Enhanced magnetic properties and improved corrosion performance of nanocrystalline Pr-Nd-Y-Fe-B spark plasma sintered magnets

doi:10.1016/j.jmst.2020.03.061

Abstract

Abstract:

Recently it is a hot topic to make full use of high abundant Y element in Nd₂Fe₁₄B-type permanent magnets. In contrast to Pr and Nd elements, Y shows different metallurgical behaviors during preparation process. In this paper, we have explored the magnetic properties, microstructures and corrosion performance of Pr-Nd-Y-Fe-B magnets fabricated by spark plasma sintering (SPS) technique from the ribbons of nanocrystalline and amorphous precursors, respectively. The coercivity and maximum energy product were improved for the magnets prepared from amorphous precursor materials (denoted as SPS-A hereafter) compared with the magnets prepared from crystalline precursor materials (denoted as SPS-C hereafter). Magnetic properties of J_r = 0.79 T, H_ci = 864 kA/m, and (BH)_max = 102 kJ/m³ were obtained for SPS-A magnets. In contrast with SPS-C magnets, the magnetic properties of SPS-A magnets are not so sensitive to the preparation conditions, which is quite beneficial to the homogeneity of microstructure and enhancement of coercivity for large-scale production of the designated magnets. Aggregated (Pr,Nd,Y)-rich phase was found out in SPS-C magnets. Pr and Nd elements are rich at grain boundary while Y is distributed uniformly at main phase and grain boundary phase. The strip grains and equiaxed grains exist in SPS-C and SPS-A magnets, respectively. The enhanced magnetic properties for SPS-A magnets are accredited to the uniform distribution of rare-earth-rich phase and low demagnetization factor. It is revealed by electrochemical test and dipping test that the corrosion potential is more positive and the corrosion rate is slower for the SPS-A magnets in 3.5 wt.% NaCl solution. The work is also expected to shed light on developing the nanocrystalline Pr-Nd-Y-Fe-B SPSed high-performance magnets in industry.

Key words: Pr-Nd-Y-Fe-B magnets, Spark plasma sintering (SPS), Magnetic properties, Corrosion performance, Microstructure and homogeneity

Qingzheng Jiang, Jie Song, Qingfang Huang, Sajjad Ur Rehman, Lunke He, Qingwen Zeng, Zhenchen Zhong. Enhanced magnetic properties and improved corrosion performance of nanocrystalline Pr-Nd-Y-Fe-B spark plasma sintered magnets[J]. J. Mater. Sci. Technol., 2020, 58: 138-144.

Figures/Tables 10

Fig. 1. XRD patterns for [(Pr0.25Nd0.75)0.7Y0.3]13.9Fe80.1B6 ribbons prepared at the wheel speed of 25 m/s and 40 m/s.

Fig. 2. M-H curves of [(Pr0.25Nd0.75)0.7Y0.3]13.9Fe80.1B6 ribbons prepared at the wheel speed of 25 m/s and 40 m/s.

Fig. 3. Demagnetization curves of (a) SPS-C and (b) SPS-A prepared at varying sintering temperature with a pressure of 50 MPa for 5 min.

Table 1 Densities and magnetic properties of SPS-C and SPS-A prepared at different sintering processes.

Magnets	Sintering processes	ρ (g/cm³)	H_ci (kA/m)	J_r (T)	(BH)_max (kJ/m³)
SPS-C	650 °C/50 MPa/5 min	7.08	764	0.77	93
	700 °C/30 MPa/5 min	7.34	798	0.72	86
	700 °C/50 MPa/5 min	7.41	818	0.79	97
	700 °C/50 MPa/10 min	7.41	785	0.65	68
	750 °C/50 MPa/5 min	7.41	694	0.45	34
SPS-A	650 °C/50 MPa/5 min	7.05	838	0.78	97
	700 °C/50 MPa/5 min	7.41	864	0.79	102
	750 °C/50 MPa/5 min	7.41	786	0.76	81

Fig. 4. (a, b, d) BSE SEM micrographs of SPS-C prepared at 700 °C with a pressure of 50 MPa for 5 min; (c, e) elemental mapping of the rectangular area marked in (b) and (d), respectively.

Fig. 5. (a, b) BSE SEM micrographs of SPS-A prepared at 700 °C with a pressure of 50 MPa for 5 min, (c) elemental mapping of the rectangular area marked in (b).

Fig. 6. (a-c) TEM micrographs of SPS-C prepared at 700 °C with a pressure of 50 MPa for 5 min, (d) EDS result along the white line marked in (c); (e, f) TEM micrographs of SPS-A prepared at 700 °C with a pressure of 50 MPa for 5 min.

