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Nanostructured Molybdenum-Oxide Anodes for Lithium-Ion Batteries: An Outstanding Increase in Capacity.

Hua WangTianyi LiAhmed M HashemAshraf E Abdel-GhanyRasha S El-TawilHanaa M AbuzeidAmanda CoughlinKai ChangShixiong ZhangHazim El-MounayriAndres TovarLikun ZhuChristian M Julien
Published in: Nanomaterials (Basel, Switzerland) (2021)
This work aimed at synthesizing MoO 3 and MoO 2 by a facile and cost-effective method using extract of orange peel as a biological chelating and reducing agent for ammonium molybdate. Calcination of the precursor in air at 450 °C yielded the stochiometric MoO 3 phase, while calcination in vacuum produced the reduced form MoO 2 as evidenced by X-ray powder diffraction, Raman scattering spectroscopy, and X-ray photoelectron spectroscopy results. Scanning and transmission electron microscopy images showed different morphologies and sizes of MoO x particles. MoO 3 formed platelet particles that were larger than those observed for MoO 2 . MoO 3 showed stable thermal behavior until approximately 800 °C, whereas MoO 2 showed weight gain at approximately 400 °C due to the fact of re-oxidation and oxygen uptake and, hence, conversion to stoichiometric MoO 3 . Electrochemically, traditional performance was observed for MoO 3 , which exhibited a high initial capacity with steady and continuous capacity fading upon cycling. On the contrary, MoO 2 showed completely different electrochemical behavior with less initial capacity but an outstanding increase in capacity upon cycling, which reached 1600 mAh g -1 after 800 cycles. This outstanding electrochemical performance of MoO 2 may be attributed to its higher surface area and better electrical conductivity as observed in surface area and impedance investigations.
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