Properties of Mechanically Milled Nanocrystalline and Amorphous Mg-Y-Ni Electrode Alloys for Ni-MH Batteries

doi:10.1007/s40195-015-0266-0

Abstract

Abstract:

Nanocrystalline and amorphous Mg₂Ni-type Mg_20-_x Y _x Ni₁₀ (x = 0, 1, 2, 3 and 4) electrode alloys were fabricated using mechanical milling. The effects of the Y content and milling time on the microstructures and electrochemical performances of the alloys were investigated in detail. X-ray diffraction and transmission electron microscopy analyses revealed that the substitution of Y for Mg yields an obvious change in the phase composition and micro morphology of the alloys. When the Y content x ≤ 1, the substitution of Y for Mg does not change the major phase Mg₂Ni, but with a further increase in the Y content, the major phase of the alloys transforms into the YMgNi₄ + YMg₃ phase. A nanocrystalline and amorphous structure can be obtained by mechanical milling, and the amorphisation degree of the alloy visibly increases with increased milling time. Electrochemical measurements indicate that the discharge capacity of the alloys first increases and then decreases with increasing Y content and milling time. The substitution of Y for Mg dramatically ameliorates the cycle stability of the as-milled alloys, and the mechanical milling more or less impairs the cycle stability of the alloys. Furthermore, the high rate discharge ability, electrochemical impedance spectrum, Tafel polarisation curves and potential step measurements indicate that the electrochemical kinetic properties of the as-milled alloys first increase and then decrease with increasing Y content and milling time.

Key words: Mg2Ni-type, alloy, Y, substitution, for, Mg, Milling, time, Electrochemical, performance

Yang-Huan Zhang, Ze-Ming Yuan, Tai Yang, Zhong-Hui Hou, Dong-Liang Zhao. Properties of Mechanically Milled Nanocrystalline and Amorphous Mg-Y-Ni Electrode Alloys for Ni-MH Batteries[J]. Acta Metallurgica Sinica (English Letters), 2015, 28(7): 826-836.

Figures/Tables 11

Fig. 1 XRD profiles of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 2 HRTEM micrographs and ED patterns of the as-milled Mg20-x Y x Ni10 (x = 0-4) alloys: a Y0 alloy, milled for 10 h; b Y1 alloy, milled for 10 h; c Y3 alloy, milled for 10 h; d Y2 alloy, milled for 10 h; e Y2 alloy, milled for 30 h; f Y2 alloy, milled for 70 h

Fig. 3 Discharge potential curves of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 4 Evolutions of the discharge capacity of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 5 Evolution of S n values of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 6 Evolutions of the S 20 values of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 7 Evolution of the HRDs of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 8 Semilogarithmic curves of anodic current versus time responses of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 9 Tafel polarisation curves of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 10 EIS of the Mg20-x Y x Ni10 (x = 0-4) alloys milled for 10 h a and as-cast and as-milled Y2 alloy b

Fig. 11 SEM images and typical XRD pattern of the as-milled (30 h) Y2 alloy before and after electrochemical cycling: a before cycling; b after cycling; c XRD pattern of the sample after cycling

