High performance MM–FeCo–B spark plasma sintered magnets with nonmagnetic grain-boundary phase

High performance MM–FeCo–B spark plasma sintered magnets with nonmagnetic grain-boundary phase

This work presents results on the effect of mischmetal (MM) content on the magnetic properties, phase formation, microstructure, and intergranular interactions in MM12+xFe78-xCo2B6 (x = 0, 4, 8) magnets. The MM-FeCo-B magnets have been prepared by Spark Plasma Sintering method from powders obtained...

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Veröffentlicht in:Intermetallics 2021-08, Vol.135, p.107232, Article 107232
Hauptverfasser: Grigoras, M., Lostun, M., Stoian, G., Lupu, N., Borza, F.
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Sprache:eng
Schlagworte:
Coercivity
Grain boundary segregation
Grains
Light rare earth elements
Magnetic properties
Magnetism
Magnets
Mischmetal
Neodymium
Plasma sintering
Rare earth magnets
Remanence
Sintering (powder metallurgy)
Spark plasma sintering
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container_title Intermetallics
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creator Grigoras, M.
Lostun, M.
Stoian, G.
Lupu, N.
Borza, F.
description This work presents results on the effect of mischmetal (MM) content on the magnetic properties, phase formation, microstructure, and intergranular interactions in MM12+xFe78-xCo2B6 (x = 0, 4, 8) magnets. The MM-FeCo-B magnets have been prepared by Spark Plasma Sintering method from powders obtained by grinding precursor nanocrystalline ribbons. A significant increase in coercivity of almost 50%, from 5.4 kOe to 10.2 kOe, has been obtained when the MM content increased from 12 at% to 20 at%, while the remanence decreased with about 30%, from 100.3 to 74.45 emu/g. X-ray diffractograms analysis indicates that for a MM content higher than 12%, in addition to the 2: 14: 1 main phase, secondary phases are formed, the amount of which increases when the MM content increases. Electron microscopy investigations have shown that the secondary phases accumulate at the boundaries of the main phase grains. In the case of the magnet with 20 at% MM content the main phase grains are completely isolated. As a result, the magnets show a weakening of the exchange interaction, explaining thus the increase in coercivity. The best magnetic properties, such as coercivity of about 8.7 kOe and maximum energy product of 11.19 MGOe, have been obtained for the magnet with 16% MM content, which is promising for practical applications in terms of filling the gap between ferrites and Nd-Fe-B magnets. [Display omitted] •Formation of non-magnetic phase along grain boundaries.•Magnetic isolation of the 2:14:1 grains leading to the high coercivity.•Grain size of magnets preserved by spark plasma sintering.•MM-FeCo-B magnets fill the gap between ferrite and NdFeB commercial magnet.
doi_str_mv 10.1016/j.intermet.2021.107232
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The MM-FeCo-B magnets have been prepared by Spark Plasma Sintering method from powders obtained by grinding precursor nanocrystalline ribbons. A significant increase in coercivity of almost 50%, from 5.4 kOe to 10.2 kOe, has been obtained when the MM content increased from 12 at% to 20 at%, while the remanence decreased with about 30%, from 100.3 to 74.45 emu/g. X-ray diffractograms analysis indicates that for a MM content higher than 12%, in addition to the 2: 14: 1 main phase, secondary phases are formed, the amount of which increases when the MM content increases. Electron microscopy investigations have shown that the secondary phases accumulate at the boundaries of the main phase grains. In the case of the magnet with 20 at% MM content the main phase grains are completely isolated. As a result, the magnets show a weakening of the exchange interaction, explaining thus the increase in coercivity. The best magnetic properties, such as coercivity of about 8.7 kOe and maximum energy product of 11.19 MGOe, have been obtained for the magnet with 16% MM content, which is promising for practical applications in terms of filling the gap between ferrites and Nd-Fe-B magnets. 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The MM-FeCo-B magnets have been prepared by Spark Plasma Sintering method from powders obtained by grinding precursor nanocrystalline ribbons. A significant increase in coercivity of almost 50%, from 5.4 kOe to 10.2 kOe, has been obtained when the MM content increased from 12 at% to 20 at%, while the remanence decreased with about 30%, from 100.3 to 74.45 emu/g. X-ray diffractograms analysis indicates that for a MM content higher than 12%, in addition to the 2: 14: 1 main phase, secondary phases are formed, the amount of which increases when the MM content increases. Electron microscopy investigations have shown that the secondary phases accumulate at the boundaries of the main phase grains. In the case of the magnet with 20 at% MM content the main phase grains are completely isolated. As a result, the magnets show a weakening of the exchange interaction, explaining thus the increase in coercivity. The best magnetic properties, such as coercivity of about 8.7 kOe and maximum energy product of 11.19 MGOe, have been obtained for the magnet with 16% MM content, which is promising for practical applications in terms of filling the gap between ferrites and Nd-Fe-B magnets. 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The best magnetic properties, such as coercivity of about 8.7 kOe and maximum energy product of 11.19 MGOe, have been obtained for the magnet with 16% MM content, which is promising for practical applications in terms of filling the gap between ferrites and Nd-Fe-B magnets. [Display omitted] •Formation of non-magnetic phase along grain boundaries.•Magnetic isolation of the 2:14:1 grains leading to the high coercivity.•Grain size of magnets preserved by spark plasma sintering.•MM-FeCo-B magnets fill the gap between ferrite and NdFeB commercial magnet.</abstract><cop>Barking</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.intermet.2021.107232</doi><orcidid>https://orcid.org/0000-0002-5908-5999</orcidid><orcidid>https://orcid.org/0000-0002-6953-6423</orcidid></addata></record>
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subjects Coercivity
Grain boundary segregation
Grains
Light rare earth elements
Magnetic properties
Magnetism
Magnets
Mischmetal
Neodymium
Plasma sintering
Rare earth magnets
Remanence
Sintering (powder metallurgy)
Spark plasma sintering
title High performance MM–FeCo–B spark plasma sintered magnets with nonmagnetic grain-boundary phase
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