Optimization of Nitriding Regimes for Sm.sub.2Fe.sub.17 Alloy Powder

Optimization of Nitriding Regimes for Sm.sub.2Fe.sub.17 Alloy Powder

Currently, the most actively developing area in the field of permanent magnets is development of those based on compounds of rare-earth metals with transition metals. This is due to their unique magnetic properties that surpass those for ferrite and lithium magnets by several factors and makes them...

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Bibliographic Details
Published in:Metallurgist (New York) Vol. 60; no. 11-12; p. 1262
Main Authors: Kutepov, A. V, Tarasov, V. P, Ignatov, A. S
Format: Journal Article
Language:English
Published: Springer 01-03-2017
Subjects:
Alloys
Iron compounds
Magnetic properties
Magnetization
Permanent magnets
Powders (Particulate matter)
Rare earth metals
Robots
Specialty metals industry
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Summary:Currently, the most actively developing area in the field of permanent magnets is development of those based on compounds of rare-earth metals with transition metals. This is due to their unique magnetic properties that surpass those for ferrite and lithium magnets by several factors and makes them irreplaceable with utilization in aero and automobile building, robot technology, computers, etc. Among all of the compounds of iron with rare-earth elements, the greatest iron content and, consequently, highest saturation magnetization applies to R.sub.2Fe.sub.17 compounds (R is rare-earth element). Regimes are studied for nitriding alloy powders (Sm.sub.0.9Zr.sub.0.1)Fe.sub.17 and Sm.sub.2(Fe.sub.0.9Co.sub.0.1).sub.17 in a nitrogen atmosphere with excess pressure of 15 kPa and temperature of 440-450°C. Dependences are established for phase composition and main magnetic parameters of nitriding regime.
ISSN:0026-0894
DOI:10.1007/s11015-017-0438-4