Hydrogen Storage Performances of Nanocrystalline and Amorphous NdMg11Ni+x wt% Ni (x=100, 200) Alloys Synthesized by Mechanical Milling

doi:10.1007/s40195-019-00880-9

Abstract

Abstract:

Nanocrystalline and amorphous NdMg₁₂-type NdMg₁₁Ni+x wt% Ni (x=100, 200) alloys were successfully prepared through ball milling (BM). The microstructures and electrochemical properties were systematically studied to get a more comprehensive understanding of the sample alloys. The maximum discharging capacity could be obtained at only two cycles, indicating that as-milled alloys have superior activation capability. The more the Ni content, the better the electrochemical properties of the as-milled samples. To be specific, the discharge capacities of x=100 and x=200 (BM 20 h) samples are 128.2 and 1030.6 mAh/g at 60 mAh/g current density, respectively, revealing that enhancement of Ni content could significantly improve the discharging capacities of the samples. Additionally, milling duration obviously influences the electrochemical properties of the samples. The discharging capacity always rises with milling duration prolonging for the x=100 sample, but that of the (x=200) sample shows a trend of first augment and then decrease. The cycling stability of the (x=100) alloy clearly decreases with extending milling duration, whereas that of the (x=200) alloy first declines and then augments under the same conditions. In addition, the high rate discharge (HRD) abilities of the sample display the maximal values as milling duration changes. The HRD (HRD=C₃₀₀/C₆₀×100%) values of the as-milled alloys (x=100, 200) are 80.24% and 85.17%, respectively.

Key words: NdMg₁₂ alloy, Mechanical milling, Electrochemical hydrogen storage performance, Dynamic characteristics, Activation energy

Yang-Huan Zhang, Kai-Feng Zhang, Ze-Ming Yuan, Peng-Peng Wang, Ying Cai, Wen-Gang Bu, Yan Qi. Hydrogen Storage Performances of Nanocrystalline and Amorphous NdMg₁₁Ni+x wt% Ni (x=100, 200) Alloys Synthesized by Mechanical Milling[J]. Acta Metallurgica Sinica (English Letters), 2019, 32(9): 1089-1098.

Figures/Tables 14

Fig. 1 XRD profiles of the as-cast and milled (20 h) NdMg11Ni+x wt% Ni (x=0, 100, 200) alloys before and after hydriding: a before hydriding; b after hydriding

Fig. 2 TEM micrographs and ED patterns of the as-cast and milled (20 h) NdMg11Ni+x wt% Ni (x=0, 100, 200) alloys: ax=0, as-cast; bx=100, milling for 20 h; cx=200 milling for 20 h

Fig. 3 PCT curves of the as-milled (20 h) NdMg11Ni+x wt% Ni (x=100, 200) alloys in the temperature range of 553-613 K and Van’t Hoff plots for hydrogen absorption/desorption of the alloys: ax=100; bx=200

Table 1 Enthalpy and entropy change of as-milled alloys obtained from the Van’t Hoff plots

Samples: NdMg₁₁Ni+x wt% Ni	Absorption		Desorption
Samples: NdMg₁₁Ni+x wt% Ni	ΔH (kJ/mol)	ΔS (J/mol/K)	ΔH (kJ/mol)	ΔS (J/mol/K)
x=100	-68.15	-126.77	78.28	135.63
x=200	-66.18	-123.62	72.58	128.01

Fig. 4 Evolution of the discharge capacity of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys with cycle number: ax=100; bx=200

Fig. 5 Variation of the discharge capacity of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys with milling time

Fig. 6 Discharge potential curves of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys: ax=100; bx=200

Fig. 7 Variation of the capacity retaining rate (Sn) of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys with cycle number: ax=100; bx=200

Fig. 8 Variation of the capacity retaining rate (S20) of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys with milling time

Fig. 9 Evolution of the HRDs of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys with current density: ax=100; bx=200

Fig. 10 Semilogarithmic curves of anodic current vs. time responses of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys: ax=100; bx=200

Fig. 11 EIS of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys: ax=100; bx=200

Fig. 12 EIS of the as-milled (20 h) NdMg11Ni+x wt% Ni (x=100, 200) alloys at various temperatures: ax=100; bx=200

Fig. 13 Evolution of the activation enthalpy ΔrH* values of the as-milled NdMg11Ni+x wt% Ni (x=100, 200) alloys with the milling time

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Hydrogen Storage Performances of Nanocrystalline and Amorphous NdMg₁₁Ni+x wt% Ni (x=100, 200) Alloys Synthesized by Mechanical Milling

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