Fig. 7. (a) Polarization curves, (b) EIS plots of SPS-C and SPS-A in 3.5 wt.% NaCl solution.

Table 2 Corrosion potential (Ecorr) and corrosion current density (Icorr) of SPS-C and SPS-A in 3.5 wt% NaCl solution.

Magnets	E_corr (V)	I_corr (μA/cm²)
SPS-C	-0.762	20.2
SPS-A	-0.752	8.7

Fig. 8. The surface morphologies of (a, b) SPS-C; (c, d) SPS-A after exposing in 3.5 wt% NaCl solution for 6 h.

References 45

[1]	S. Sugimoto, J. Phys. D Appl. Phys. 44 (2011), 064001.
[2]	Q.Z. Jiang, Z.C. Zhong, J. Mater. Sci. Technol. 33 (2017) 1087-1096.
[3]	J.S. Zhang, W. Li, X.F. Liao, H.Y. Yu, L.Z. Zhao, H.X. Zeng, D.R. Peng, Z.W. Liu, J. Mater. Sci. Technol. 35 (2019) 1877-1885.
[4]	T.Y. Ma, M. Yan, K.Y. Wu, B. Wu, X.L. Liu, X.J. Wang, Z.Y. Qian, C. Wu, W.X. Xia, Acta Mater. 142 (2018) 18-28.
[5]	W. Li, A.H. Li, H.B. Feng, S.L. Huang, J.D. Wang, M.G. Zhu, IEEE Trans. Magn. 51 (2015), 2103603.
[6]	Z.B. Li, B.G. Shen, M. Zhang, F.X. Hu, J.R. Sun, J. Alloys. Compd. 628 (2015) 325-328. DOI URL
[7]	L.Z. Zhao, C.L. Li, Z.P. Hao, X.L. Liu, X.F. Liao, J.S. Zhang, K.P. Su, L.W. Li, H.Y. Yu, J.M. Greneche, J.Y. Jin, Z.W. Liu, Mater. Charact. 148 (2019) 208-213.
[8]	J.Y. Jin, M. Yan, Y.S. Liu, B.X. Peng, G.H. Bai, Acta Mater. 169 (2019) 248-259.
[9]	L.K. He, Q.Z. Jiang, S.U. Rehman, J. Song, H. Ouyang, Z.C. Zhong, Mater. Res. Express 6 (2019), 096111.
[10]	J.Y. Jin, G.H. Bai, Z.H. Zhang, M. Yan, J. Alloys. Compd. 763 (2018) 854-860.
[11]	Q.Z. Jiang, W.K. Lei, L.K. He, Q.W. Zeng, S.U. Rehman, L.L. Zhang, R.H. Liu, S.C. Ma, Z.C. Zhong, J. Alloys. Compd. 775 (2019) 449-456.
[12]	M.G. Zhu, R. Han, W. Li, S.L. Huang, D.W. Zheng, L.W. Song, X.N. Shi, IEEE Trans. Magn. 51 (2015), 2104604.
[13]	Q.Z. Jiang, M.L. Zhong, W.K. Lei, Q.W. Zeng, Y.F. Hu, Q.C. Quan, Y.P. Xu, X.J. Hu, L.L. Zhang, R.H. Liu, S.C. Ma, Z.C. Zhong, AIP Adv. 7 (2017), 085013. DOI URL
[14]	X.D. Fan, S. Guo, K. Chen, R.J. Chen, D. Lee, C.Y. You, A.R. Yan, J. Magn. Magn. Mater. 419 (2016) 394-399.
[15]	Q.Z. Jiang, L.K. He, S.U. Rehman, Y.F. Hu, J. Song, H. Ouyang, M.N. Yang, Z.C. Zhong, J. Alloys. Compd. 811 (2019), 151998.
[16]	X.D. Fan, G.F. Ding, K. Chen, S. Guo, C.Y. You, R.J. Chen, D. Lee, A.R. Yan, Acta Mater. 154 (2018) 343-354.
[17]	Z. Li, W.Q. Liu, S.S. Zha, Y.Q. Li, Y.Q. Wang, D.T. Zhang, M. Yue, J.X. Zhang, X.L. Huang, J. Magn. Magn. Mater. 393 (2015) 551-554.
[18]	X.B. Liu, Z. Altounian, M.D. Huang, Q.M. Zhang, J.P. Liu, J. Alloys. Compd. 549 (2013) 366-369.
[19]	X.D. Fan, K. Chen, S. Guo, R.J. Chen, D. Lee, A.R. Yan, C.Y. You, Appl. Phys. Lett. 110 (2017), 172405.
[20]	J.F. Herbst, Rev. Mod. Phys. 63 (1991) 819-898.
