Chemical composition and coercivity of SmCo5 magnets

Campos, Marcos Flávio de; Landgraf, Fernando José Gomes; Saito, N.H.; Romero, S.A.; Neiva, A.C.; Missell, F.P.; Morais, E. de; Gama, S.; Obrucheva, E.V.; Jalnin, B.V.

doi:10.1063/1.368075

Cited by 46 publications

(26 citation statements)

References 12 publications

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“…Therefore, the V of SmCo 5 continuously expands with the increase in Sm content, which verifies the existence of the high-temperature homogeneity range for SmCo 5 . A similar tendency of change of lattice parameters with the variation of Sm content was observed in sintered SmCo 5 magnets [16,17]. and Figure 3c summarizes the deduced magnetic properties.…”

Section: Experimental Methodssupporting

confidence: 53%

Effect of Sm content on energy product of rapidly quenched and oriented SmCo5 ribbons

Zhang

Valloppilly

2014

Appl. Phys. A

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The Sm-content dependence of phase composition, anisotropy, and other magnetic properties of Sm 1+δ Co 5 (δ ≤ 0.12) ribbons melt spun at 10 m/s has been studied. The samples consist of hexagonal SmCo 5 grains whose c axes are preferentially aligned along the long direction of the ribbon. The lattice parameter a and the cell volume (V) increase with increasing Sm content δ, whereas c decreases. Sm addition appears to improve the degree of the preferred orientation of the c-axis and to increase the mean grain size, which weakens the effective intergranular exchange coupling. Therefore, the remanence ratio, coercivity, and squareness of the hysteresis loops are significantly enhanced. The remanence ratio of 0.91 and the maximum energy product of 21.2 MGOe, which is the highest value reported so far for Sm-Co ribbons, are achieved for δ = 0.06. High performance in combination with simple processing may facilitate high-temperature applications for anisotropic Sm 1+δ Co 5 ribbons.

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Section: Experimental Methodssupporting

confidence: 53%

Effect of Sm content on energy product of rapidly quenched and oriented SmCo5 ribbons

Zhang

Valloppilly

2014

Appl. Phys. A

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“…It has been suggested that the removal of lattice defects can be the responsible for the large increase of coercivity between sintering and heat treatment temperatures [2,3]. Even with a detailed verification of microstructure, before and after the post-sintering heat treatment in SmCo 5 [3,4,23] and NdFeB [4] magnets, no significant difference was found in microstructure, supporting the idea that the elimination of defects in atomic level can be the reason of the beneficial effect of heat treatment.…”

Section: Lattice Defects and Coercivitysupporting

confidence: 51%

“…Previous microstructural studies [3,4,23] indicated that a possible microstructural change-between sintering and heat-treatment temperatures-is the elimination of rare-earth atoms from a supersatured matrix. The calculation presented in this study will take into account the experimentally measured diffusion coefficients of Sm into SmCo 5 phase [24][25][26] and the Sm-Co phase diagram [27].…”

Section: Lattice Defects and Coercivitymentioning

confidence: 99%

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Kinetical analysis of the heat treatment procedure in SmCo5 and other rare-earth transition-metal sintered magnets

Campos

Rios

2004

Journal of Alloys and Compounds

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“…The inset also shows the temperature dependence of the coercive field, H C (T), which appears to have a dependence similar to the remanence. To conclude, we note that the observed 2.5 T coercive field is on the order of those found in some important rare-earth permanent magnets, such as Nd 2 Fe 14 B where  o H C ~ 2.6 T 20 , and SmCo 5 where  o H C ~ 4 T. 21 The large coercivity of nanostructured Mn x Ga films is also present in the electronic properties through the anomalous Hall effect (AHE). The Hall effect in magnetic materials contains two main contributions, ρ H (H) = R o H + R 1 M(H,T), where R o = -1/ne is the ordinary Hall effect (OHE) coefficient, n the carrier concentration, R 1 the AHE coefficient, and M(H,T) the field and temperature-dependent magnetization.…”

mentioning

confidence: 99%

Large coercivity in nanostructured rare-earth-free MnxGa films

Nummy

Bennett

Cardinal

et al. 2011

Applied Physics Letters

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The magnetic hysteresis of Mn x Ga films exhibit remarkably large coercive fields as high as  o H C = 2.5 T when fabricated with nanoscale particles of a suitable size and orientation. This coercivity is an order of magnitude larger than in wellordered epitaxial film counterparts and bulk materials. The enhanced coercivity is attributed to the combination of large magnetocrystalline anisotropy and ~ 50 nm size nanoparticles. The large coercivity is also replicated in the electrical properties through the anomalous Hall effect. The magnitude of the coercivity approaches that found in rare-earth magnets, making them attractive for rareearth-free magnet applications.Rare-earth-based magnets provide the backbone of many products, from computers and mobile phones to electric cars and wind-powered generators. 1 But because of the high cost and limited availability of rare-earth and precious elements, which are expensive to mine and process, there is a growing interest in developing new magnetic materials without these elements. [2][3][4] This critical need has fostered innovative research aimed at the discovery of novel compounds and nanoscale composites that are free of these elements. One of the key properties of super strong magnets is their large magnetocrystalline anisotropy. With this in mind, it is advantageous to search for rare-earth-free ferromagnets that have large anisotropies, such as MnAl and Mn x Ga. However, in order to take advantage of the large anisotropy and make them suitable for applications they must be synthesized with an appropriate composition and structure at the nanoscale level. We find that when the Heusler compound Mn x Ga is synthesized with the proper nanostructuring, a remarkably high coercive field is produced. These results suggest that Mn x Ga is a good candidate for producing materials with enhanced coercive fields aimed at replacing some rare-earth-based magnets in use today.

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Chemical composition and coercivity of SmCo5 magnets

Cited by 46 publications

References 12 publications

Effect of Sm content on energy product of rapidly quenched and oriented SmCo5 ribbons

Effect of Sm content on energy product of rapidly quenched and oriented SmCo5 ribbons

Kinetical analysis of the heat treatment procedure in SmCo5 and other rare-earth transition-metal sintered magnets

Large coercivity in nanostructured rare-earth-free MnxGa films

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