Among the various battery technologies, lithium ion batteries stand out because of the facilitating design of storage systems with high energy density. To advance its performance, vanadium trioxide (V2O3) has been regarded as a potential anode material because of their high theoretical lithium storage capability (1073 mAh g-1), large nature abundance and low toxicity. In addition of V2O3, vanadium nitride also has the opportunity to improve performance due to its relatively low electrical resistivity. Herein, a simple process to prepare the electrode is introduced. Vanadium pentoxide nanowires are simply synthesized by hydrothermal method and compress into free-standing sheet. It is then transformed into vanadium oxide/vanadium oxynitride nanoporous composite (V2O3/VOxNy) by nitrodation process under NH3. Different vanadium oxide/vanadium oxynitride ratios were achieved by controlling the nitridation temperature. The free-standing (V2O3/VOxNy) sheet was direct used as anode electrode without the process of coating material with mixing slurry on the substrate. To improve cycling performance, we add Super P® (conductive carbon) to prepare vanadium oxide/vanadium oxynitride composite with Super P® (V2O3/VOxNy-C). As a result, V2O3/VOxNy and V2O3/VOxNy-C deliver 222 and 322 mAh g-1 up to fifty cycles at a current density of 100 and 80 mAh g-1. Thus, these composite films are promising candidates for anode of lithium-ion battery.