Ethanol-Mediated 2D Growth of Cu(2)O Nanoarchitectures on Nanoporous Cu Templates in Anhydrous Ethanol

Two types of cupric oxide (Cu(2)O) nanoarchitectures (nanobelts and nanopetal networks) have been achieved via immersion nanoporous copper (NPC) templates in anhydrous ethanol. NPC templates with different defect densities have been prepared by dealloying amorphous Ti(60)Cu(40) ribbons in a mixture solution of hydrofluoric acid and polyvinylpyrrolidone (PVP) with different ratios of HF/PVP. Both a water molecule reactant acting as OH(−) reservoir and the ethanol molecule serving as stabilizing or capping reagent for inhibiting the random growth of Cu(2)Oplayed a role of the formation of 2-dimensional Cu(2)O nanoarchitectures. Cu(2)O nanobelts are preferred to form in anhydrous ethanol on the NPC templates from Ti(60)Cu(40) ribbons dealloying in the solution with low HF concentration and small addition of PVP; and Cu(2)O nanopetals are tended to grow in anhydrous ethanol from the NPC templates from Ti(60)Cu(40) ribbons dealloying in the solution with high HF concentration and large addition of PVP. With increasing the immersion time in anhydrous ethanol, Cu(2)O nanopetals united together to create porous networks about 300 nm in thickness. The defect sites (i.e., twin boundary) on nanoporous Cu ligaments preferentially served as nucleation sites for Cu(2)O nanocrystals, and the higher defect density leads to the formation of uniform Cu(2)O layer. Synergistic effect of initial microstructure of NPC templates and stabilizing agent of ethanol molecule results in different Cu(2)O nanoarchitectures.