We report a deposition process to prepare nearly aligned binary and ternary vanadium oxides nanowires, including VO2(R), VO2(B), V2O3, and -NaxV2O5. In the first section, VO2(R), VO2(B), and V2O3 nanowires were prepared by reducing the precursor of V2O5 nanowires with controlled concentration of reducing gas flow and reduced period. The large portions of NWs microstructure are successfully preserved during the reduction, and are still nearly vertical-aligned on the surface. The growth directions of these reducing products were influenced by the growth direction of the original phase, V2O5 NWs. On the basis of the growth direction of each product, possible mechanisms of conversion during reduction reaction are proposed. In the second section, -NaxV2O5 nanowires were prepared via a route combined the original thermal evaporation procedure with additive pre-treatment of the surfaces of substrates. The sodium silicate, source of the sodium, was first coated on the substrates and the amount of precursor was carefully controlled on a Na+-free substrate. The length of the -Na0.24V2O5 wires could be controlled in the range of 5-25m by changing the reaction condition, which grew along the [100] direction. X-ray powder diffraction (XRD) and transmission electron microscopy (TEM) were used to confirm the crystallinity of oxide nanowires. The effect of the controlled amount of deposited material and morphology were studied. A possible formation mechanism was proposed. The field emission properties of these binary and ternary vanadium oxides nanowires have been investigated. The results show that the as-prepared NWs possess excellent field emission performances with low turn-on field, large emission current density and linear Fowler-Nordheim behaviors. The studies suggest that these 1D nanomaterials could serve as promising candidates for future field emission devices.