References 39

[1]	T. Nejat, S. Şahin,Energy Convers. Manag. 49, 1820(2008)
[2]	H. Wang, A.K. Prasad, S.G. Advani, Int. J. Hydrog. Energy 37, 290 (2012)
[3]	H.G. Huang, R. Li, T.W. Liu, L. Chen, D.L. Luo, Acta Metall. Sin. (Engl. Lett.) 23, 446(2010)
[4]	L.Z. Ouyang, Z.J. Cao, H. Wang, J.W. Liu, D.L. Sun, Q.A. Zhang, M. Zhu, J. Alloys Compd. 586, 113(2014)
[5]	A. Ebrahimi-Purkani, S.F. Kashani-Bozorg, J. Alloys Compd. 456, 211(2008)
[6]	L. Schlapbach, A. Züttel, Nature 414, 353 (2001)
[7]	L.Z. Ouyang, Z.J. Cao, H. Wang, J.W. Liu, D.L. Sun, Q.A. Zhang, M. Zhu, Int. J. Hydrog. Energy 38, 8881 (2013)
[8]	M.Y. Song, Y.J. Kwak, H.S. Shin, S.H. Lee, B.G. Kim, Int. J. Hydrog. Energy 38, 1910 (2013)
[9]	M. Anik, I. Akay, S. Topcu, Int. J. Hydrog. Energy 34, 5449 (2009)
[10]	L.Z. Ouyang, Z.J. Cao, L.L. Li, H. Wang, J.W. Liu, D. Min, Y.W. Chen, F.M. Xiao, R.H. Tang, M. Zhu, Int. J. Hydrog. Energy 39, 12765 (2014)
[11]	Y.H. Jia, S.M. Han, W. Zhang, X. Zhao, P.F. Sun, Y.Q. Liu, H. Shi, J.S. Wang, Int. J. Hydrog. Energy 38, 2352 (2013)
[12]	R. Ohara, C.H. Lan, C.S. Hwang, J. Alloys Compd. 580, S368(2013)
[13]	Y. Wang, S.Z. Qiao, X. Wang, Int. J. Hydrog. Energy 33, 1023 (2008)
[14]	L. Hima Kumar, B. Viswanathan, S. Srinivasa Murthy, J. Alloys Compd. 461, 72(2008)
[15]	A. Teresiak, A. Gebert, M. Savyak, M. Uhlemann, C. Mickel, N. Mattern, J. Alloys Compd. 398, 156(2005)
[16]	S. Ruggeri, L. Roué, J. Huot, R. Schulz, L. Aymard, J.M. Tarascon, J. Power Sources 112, 547 (2002)
[17]	Y.H. Zhang, C. Zhao, T. Yang, H.W. Shang, C. Xu, D.L. Zhao, J. Alloys Compd. 555, 131(2013)
[18]	Y.H. Zhang, C. Li, Y. Cai, F. Hu, Z.C. Liu, S.H. Guo, J. Alloys Compd. 584, 81(2014)
[19]	M. Mezbahul-Islam, M. Medraj, Calphad 33, 478 (2009)
[20]	H. Niua, D.O. Northwood, Int. J. Hydrog. Energy 27, 69 (2002)
[21]	X.Y. Zhao, Y. Ding, L.Q. Ma, L.Y. Wang, M. Yang, X.D. Shen, Int. J. Hydrog. Energy 33, 6727 (2008)
[22]	G. Zheng, B.N. Popov, R.E. White, J. Electrochem. Soc. 142, 2695(1995)
[23]	N. Kuriyama, T. Sakai, H. Miyamura, I. Uehara, H. Ishikawa, T. Iwasaki, J. Alloys Compd. 202, 183(1993)
[24]	W.H. Lai, C.Z. Yu,Battery Bimon. 26, 189(1996)
[25]	E.A. Lass, Int. J. Hydrog. Energy 36, 10787 (2011)
[26]	L.Z. Ouyang, Z.J. Cao, L. Yao, H. Wang, J.W. Liu, M. Zhu, Int. J. Hydrog. Energy 39, 13616 (2014)
[27]	K. Tanaka, Y. Kanda, M. Furuhashi, K. Saito, K. Kuroda, H. Saka, J. Alloys Compd. 295, 521(1999)
[28]	T. Spassov, L. Lyubenova, U. Köster, M.D. Baró,Mater. Sci. Eng., A 375-377, 794(2004)
[29]	Y.H. Zhang, H.T. Wang, X.P. Dong, W.G. Bu, Z.M. Yuan, G.F. Zhang, Acta Metall. Sin. (Engl. Lett.) 27, 1088(2014)
[30]	N. Cui, B. Luan, H.J. Zhao, H.K. Liu, S.X. Dou, J. Alloys Compd. 233, 236(1996)
[31]	A. Züttel, F. Meli, L. Schtapbach, J. Alloys Compd. 200, 157(1993)
[32]	L. Zaluski, A. Zaluska, J.O. Ström-Olsen, J. Alloys Compd. 253-254, 70 (1997)
[33]	C. Lenain, L. Aymard, L. Dupont, J. Tarascon, J. Alloys Compd. 292, 84(1999)
[34]	H.P. Ren, Y.H. Zhang, B.W. Li, D.L. Zhao, S.H. Guo, X.L. Wang, Int. J. Hydrog. Energy 34, 1429 (2009)
[35]	M.V. Simičić, M. Zdujić, R. Dimitrijević, L. Nikolić-Bujanović, N.H. Popović, J. Power Sources 158, 730 (2006)
[36]	B.V. Ratnakumar, C. Witham, R.C. Bowman Jr, A. Hightower, B. Fultz, J. Electrochem. Soc. 143, 2578(1996)
[37]	F. Feng, J. Han, M. Geng, D.O. Northwood, J. Electroanal. Chem. 487, 111(2000)
[38]	N. Cui, J.L. Luo, Int. J. Hydrog. Energy 24, 37 (1999)
[39]	Y.H. Zhang, Z.C. Liu, B.W. Li, Z.H. Ma, S.H. Guo, X. L Wang. Electrochim. Acta 56, 427 (2010)