Abstract
In this study, two compounds of TiNb2O7 and Ti2Nb10O29 were successfully synthesized by mechanochemical method and post-annealing as an anode material for lithium-ion batteries. The effect of annealing atmosphere on the morphology, particle size, and electrochemical characteristics of two compounds was investigated. For these purposes, the reactive materials were milled under an argon atmosphere with a certain mole ratio. Subsequently, each sample was subjected to annealing treatment in two different atmospheres, namely argon and oxygen. Phase and morphology identifications were carried out by X-ray diffraction (XRD) and field emission scanning electron microscopy (FESEM) to identify the phases and evaluate the morphology of the synthesized samples. The charging and discharging tests were conducted using a battery-analyzing device to evaluate the electrochemical properties of the fabricated anodes. Annealing in different atmospheres resulted in variable discharge capacities so that the two compounds of TiNb2O7 and Ti2Nb10O29 annealed under the argon atmosphere showed a capacity of 60 and 66 mAh/g after 179 cycles, respectively, which had a lower capacity than their counterpart under the oxygen atmosphere. The final capacity of the annealed samples in the oxygen atmosphere is 72 and 74 mAh/g, respectively.
Highlights
Global warming and energy saving are among the most crucial issues in the world
The annealing atmosphere might be an effect on the morphology and crystallite size
The EDS analysis of all specimens is further confirmed that the presence of Ti, Nb, and O representing the formation of TiNb2 O7 and Ti2 Nb10 O29 compounds as shown in Figure S1
Summary
Global warming and energy saving are among the most crucial issues in the world. With rapid economic growth and manpower, global energy consumption increases dramatically [1,2,3]. The issue of sustainability and saving energy resources worldwide received great consideration due to the crisis of reducing and terminating fossil energy resources and consideration of environmental pollution issues [4]. Batteries are one of the types of energy storage systems that currently have a wide range of commercial or underdeveloped research stages [5]. Lithium-ion (Li-ion) batteries with increased effectiveness, lower costs, and increased safety are required for a variety of applications, such as hybrid cars, consumer electronics, and grid-scale energy storage, and considerable research and development initiatives are underway [6,7,8].
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