendicular magnetic anisotropy

We report a micromagnetic studies of the magnetic reversal and domain pattern formation in antidot arrays with perpendicular magnetic anisotropy. The effect of the lattice symmetry (triangular, square, quasicrystalline and random), antidot shapes (triangles, squares and crosses) as well as their angular orientation has been investigated. Simulations are performed by solving the Landau-Lifshitz-Gilbert equation and finding the system’s energy minimum for model with intrinsic and extrinsic defects, which allows to emulate the behaviour of real systems. The significant differences in coercivity values and domain sizes were noticed during rotation of the antidots around their centres. This parameter has a special impact on the magnetic behaviour of systems with square and cross-shaped antidots. The results are discussed in terms of the local shape anisotropy and equilibrium positions of domain walls.

Giant magnetoreactance in magnetic nanowires

We outline the idea of magnetic-field sensing with a nanometer spatial resolution using the effect of giant magnetoreactance (GMX) and we discuss results of our micromagnetic studies of domain-wall-assisted (or double-vortex-assisted) GMX in nanomagnets. By analogy to low-frequency giant magnetoimpedance (GMI), we consider systems of domains magnetized perpendicular to the direction of the AC current that creates an alternating Oersted field, thus, it drives the DW oscillations. Because of small cross-sections, the nanomagnets are not capable to induce large changes of the magnetic flux, therefore, the impedance of magnet-containing nanocircuits is dominated by the static resistivity (in accessible frequency regimes), while, GMX is an alternative effect to be utilized for sensing. We analyze in detail the effect in single-crystalline nanowire of cobalt with the easy axis transverse to the nanowire axis. In that system, small coherent shifts of the domain walls (DWs) induce relatively high changes of the magnetic flux through the largest cross-section of the nanowire due to large density of periodically packed DWs. Driven by the alternating transverse field of the Oersted origin, the system allows for perpendicular (the field directed perpendicular to the long axis of the nanowire and to the domain magnetization) GMX of improved characteristics (the GMX ratio and the field sensitivity of GMX) at a high stability of the magnetic structure in a wide region of the external field. Moreover, due to a non-zero overall magnetization (created by DWs), the perpendicular GMX is strongly asymmetric with respect to the field reversal (in a low-field regime). Also, we study the transverse GMX (the field parallel to the domain magnetization).

Antiferromagnetic domain wall control via surface spin flop in fully tunable synthetic antiferromagnets with perpendicular magnetic anisotropy

Antiferromagnetic (AF) domain walls have recently attracted revived attention, not only in the emerging field of AF spintronics, but also more specifically for offering fast domain wall velocities and dynamic excitations up to the terahertz frequency regime. Here we introduce an approach to nucleate and stabilize an AF domain wall in a synthetic antiferromagnet (SAF). We present experimental and micromagnetic studies of the magnetization reversal in [(Co/Pt)$_{X-1}$/Co/Ir]$_{N-1}$(Co/Pt)$_X$ SAFs, where interface induced perpendicular magnetic anisotropy (PMA) and AF interlayer exchange coupling (IEC) are completely controlled via the individual layer thicknesses within the multilayer stack. By combining strong PMA with even stronger AF IEC, the SAF reveals a collective response to an external magnetic field applied normal to the surface, and we stabilize the characteristic surface spin flop (SSF) state for an even number N of AF-coupled (Co/Pt)$_{X-1}$/Co multilayer blocks. In the SSF state our system provides a well-controlled and fully tunable vertical AF domain wall, easy to integrate as no single crystal substrates are required and with uniform 2D-magnetization in the film plane for further functionalization options, such as for example lateral patterning via lithography.

Micromagnetic studies of the domain structure of BaFe12O19 cubes in zero magnetic field

This article reports an investigation of the domain structure of cube-shaped BaFe12O19 models in zero magnetic field using the public-domain OOMMF micromagnetic simulator to model cubes with sides varying from 100 to 900 nm. A Bloch wall appears in BaFe12O19 cubes larger than about 510 nm and a single-domain structure appeared below 510 nm. The transition from single- to multiple- domain structure in the cube-shaped models occurred near the size predicted by analytical solutions of Kittel’s equation. Analysis of the magnetization energy showed that the exchange energy increased with increasing size once the Bloch wall was formed. We also calculated the width of the Bloch walls from the full width at half maximum of the transverse component of the magnetization vector. The domain wall width increased, as the modeled cubes grew larger.

