Anisotropic vanadium oxide nanostructured host matrices for lithium ion intercalation

We report on unique high-volume low-dimensional V O-based turbostratic nanostructures, prepared using sol-gel synthetic methods from VO ṡ n H 2 O xerogels. Electrochemical intercalation of Li to form Li VO resulted in a maximum measured charge capacity of 1225mAh g as the β- Li VO phase. Conductivities of the order of 10 Scm were found on compressed-nanotube parallelepipedal samples, which exhibit an anisotropy factor of 70 at room temperature by preferential alignment of the nanotubes. The improved electrochemical properties observed in novel vanadium oxide nanostructured arrays are attributed to the increased volumetric density for ion intercalation, shorter diffusion paths to the intercalation sites, and a high degree of crystallinity ofthe individual nanotubular host structures

Anisotropic vanadium oxide nanostructured host matrices for lithium ion intercalation

We report on unique high-volume low-dimensional V O-based turbostratic nanostructures, prepared using sol-gel synthetic methods from VO ṡ n H 2 O xerogels. Electrochemical intercalation of Li to form Li VO resulted in a maximum measured charge capacity of 1225mAh g as the β- Li VO phase. Conductivities of the order of 10 Scm were found on compressed-nanotube parallelepipedal samples, which exhibit an anisotropy factor of 70 at room temperature by preferential alignment of the nanotubes. The improved electrochemical properties observed in novel vanadium oxide nanostructured arrays are attributed to the increased volumetric density for ion intercalation, shorter diffusion paths to the intercalation sites, and a high degree of crystallinity ofthe individual nanotubular host structures