In many applications, metallic copper can be covered by an ultrathin native or a passive oxide film depending on the redox conditions of the interface formed with the environment, which governs its surface properties. In the present work, we constructed and optimized through quantum chemical DFT calculations a model of this Cu(111)||Cu2O(111) stoichiometric oxide supported in parallel epitaxy on Cu(111) substrate. Energetic analysis of the metal-oxide interface shows the stable formation of the interface between oxide film and metal substrate. The Cu2O(111) film binds to the Cu(111) surface via the unsaturated oxygen atoms bonded to copper metal atoms in top, bridge and hollow sites. Structural analysis of the Cu2O(111) film surface shows reconstruction with modifications of the distances between the unsatu-rated and the saturated copper atoms. The surface interlayer relaxation is inward for Cu(111)||Cu2O(111), whereas it is outward for the non supported Cu2O(111) oxide, and converges to that of bulk oxide with increasing the Cu2O(111) thickness. The electronic work function is not significantly modified with respect to the Cu(111) electronic work function, whatever the oxide thickness. The hydration of the surface is energetically favorable and water molecular adsorption is favored over dissociative adsorption. Water molecules chemisorb on top over unsaturated copper atoms. The hydroxylation of the surface shows two adsorption modes of the OH groups on top over unsaturated Cu atoms and on bridge site between unsaturated and saturated Cu atoms.