Microstructures, Magnetic Properties And Coercivity Mechanisms Of Nd-Ce-Fe-B Based Alloys By Zr Substitution

In this paper, the effects of Zr addition on microstructures, magnetic properties, exchange coupling, and coercivity mechanisms of Nd-Ce-Fe-B alloys fabricated by melt-spinning technique are investigated. It is found that the coercivity H-cj is enhanced significantly by Zr substitution in the (Nd0.8Ce0.2)(13)Fe82-xZrxB5 alloys, while the remanence J(r) is reduced slightly. The H-cj increases from 12.2 to 13.7 kOe by adding Zr up to 1.5 at. %, whereas H-cj is decreased with a further increase in Zr content. The larger lattice constants and unit cell volumes of the matrix phase indicate that Zr atoms enter into the hard magnetic phase by substituting Fe sites. The reduction of T-c implies the attenuation of the exchange interaction in the 2:14:1 phase with Zr occupying the Fe sites. The weakened intergranular exchange coupling of the Zr added alloy may be attributed to the formation of a non-magnetic intergranular phase. It is worth noting that the coercivity is dominated by the pinning of domain walls at defect positions even though the nucleation of reversal domains still exists. The synergistic function between the pinning effect and the exchange coupling leads to improved magnetic properties. Published by AIP Publishing.