A phosphoric anion layer inhibits electronic current generation and nanotube growth during anodization of titanium

Nowadays the formation mechanism of anodic TiO(2) nanotubes has attracted extensive attention. Field-assisted dissolution (TiO(2) + 6F(−) + 4H(+) → [TiF(6)](2−) + 2H(2)O) has been considered as the causal link to the formation and growth of nanotubes. But it is hard for this theory to explain three stages of the current–time curve. Here, the anodization of titanium was studied by adding different concentrations of H(3)PO(4) (0%, 4 wt%, 6 wt%, 8 wt%, and 10 wt%) in ethylene glycol containing the same concentration of NH(4)F (0.5 wt%). The results prove that under the action of the same concentration of NH(4)F, the growth rate of nanotubes decreases obviously with the increase of H(3)PO(4) concentration, and the second stage of the current–time curve is also prolonged simultaneously. These experimental facts cannot be interpreted by field-assisted dissolution theory and the viscous flow model. Here, an anion layer formed by H(3)PO(4) and the electronic current theory are ably used to explain these facts reasonably for the first time.