The influence of ethylene glycol (EG) on the morphology of anodic alumina fabricated during hard anodization (HA) was analyzed. A transformation from continuous nano-porous film to separated alumina nano-tubes was induced upon addition of EG to a 0.M oxalic acid solution. Moreover, while anodization under constant voltage in a 1:1 v/v EG:H2O acidic solution resulted in distinct current density (i(a)) reduction in reference with the i(a) registered for the HA in an EG-free solution, the anodization in a 1:4 v/v EG:H2O mixture was often accompanied by a sudden i(a) increase and irregular current oscillations. In the latter case mostly the alumina nanotubes with wall thickness variation were produced. In-general, the separation phenomena was explained by extensive incorporation of soluble C2O42- and COO- ions into the oxide framework leading to an enhanced oxide dissolution rate and preferred cleavages along the cell boundaries. The current oscillation and the production of nanotubes with an altered diameter were ascribed to a higher value of epsilon(el) . epsilon(ox) / eta ratio (where epsilon(el) and epsilon(ox) are the dielectric coefficient of electrolyte and the formed anodic oxide, respectively, and eta is the dynamic viscosity of the solvent) as compared to the value relevant for more viscous solvent. (C) 2015 Elsevier B.V. All rights reserved.