Growth of thin vanadia nanobelts with improved lithium storage capacity in hydrothermally aged vanadia gelsElectronic supplementary information (ESI) available. See DOI: 10.1039/c1ce05802a

A process of hydrothermal ageing of vanadia gels yields 1020 nm thick and 90100 nm wide nanobelts exceeding 10 microns in length. The diminished thickness and networking of anisotropic nanobelts lead to lithium intercalation capacities exceeding 450500 mA h g 1 at a C/25 rate. The observed morpholog...

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Main Authors: Semenenko, Dmitry A, Kozmenkova, Anna Ya, Itkis, Daniil M, Goodilin, Eugene A, Kulova, Tatyana L, Skundin, Alexander M, Tretyakov, Yuri D
Format: Article
Language:English
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Summary:A process of hydrothermal ageing of vanadia gels yields 1020 nm thick and 90100 nm wide nanobelts exceeding 10 microns in length. The diminished thickness and networking of anisotropic nanobelts lead to lithium intercalation capacities exceeding 450500 mA h g 1 at a C/25 rate. The observed morphology features depend essentially on preparation conditions and allow to assume that this particular route results in a suitable morphology of nanobelts via chemical bond rearrangement in the course of olation and oxolation in the aged bulk gel. Unzipping of the layered structure of the precursor gel into single-crystalline nanobelts, and optimization of post-hydrothermal processing resulted in nanomaterials with enhanced electrochemical characteristics, making vanadia gels a precursor of choice for simple preparation of new battery nanomaterials. A process of hydrothermal ageing of vanadia gels yields anisotropic vanadia nanobelts demonstrating lithium intercalation capacities exceeding 450500 mAh g 1 at a C/25 rate. The observations made show that electrochemical properties are in a strong correlation with a nanobelts preparation route.
ISSN:1466-8033
DOI:10.1039/c1ce05802a