Development of Cathode Material for Lithium Ion Rechargeable Batteries Based on the System Li(Niv3Mnii3C01/3 _Nax, 002 x = 0.02 , 0.06
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Date
2017
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Uva Wellassa University of Sri Lanka
Abstract
Expensiveness of electrode materials, such as LiCo02, is recognized as one of the main barriers that prevents the development of the rechargeable Lithium Ion Batteries (LIB) from reaching the common masses. Therefore, layered transition metal oxides such as Li(Niii3Mni3C01/3)02 are presently being investigated as an alternative cathode material. Moreover, substitution of Na in transition metal oxides of Ni, Mn and Co (NMC) has been identified as an effective strategy to improve their ele'ctrochemical performance. The present work attempted to synthesize Li(Niv3Mn 13C01/3-xNa 002 x = 0.02 and 0.06 through substituting expensive Co by cheaper Na, using Glycine Nitrate Combustion (GNC) method. The GNC is an effective method to synthesize sub-micron size particles formed by agglomerating primary nano scale particles. This particle morphology is chemically stable and provides greater rate capability and electrochemical performance. Li(Niu3Mnit3C01/3-xNax)02, x = 0.02 and
0.06, oxide powders were synthesized by GNC method keeping the Glycine:Nitrate ratio as 0.6, by calcining at 900 °C for two hours. This process is a simple and single step process with a low calcination period. Scanning electron microscopy showed that the synthesized powder consists of quasi-spherical, secondary particles formed by aggregating nano-scale primary particles. Chemical analyses of synthesized powders reveal that the composition of these synthesized samples was close to stoichiometric ratio given by its empirical formula. Fourier transform infrared spectra of Li(NiIRMn1RCo1/3-xNax)02 x = 0.02 and 0.06 are characterized by IR absorption bands in three distinct regions. These bands represent the characterized chemical bonds in layered metal oxides with a-NaFe02 structure. The four probe D.C. electrical conductivity measurements performed on the dense sintered pellets showed enhanced electrical conductivity in these novel materials compared that of base material, Li(Ni1/3Mnii3Coi/3)02. Hence this study revealed the possibility of preparing cheaper Li(Ni1i3Mnii3C01/3-xNax)02 by GNC method, for the intended LIB cathode applications.
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Science and Technology Degree Programme (SCT)