Spin-orbit-torque-driven multilevel switching in Ta/CoFeB/MgO structures without initialization

Spin-orbit torque (SOT) has been proposed as an alternative writing mechanism for the next-generation magnetic random access memory (MRAM), due to its energy efficiency and high endurance in perpendicular magnetic anisotropic materials. However, the three-terminal structure of SOT-MRAM increases the cell size and consequently limits the feasibility of implementing high density memory. Multilevel storage is a key factor in the competitiveness of SOT-MRAM technology in the nonvolatile memory market. This paper presents an experimental characterization of a multilevel SOT-MRAM cell based on a perpendicularly magnetized Ta/CoFeB/MgO heterostructure and addresses the initialization-free issue of multilevel storage schemes. Magneto-optical Kerr effect microscopy and micromagnetic simulation studies confirm that the multilevel magnetization states are created by changing a longitudinal domain wall pinning site in the magnet. The realization of robust intermediate switching levels in the commonly used perpendicularly magnetized Ta/CoFeB/MgO heterostructure provides an efficient way to switch magnets for low-power, high-endurance, and high-density memory applications.

Micromagnetic Studies of Laser-Induced Magnetization Dynamics in FePt–C Films

Laser-induced magnetization switching has been studied extensively for its applications in heat-assisted magnetic recording (HAMR) and all-optical switching (AOS), since Beaurepaire etal. found that magnetizations can respond to the femtosecond time scale laser pulse [1]. With the help of heat and assistance of external field or helicity-dependent magneto-optical effect, magnetizations switch in an ultrafast regime of picoseconds [2]. Recently, micromagnetic simulations based on LLB equation have been used to study the magnetization dynamics and switching in FePt films [3], [4]. In this work, the hybrid Monte Carlo (HMC) micromagnetics developed by the authors [5], [6] will be utilized to analyze the laser-induced magnetization switching. In this work, we built a model of FePt-C granular film with Voronoi polycrystalline structure. Some magnetic and structural parameters are derived by experimental measurements [7]. The total simulated area is 32nm $\times 32$ nm $\times 8$ nm, divided into a regular mesh of 2.5nm $\times 2.5$ nm $\times 2$ nm micromagnetic cells and the number of crystalline grains is 48. At $\mathrm {T}=0\mathrm {K}$, in crystalline grains, the saturation $M_{s}(0)$ is 1300 emu/cc, the exchange constant $A_{1}^{\ast }$ is $6.8 \times 10 ^{-7}$ erg/cm and the anisotropy energy $K(0)$ is $4.5 \times 10 ^{7}$ erg/cm 3; at disorder grain boundary, $M'_{s}(0)$ is $0.1 M_{s}(0)$, $A_{2}^{\ast }$ is $0.2 A_{1}^{\ast }$ and $K'(0)$ is 0.1 K(0) [7]. In simulation of laser-induced magnetization dynamics, the temperature profile of the laser shooting process is vitally important. In LLB micromagnetics, two-temperature model (2TM) is commonly used to get the profile of the electron temperature, which is then introduced in LLB equation via the spin coupling parameter $\lambda $. But some parameters in 2TM model are quite arbitrary. In HMC micromagnetics, we use the time-resolved magneto-optical kerr effect (TR-MOKE) to get the spin temperature profile directly. The time resolved kerr rotation, which is proportional to magnetization, is measured with an external magnetic field 2 T applied in the direction of initial magnetization to ensure that all magnetizations are saturated in one direction. The measurement and simulation results are shown in Fig. 1 and Fig. 2. The measured kerr rotation signal is shown in Fig.1(a). In Fig. 1(a), in the process of $\sim 290$ fs laser shooting, the kerr rotation decreases rapidly and then recovers slowly, which results from the rapid demagnetization and slower recovery of magnetization. Additionally, with higher laser power, the kerr rotation decreases to a critical minimum point where the magnitude of magnetization gets closely to zero, so that we can get the scaling relationship between the kerr rotation signal and the magnetization. We assume a spin temperature profile in Fig.1(b), and the HMC micromagnetics is performed with $M_{s}(T)$ determined by the mean field Brillouin function based on the temperature profile $T(t)$ in Fig.1(b) [8]. The simulated averaged M(t) curves fit well with the measurements in Fig.1(a), which in turn convince the correct choice of the spin temperature profile in Fig.1(b). So that HMC micromagnetics can be further utilized to study the laser-induced magnetization dynamics with various external magnetic fields or circularly polarized light.

An analytic study on coercivity mechanism of exchange coupled Nd2Fe14B/α-Fe nanocomposite magnets

In this study, a coercivity mechanism has been suggested for exchange coupled soft/hard nanocomposite magnets to estimate the coercive field from maximum domain wall energy gradient at the soft/hard phase grain boundary. A derivable function γ(x) has been suggested near the soft/hard grain boundary to reflect detailed microstructures (e.g. grain sizes of hard and soft phases) and the coercivity has been expressed by the first derivative dγ(x)/dx. Using the model, for exchange coupled Nd2Fe14B/α-Fe nanocomposite multilayer systems, relation between the coercivity and α-Fe layer thickness has been estimated and analyzed by comparing with the results from prior experimental and micromagnetic studies.

