Hard magnetic property improvement of melt-spun PrCo₅ ribbons by Fe and C Doping

Magnetic properties and microstructure of melt-spun PrCo_5-x-yFe_xC_y (x = 0 and 0.3; y = 0-0.3) ribbons are studied. For PrCo₅ ribbons spun at lower wheel speed of 20 m/s, the coexistence of 2:17 phase with magnetic hard 1:5 phase leads to low coercivity of 0.6 kOe. Increasing wheel speed to 40 m/s imroves the coercivity to 3.3 kOe due to the increased volume fraction of 1:5 phase. Interestingly, magnetic properties of PrCo₅ ribbons melt spun at 40 m/s (B_r = 6.4 kG, _iH_c = 3.3 kOe, and (BH)_max = 4.5 MGOe) are improved to B_r = 6.1-6.5 kG, _iH_c = 7.8-13.5 kOe, (BH)_max = 7.3-8.9 MGOe by doping C, and significantly enhanced to B_r = 6.3 kG, _iH_c = 16.1 kOe, and (BH)_max = 9.3 MGOe for C and Fe co-doped PrCo_4.6Fe_0.3C_0.1 ribbons. The structural and thermo-magnetic analysis confirms that the entrance of Fe and part of C into the crystal structure of 1:5 phase leads to the increase of Curie temperature. Doping proper C content not only uniformly refines grain size and, therefore, improves the squareness of demagnetization curve and (BH)_max, but also increases the volume fraction of 1:5 phase, and thus enhances the coercivity. The increased volume fraction of 1:5 phase and the reduced magnetic domain size due to refined microstructure by co-doping Fe and C make PrCo_4.6Fe_0.3C_0.1 ribbons exhibit a high permanent magnetic performance. They are promising candidate materials for making bonded magnets.