Electrochemical Study of Zinc-Substituted Nickel Hydroxide

Tessier, Cécile; Fauré, Christine; Guerlou‐Demourgues, Liliane; Denage, C.; Nabias, G.; Delmas, Claude

doi:10.1149/1.1495496

Cited by 65 publications

(58 citation statements)

References 21 publications

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“…But till now, non-spherical Ni(OH) 2 has attracted little attention as raw material for the positive electrode in commercial batteries because non-spherical powders always show a lower tapdensity (1.5-1.8 g cm −3 ) [8,23]. Most studies about non-spherical Ni(OH) 2 in the literature mainly focused on either the properties of Ni(OH) 2 electrodes for rechargeable Cd-Ni and Ni-MH batteries or the crystal chemistry of Ni(OH) 2 [24][25][26][27]. In the previous work [22], we have studied the effect of tap-density on the electrochemical performance of non-spherical Ni(OH) 2 electrodes.…”

Section: Introductionmentioning

confidence: 99%

Comparative structural and electrochemical study of high density spherical and non-spherical Ni(OH)2 as cathode materials for Ni–metal hydride batteries

Shangguan

Chang

Tang

et al. 2011

Journal of Power Sources

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:Nickel hydroxide High-density Nickel-metal hydride batteries High-rate discharge Cathode materials a b s t r a c tIn this paper we compare the behavior of non-spherical and spherical ␤-Ni(OH) 2 as cathode materials for Ni-MH batteries in an attempt to explore the effect of microstructure and surface properties of ␤-Ni(OH) 2 on their electrochemical performances. Non-spherical ␤-Ni(OH) 2 powders with a high-density are synthesized using a simple polyacrylamide (PAM) assisted two-step drying method. X-ray diffraction (XRD), infrared spectroscopy (IR), scanning electron microscopy (SEM), thermogravimetric/differential thermal analysis (TG-DTA), Brunauer-Emmett-Teller (BET) testing, laser particle size analysis, and tap-density testing are used to characterize the physical properties of the synthesized products. Electrochemical characterization, including cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), and a charge/discharge test, is also performed. The results show that the non-spherical ␤-Ni(OH) 2 materials exhibit an irregular tabular shape and a dense solid structure, which contains many overlapped sheet nano crystalline grains, and have a high density of structural disorder and a large specific surface area. Compared with the spherical ␤-Ni(OH) 2 , the non-spherical ␤-Ni(OH) 2 materials have an enhanced discharge capacity, higher discharge potential plateau and superior cycle stability. This performance improvement can be attributable to a higher proton diffusion coefficient (4.26 × 10 −9 cm 2 s −1 ), better reaction reversibility, and lower electrochemical impedance of the synthesized material.

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Section: Introductionmentioning

confidence: 99%

Comparative structural and electrochemical study of high density spherical and non-spherical Ni(OH)2 as cathode materials for Ni–metal hydride batteries

Shangguan

Chang

Tang

et al. 2011

Journal of Power Sources

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“…Partial substitution of nickel ion in the nickel hydroxide lattice by other metal ions, such as Al [9,11], Co [11,12], Fe [13], Mn [14] and Zn [15,16], is the commonly used method to prepare a stable ␣-Ni(OH) 2 , among which Al is the most attractive because Al-substituted ␣-Ni(OH) 2 has relatively better electrochemical performance. Chemical co-precipitation, electrochemical impregnation and the 'chimie douce' techniques are the three common used methods to prepare ␣-Ni(OH) 2 [17], while homogeneous precipitation in the presence of urea, usually called urea decomposition, can also produce Ni(OH) 2 .…”

Section: Introductionmentioning

confidence: 99%

Effect of crystallinity on the electrochemical performance of nanometer Al-stabilized α-nickel hydroxide

et al. 2008

Journal of Alloys and Compounds

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“…On the negative sweep the cathodic current peak at about Ni(II) -ClNi 2+ + Clfi NiCl + 0 0.75 V is obviously divided into two current peaks C11 and C12. As has been reported in the literature [20][21][22], nickel hydroxide may exist in at least two different crystallographic forms a-Ni(OH) 2 and b-Ni(OH) 2 , hydrous and anhydrous, respectively. In addition, the oxidization of nickel hydroxide gives two other varieties of oxyhydroxides, b-NiOOH and c-NiOOH.…”

Section: Cyclic Voltammogram Researchmentioning

confidence: 60%

Influence of ammonia concentration on anodic deposition of nickel oxide

Zheng

2007

J Appl Electrochem

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Nickel oxide was prepared by anodic deposition in a basic solution comprising nickel chloride, ammonium chloride and ammonia. The influence of ammonia was investigated using galvanostatic reduction techniques and cyclic voltammetry (CV). It was found that the oxidization peak potentials shift positively with decreasing ammonia concentration, while the oxidization peak currents firstly increase with decreasing ammonia concentration and then decrease when the ammonia concentration is lower than 1.67 mol L -1 . This is mainly attributed to the fact that the equilibrium concentration of Ni(OH) 2(aq) varies with the ammonia concentration. A potential plateau at about 0.75 V was observed in galvanostatic reduction curves for nickel oxide, and the length of the potential plateau in solution with 1.67 mol L -1 ammonia concentration was longer than that in the other solutions, which agreed well with the CV results.

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Electrochemical Study of Zinc-Substituted Nickel Hydroxide

Cited by 65 publications

References 21 publications

Comparative structural and electrochemical study of high density spherical and non-spherical Ni(OH)2 as cathode materials for Ni–metal hydride batteries

Comparative structural and electrochemical study of high density spherical and non-spherical Ni(OH)2 as cathode materials for Ni–metal hydride batteries

Effect of crystallinity on the electrochemical performance of nanometer Al-stabilized α-nickel hydroxide

Influence of ammonia concentration on anodic deposition of nickel oxide

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