A chemical, crystallographic and magnetic characterisation of individual iron-oxide grains in Hawaiian lavas

Our knowledge on the behaviour of the geomagnetic field through time critically depends on how information of the past state of the field is recorded by, and stored in iron-bearing minerals such as magnetite. For small, single domain grains these processes are described by classical Néel theory, but the magnetic behaviour of larger, pseudo-single domain or multidomain grains, still is enigmatic. Here we present a chemical, crystallographic and magnetic characterisation of three to six individual, large (~3–10 μm) iron-oxide grains from eleven different flows sampled on the Big Island of Hawai’i. These grains were all subjected to a Magnetic Force Microscopy study to characterise their magnetic domain structure; a Microprobe analyses to assess their chemical composition; and a Scanning Electron Microscopy study to identify phases and crystallographic orientations. This comprehensive dataset enables systematic analyses of their magnetic behaviour as function of chemistry and forms the basis for future micromagnetic modelling studies eventually contributing to the development of a fundamental theory of magnetic behaviour in large iron-oxide grains.

Skyrmion Racetrack Memory With Random Information Update/Deletion/Insertion

Racetrack memory (RM) has demonstrated great potential as nonvolatile mass storage in future advanced computer architectures. Domain wall (DW)-based RM first proposed in 2008 by IBM, however, suffers from challenges, such as storage density, scalability, and energy consumption. Recently, magnetic skyrmions, topologically protected particle-like spin textures, have expected to replace DWs as new information carriers in the RM design, owing to their superiorities to DWs in terms of topological stability, smaller size, as well as lower driving current density. Extensive investigations have been performed in skyrmion-based RM (Sky-RM) to date. Furthermore, skyrmions exhibits some unique properties that are inaccessible to DWs, thus enabling Sky-RM to explore some new functions that may be inaccessible to DW-RM. In this paper, a novel Sky-RM, capable of random information update/deletion/insertion, is proposed by exploiting the particle-like behaviors of skyrmions. Micromagnetic studies are performed to validate the function and performance of these novel data operations, which may bring performance benefits in data access operations and enable new applications.

Micromagnetic Studies at Finite Temperature on FePt–C Granular Films

A new micromagnetic method using the hybrid Monte Carlo (HMC) algorithm has been developed, and the magnetic properties at finite temperature can be simulated. In this paper, the HMC micromagnetics are applied on the polycrystalline FePt–C granular films for heat-assisted magnetic recording, where the significant parameters such as the temperature-dependent saturation magnetization $M_{s}$ (T) are measured by experiments. The Voronoi polycrystalline microstructure is built upon a regular mesh of micromagnetic cells. The magnetization (M–H) loops below the Curie temperature are calculated; they agree well with experiments at 300, 400, 500, and 600 K, respectively, which have confirmed the validity of the HMC micromagnetic method. Besides, the M–H loop at 700 K, which currently cannot be measured by experiments, can also be simulated using the HMC algorithm, which shows superparamagnetic properties.

Shape induced magnetic vortex state in hexagonal ordered cofe nanodot arrays using ultrathin alumina shadow mask

The magnetization reversal process of hexagonal ordered CoFe nanodot arrays was investigated as a function of nanodot thickness (td) varying from 10 to 30 nm with fixed diameter. For this purpose, ordered CoFe nanodots with a diameter of 80 ± 4 nm were grown by sputtering using ultra-thin alumina mask. The vortex annihilation and the dynamic spin configuration in the ordered CoFe nanodots were analyzed by means of magnetic hysteresis loops in complement with the micromagnetic simulation studies. A highly pinched hysteresis loop observed at 20 nm thickness suggests the occurrence of vortex state in these nanodots. With increase in dot thickness from 10 to 30 nm, the estimated coercivity values tend to increase from 80 to 175 Oe, indicating irreversible change in the nucleation/annihilation field of vortex state. The measured magnetic properties were then corroborated with the change in the shape of the nanodots from disk to hemisphere through micromagnetic simulation.

Micromagnetic Studies of Finite Temperature M–H Loops for FePt-C Media**Supported by the National Natural Science Foundation of China under Grant Nos 51171086 and 51371101.

We have recently developed a new micromagnetic method at finite temperature, where the Hybrid Monte Carlo method is employed to realize the Boltzmann distribution with respect to the magnetic free energy. Hence, the hysteresis loops and domain structures at arbitrary temperature below the Curie point Tc can be simulated. The Hamilton equations are used to find the magnetization distributions instead of the Landau–Lifshitz (LL) equations. In our previous work, we applied this method on a simple uniaxial anisotropy nano-particle and compared it with the micromagnetic method using LL equations. In this work, we use this new method to simulate an L10 FePt-C granular thin film at finite temperatures. The polycrystalline Voronoi microstructure is included in the model, and the effects of the misorientation of FePt grains are also simulated.