Magnetic interactions in anisotropic Nd-Dy-Fe-Co-B/α-Fe multilayer magnets

Dai, Zhiming; Liu, W.; Zhao, Xinguo; Han, Zhaoyang; Kim, D.; Choi, Chul-Jin; Zhang, Z. D.

doi:10.1063/1.4964804

Cited by 18 publications

(18 citation statements)

References 33 publications

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“…Figure 8 b shows the distribution curves of the reversible and irreversible parts separated from the FORCs data. The separation of the reversible and irreversible processes has been performed near the descending branch of the major loop by monitoring the magnetization change versus

in the original FORC [ 39 ]. In mathematical form, the reversible/irreversible parts are represented by the following formulas:

…”

Section: Resultsmentioning

confidence: 99%

Coercivity Mechanism and Magnetization Reversal in Anisotropic Ce-(Y)-Pr-Fe-B Films

Zhao

Liu

et al. 2021

Materials

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In this study, the magnetic properties, coercivity mechanism, and magnetization reversal process were investigated for Ce-(Y)-Pr-Fe-B films. After the addition of Y and subsequent heating treatment, the formations of REO (RE ≡ Ce and Pr) and REFe2 (RE ≡ rare earths) phases are inhibited, and the microstructure of Ce-Y-Pr-Fe-B film is optimized. Meanwhile, the coercivity and the squareness of the hysteresis loop are significantly improved. The coercivity mechanism of Ce-Y-Pr-Fe-B film is determined to be a mixture of nucleation and pinning mechanisms, but dominated by the nucleation mechanism. The demagnetization results show that the nucleation of reversal magnetic domains leads to irreversible reversal. Our results are helpful to understand the coercivity mechanism and magnetization reversal of permanent magnetic films with multi-main phases.

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in the original FORC [ 39 ]. In mathematical form, the reversible/irreversible parts are represented by the following formulas:

…”

Section: Resultsmentioning

confidence: 99%

Coercivity Mechanism and Magnetization Reversal in Anisotropic Ce-(Y)-Pr-Fe-B Films

Zhao

Liu

et al. 2021

Materials

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“…[3,30] Thus, it is very important to make clear the mechanism of the long-range interactions between the hard-and soft-magnetic layers. Dai et al [31] analyzed the interactions mechanism by using the first-order-reversal-curves (FORCs) distributions and discussed the dependence of the mean interaction on the distance between soft-and hard-magnetic layers.…”

Section: -4mentioning

confidence: 99%

“…[16,22] Applied field/kOe Applied field/kOe 10 nm) (t MgO = 0 nm, 2 nm, 60 nm, 70 nm, and 100 nm). [31] The OOP demagnetization curves of multilayers with Ta and Cr 2 O 3 spacer layers are presented in Figs. 13(a) and 13(b), respectively.…”

Section: -4mentioning

confidence: 99%

Anisotropic nanocomposite soft/hard multilayer magnets

Liu¹,

Zhang²

2017

Chinese Phys. B

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Experimental and theoretical researches on nanostructured exchange coupled magnets have been carried out since about 1988. Here, we review the structure and magnetic properties of the anisotropic nanocomposite soft/hard multilayer magnets including some new results and phenomena from an experimental point of view. According to the different component of the oriented hard phase in the nanocomposite soft/hard multilayer magnets, three types of magnets will be discussed: 1) anisotropic Nd 2 Fe 14 B based nanocomposite multilayer magnets, 2) anisotropic SmCo 5 based nanocomposite multilayer magnets, and 3) anisotropic rare-earth free based nanocomposite multilayer magnets. For each of them, the formation of the oriented hard phase, exchange coupling, coercivity mechanism, and magnetic properties of the corresponding anisotropic nanocomposite multilayer magnets are briefly reviewed, and then the prospect of realization of bulk magnets on new results of anisotropic nanocomposite multilayer magnets will be carried out.

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“…The compositional design can also be performed by blending precursor powders with the different grain sizes and chemical compositions of Dy alloy powders, resulting in homogeneous HRE distribution [ 15 ]. Another available method to design the microstructures in permanent magnets is achieved by growing the materials layer by layer using the vacuum sputtering system [ 16 ]. All these processes experience a complex thermodynamic evolution.…”

Section: Introductionmentioning

confidence: 99%

Magnetic-Property Assessment on Dy–Nd–Fe–B Permanent Magnet by Thermodynamic Calculation and Micromagnetic Simulation

Dai

Wang

et al. 2022

Materials

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Heavy rare-earth (HRE) elements are important for the preparation of high-coercivity permanent magnets. A further understanding of the thermodynamic properties of HRE phases, and the magnetization reversal mechanism of magnets are still critical issues to obtain magnets that can achieve better performance. In this work, the Nd–Dy–Fe–B multicomponent system is investigated via the calculation of the phase diagram (CALPHAD) method and micromagnetic simulation. The phase composition of magnets with various ratios of Nd and Dy is assessed using critically optimized thermodynamic data. γ-Fe and Nd2Fe17 phases are suppressed when partial Nd is substituted with Dy (<9.3%), which, in turn, renders the formation of Nd2Fe14B phase favorable. The influence of the magnetic properties of grain boundaries (GBs) on magnetization reversal is detected by the micromagnetic simulations with the 3D polyhedral grains model. Coercivity was enhanced with both 3 nm nonmagnetic and the hard-magnetic GBs for the pinning effect besides the GBs. Moreover, the nucleation and propagation of reversed domains in core-shell grains are investigated, which suggests that the magnetic structure of grains can also influence the magnetization reversal of magnets. This study provides a theoretical route for a high-efficiency application of the Dy element, realizing a deterministic enhancement of the coercivity in Nd–Fe–B-based magnets.

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Magnetic interactions in anisotropic Nd-Dy-Fe-Co-B/α-Fe multilayer magnets

Cited by 18 publications

References 33 publications

Coercivity Mechanism and Magnetization Reversal in Anisotropic Ce-(Y)-Pr-Fe-B Films

Coercivity Mechanism and Magnetization Reversal in Anisotropic Ce-(Y)-Pr-Fe-B Films

Anisotropic nanocomposite soft/hard multilayer magnets

Magnetic-Property Assessment on Dy–Nd–Fe–B Permanent Magnet by Thermodynamic Calculation and Micromagnetic Simulation

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