Abstract

A new synthesis route has been applied to obtain Li1+xV3O8. Instead of the conventional high-temperature technique
\nleading to the crystalline form, a solution technique producing the amorphous form has been used. This material, after dehydration,
\nshows an electrochemical performance exceeding that of the crystalline one. The rationale for this behavior
\nmainly lies in microscopic factors, i.e., in the possibility for the unit cell of amorphous Li1+xV3O8 to insert up to 9 Li +, instead
\nof six for crystalline Li1+xV3O8. Furthermore, the absence of a long-range crystallographic order reduces the length
\nof the pathways through which Li + ions diffuse. This and the favorable morphology endow amorphous Li1+xV3O8 with a
\nhigh rate capability. The higher energy content afforded by this new form (theoretical value, 935 Wh/kg, based on the electrodes
\nweight) can be exploited in long-cycling cells at high rates.