[21]	B.X. Peng, T.Y. Ma, Y.J. Zhang, J.Y. Jin, M. Yan, Scr. Mater. 131 (2017) 11-14.
[22]	Z.W. Liu, D.Y. Qian, D.C. Zeng, IEEE Trans. Magn. 48 (2012) 2797-2799.
[23]	S. Tao, Z. Ahmad, P.Y. Zhang, M. Yan, X.M. Zheng, J. Magn. Magn. Mater. 437 (2017) 62-66.
[24]	Z.W. Liu, D.Y. Qian, L.Z. Zhao, Z.G. Zheng, X.X. Gao, R.V. Ramanujan, J. Alloys. Compd. 606 (2014) 44-49.
[25]	X.H. Tan, H. Xu, Q. Bai, W.J. Zhao, Y.D. Dong, J. Alloys. Compd. 452 (2008) 373-376.
[26]	X. Zhang, Y.T. Ma, B. Zhang, Y. Li, M.K. Lei, F.H. Wang, M.G. Zhu, X.H. Wang, Corros. Sci. 87 (2014) 156-166.
[27]	E. Isotahdon, E.H. Saarivirta, V.T. Kuokkala, J. Alloys. Compd. 692 (2017) 190-197.
[28]	Y.H. Hou, Y.L. Wang, Y.L. Huang, Y. Wang, S. Li, S.C. Ma, Z.W. Liu, D.C. Zeng, L.Z. Zhao, Z.C. Zhong, Acta Mater. 115 (2016) 385-391.
[29]	Y.L. Huang, Y. Wang, Y.H. Hou, Y.L. Wang, Y. Wu, S.C. Ma, Z.W. Liu, D.C. Zeng, Y. Tian, W.X. Xia, Z.C. Zhong, J. Magn. Magn. Mater. 399 (2016) 175-178.
[30]	Q.Z. Jiang, W.K. Lei, Q.W. Zeng, Q.C. Quan, L.L. Zhang, R.H. Liu, X.J. Hu, L.K. He, Z.Q. Qi, Z.H. Ju, M.L. Zhong, S.C. Ma, Z.C. Zhong, AIP Adv. 8 (2018), 056203.
[31]	X. Tang, H. Sepehri-Amin, T. Ohkubo, K. Hioki, A. Hattori, K. Hono, Acta Mater. 123 (2017) 1-10.
[32]	Q.Z. Jiang, L.K. He, S.U. Rehman, W.K. Lei, Q.W. Zeng, X.J. Hu, L.L. Zhang, R.H. Liu, S.C. Ma, Z.C. Zhong, IEEE Trans. Magn. 55 (2019), 2101806.
[33]	M. Yan, X.G. Cui, L.Q. Yu, T.Y. Ma, J. Mater. Sci. Technol. 25 (2009) 629-632.
[34]	J. Liu, H. Sepehri-Amin, T. Ohkubo, K. Hioki, A. Hattori, T. Schrefl, K. Hono, Acta Mater. 82 (2015) 336-343.
[35]	H. Kronmüller, Phys. Status Solidi B 130 (1985) 197-203.
[36]	J. Bauer, M. Seeger, A. Zern, H. Kronmüller, J. Appl. Phys. 80 (1996) 1667-1673.
[37]	D. Goll, M. Seeger, H. Kronmüller, J. Magn. Magn. Mater. 185 (1998) 49-60.
[38]	D. Nagahama, T. Ohkubo, T. Miyoshi, S. Hirosawa, K. Hono, Acta Mater. 54 (2006) 4871-4879. DOI URL
[39]	J. Liu, H. Sepehri-Amin, T. Ohkubo, K. Hioki, A. Hattori, K. Hono, J. Appl. Phys. 115 (2014), 17A744.
[40]	Y.Q. Wu, T. Bitoh, K. Hono, A. Makino, A. Inoue, Acta Mater. 49 (2001) 4069-4077.
[41]	A.A. El-Moneim, O. Gutfleisch, A. Plotnikov, A. Gebert, J. Magn. Magn. Mater. 248 (2002) 121-133.
[42]	R. Sueptitz, K. Tschulik, M. Uhlemann, M. Katter, L. Schultz, A. Gebert, Corros. Sci. 53 (2011) 2843-2852.
[43]	P. Zhang, L.P. Liang, J.Y. Jin, Y.J. Zhang, X.L. Liu, M. Yan, J. Alloys. Compd. 616 (2014) 345-349.
[44]	E. Isotahdon, E. Huttunen-Saarivirta, V.T. Kuokkala, M. Paju, Mater. Chem. Phys. 135 (2012) 762-771.
[45]	C. Sun, W.Q. Liu, H. Sun, M. Yue, X.F. Yi, J.W. Chen, J. Mater. Sci. Technol. 28 (2012) 927-930.