Sodium ion battery (SIB) has engage sustainable alternative on replacing lithium ion batteries. The lower potential and larger ionic value has demanded on seeking a potential anode materials. Amorphous TiO₂ prepared by electrochemical anodisation technique has provide a suitablility as anode SIB materials, which approved by conducting XRD, FTIR, and SEM-EDX measurements. Electrochemical performance was tested with variations in the concentration of NaOCl₄ electrolyte in propylene carbonate (PC) solvent. Diffractogram of TiO₂ showed the only peaks of Ti was observed at 2θ = 40.34. The TiO₂ IR spectrogram shows that the absorption band at 507 cm^-1 is the peak of the vibration characteristics of the Ti-O bond and the peak of 975 cm^-1 corresponds to Ti-O-Ti bond. SEM-EDX image analysis showed the morphology of TiO₂ was smooth without pore with a ratio of Ti: O elemental composition of 1: 2. Voltammogram showed the anodes in 0.5 M NaOCl₄ electrolyte in PC solvent has a good stability potential windows with the high current density 1.2 mA and the capacity of 0.037 F/g

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