Abstract

Portable electronics and their commercial use are strongly dependent on the prize, performance and life cycle of the rechargeable batteries. This is even truer for the use in electric vehicles. Currently used Li+-ion batteries represent the state of art technology but there still is a strong demand for further improvement [1,2]. Low abundance and thus high costs for lithium have initiated intensive research for the possible replacement of lithium by other more abundant metals such as magnesium and sodium [3]. Ionic, electronic and chemical characteristics of Li+-, Na+- and Mg2+-ions are different and therefore host materials appropriate for Li+-ions intercalation are not necessarily suitable for Mg2+ and Na+ ions – as well known for the case of graphite anodes. The cathode material V2O5 is one candidate which already showed good performance not just for Li+ but also for Mg2+ and Na+ions [4,5]. Since the morphology and structure of the host materials strongly influence the intercalation process, in this study efforts have been done to synthesize V2O5 with different morphology by applying different synthetic routes and choosing the best material for the metal ion intercalation. V2O5 was prepared by means of sonochemical modification of commercial V2O5 powder, anodization of V metal, electrochemical deposition and hydrothermal synthesis. The obtained materials were characterized by means of scanning electron microscopy, X-ray diffraction and X-ray photoelectron spectroscopy. The sonochemical treatment and electrochemical deposition yielded V2O5-nanofibers, the anodization method V2O5-nanotubes and the hydrothermal synthesis hollow nanospheres of V2O5. The performance of the obtained materials was tested by several electrochemical techniques such are cyclic voltammetry, potentiostatic intermittent titration technique (PITT) and galvanostatic charge/discharge cycles. Li, Na and Mg intercalation were studied. For Li, the rate capability of the sonochemically prepared material was clearly improved compared to commercial, microcrystalline V2O5, but the available voltage at a given discharge capacity was less. The electrodeposited material showed a rather poor performance, while the hollow nanospheres behaved very promising. Also for Na intercalation the latter material showed reasonable performance. First measurements for Mg insertion are shown as well. [1] Dunn B. et al., Electrical Energy Storage for the Grid: A Battery of Choices, Science 334 (2011) 928 [2] Gachot G. et al., Deciphering the multi-step degradation mechanisms of carbonate-based electrolyte in Li batteries, Journal of Power Sources 178 (2008) 409 [3] Besenhard J. et al., Advances in battery technology: rechargeable magnesium batteries and novel negative-electrode materials for lithium ion batteries, ChemPhysChem 3 (2002) 155 [4] Gershinsky G. et al., Electrochemical and Spectroscopic Analysis of Mg2+ Intercalation into Thin Films Electrodes of Layered Oxides: V2O5 and MoO3, Langmuir 29 (2013) 10964 [5] Su D. W. et al., Hierarchical orthorhombic V2O5hollow nanospheres as high performance cathode materials for sodium-ion batteries, J. Mater. Chem. 2 (2014) 11185

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