Prospects for nanoparticle-based permanent magnets

Balamurugan, Balamurugan; Sellmyer, David J.; Hadjipanayis, G. C.; Skomski, Ralph

doi:10.1016/j.scriptamat.2012.03.034

Cited by 110 publications

(97 citation statements)

References 60 publications

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“…8 Another way to maximize the energy product is to induce a texture to enhance the remanence M r by aligning the particles' easy axes or by pressing the aligned powder to high density in order to approach M r to M s . 7,9 These will increase the ratio M r /M s , which is ≈ 0.5 for isotropically oriented, magnetically uniaxial and non-interacting single domain particles. 7 The challenge here is produce an optimized permanent magnets taking care of all the requirements discussed above.…”

Section: Introductionmentioning

confidence: 99%

Optimization of the magnetic properties of nanostructured Y-Co-Fe alloys for permanent magnets

2016

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The structural and magnetic properties of ball-milled Fe-doped Y Co5−xFex(0 ≤ x ≤ 0.5) were investigated. The magnetization increases with Fe-doping up to the solid solubility limit, x = 0.3 without destroying the crystal structure or degrading the coercivity. A special magnet array is designed using ring magnets for pressing the powders under magnetic field in order to achieve magnetic alignment. A dramatic increase in magnetization is observed for magnetically aligned Y Co4.8Fe0.2 pressed ingots.

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Section: Introductionmentioning

confidence: 99%

Optimization of the magnetic properties of nanostructured Y-Co-Fe alloys for permanent magnets

2016

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“…[1][2][3][4][5][6][7] As the structural length scale approaches the nanoregime, the magnetic properties are a complex function of size-modified electronic structure, defects, and surface effects, and this can lead to unusual magnetic ordering or transitions, modified ordering temperatures, and entirely different spin structures in nanoparticles and clusters as compared to the corresponding bulk alloys. 8,9 In the case of bulk and thin-film magnets constructed with nanoscale building blocks, the exchange interactions between the nanoclusters or grains also control the coercivity H c .…”

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“…19 In this regard, we have used successfully the cluster-deposition method to produce nanoclusters of high-anisotropy Co-rich intermetallic compounds without the requirement of a subsequent post-deposition annealing. The compounds include traditional R-Co alloys (R ¼ Y or Sm) such as RCo 5 with hexagonal CaCu 5 -type structure and R 2 Co 17 with rhombohederal Th 2 Zn 12 -type structures, 5,30-32 and also complex rare-earth-free HfCo 7 and Zr 2 Co 11 alloys having orthorhombic and rhombohedral structures, respectively, as shown in Fig. 3(a).…”

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confidence: 99%

“…Interestingly, FeSi 2 nanoclusters exhibit room-temperature ferromagnetic ordering and the preliminary results on FeGe nanocluster films have shown a possible Skyrmion-like behavior around 200 K in the dc susceptibility curves. The rare-earth free high-anisotropy Co-rich intermetallic clusters such as HfCo 7 and Zr 2 Co 11 show appreciable permanent-magnetic properties and also are used as building blocks to fabricate rare-earth-free exchange-coupled nanocomposite films with energy products as high as 20.3 MGOe (at 27 C) and 17.1 MGOe (at 180 C). The various types of magnetic nanoclusters and nanostructures discussed in this work provide useful insights for developing future magnetic materials with improved performance for many important applications.…”

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confidence: 99%

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Novel structures and physics of nanomagnets (invited)

Sellmyer

Balamurugan

Das

et al. 2015

Journal of Applied Physics

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Nanoscale magnets with characteristic dimensions in the range of 1–100 nm are important in several areas of nanoscience and technology. First, this length scale spans the typical important dimensions of exchange lengths and domain-wall widths, which means that significant control of magnetic properties can be obtained by varying grain or particle dimensions. Second, the nonequilibrium synthetic processes used for clusters, particles, and films, often lead to new real-space crystal structures with completely novel spin structures and magnetic properties. Third, a basic-science challenge in this class of matter involves the spin-polarized quantum mechanics of many-electron systems containing 10–10 000 atoms. Finally, the materials under study may have important future applications in high-density data storage, ultra-small spintronic devices, or high-energy magnetic materials. In this article, we discuss our recent work on novel Fe-Au nanoclusters, MnAu-Mn core-shell structures, and complex high-anisotropy Co-rich intermetallic compound clusters. We also present new results on Fe-based alloys including the magnetic properties of semiconducting FeSi2 nanoclusters and spin correlations in FeGe nanocluster films.

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“…Generally, a structure containing soft inclusions inside a hard matrix has been shown to produce the best results. Balamurugan and co-workers 6 proposed different ideal microstructures for exchange-coupled composite magnets. Similarly to modern high performance magnets, grains are separated by a non-magnetic or weakly ferromagnetic grain boundary phase, in order to avoid domain wall propagation once a reversed domain has been nucleated.…”

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High energy product in Battenberg structured magnets

Bance

Oezelt

Schrefl

et al. 2014

Applied Physics Letters

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Multiphase nano-structured permanent magnets show a high thermal stability of remanence and a high energy product while the amount of rare-earth elements is reduced. Non-zero temperature micromagnetic simulations show that a temperature coefficient of remanence of −0.073%/K and that an energy product greater than 400 kJ/m3 can be achieved at a temperature of 450 K in a magnet containing around 40 volume percent Fe65Co35 embedded in a hard magnetic matrix.

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Prospects for nanoparticle-based permanent magnets

Cited by 110 publications

References 60 publications

Optimization of the magnetic properties of nanostructured Y-Co-Fe alloys for permanent magnets

Optimization of the magnetic properties of nanostructured Y-Co-Fe alloys for permanent magnets

Novel structures and physics of nanomagnets (invited)

High energy product in Battenberg structured magnets

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