This thesis contains two main topics: heterojunction nano-structures and photocatalysts. First, a series of novel p-type Cu2O and CuO, n-tpye ZnO, and their mixed p-n heterojunction nano-structures were newly prepared mainly by chemical reduction method. Second, the nano-structures obtained were applied as photocatalysts and the nano-structural influence on photocatalytic performance was compared and discussed. Cu2O was prepared by spontaneous oxidation of spherical Cu nano-particles (~5 nm in diameter) in water at room temperature. Several novel CuO nano-structures were then simply synthesized by the further oxidation of the prepared Cu2O nano-particles in aqueous solutions. Accompanying with the oxidation process, a distinct morphological transformations from zero-dimensional (Cu2O) to one-dimensional or two-dimensional (CuO) was found and its mechanism is considered as the key point to produce such a variety of CuO nanostructures including buckhorn-like rods, short rods, and flakes, in this work. In addition, one-dimensional Cu(OH)2 nano-structures (~100 nm long and 15 nm in width) can also be found under some oxidation conditions. ZnO nano-structures including one-dimensional single crystal rods, octahedra and three-dimensional flower-like assemblies were synthesized. In addition, using suspended Cu2O nano-particles as substrates, ZnO nano-structures could directly grow on Cu2O to form a p-n heterojunction ZnO/CuO composite. Our photocatalytic experiment has proved that the p-n heterojunction ZnO/CuO composite prepared indeed presents at least 45% enhancement of the degradation efficiency of organic dye, Rhodamine B, comparing with the simple mixture of CuO and ZnO nano-structures. Nano-structures generally demonstrate a variety of morphologies in comparison with bulk materials. In this thesis, we illustrated a series of XRD analysis with theoretical calculations to distinguish some frequently observed morphologies of nano-particles, including cube, sphere, decahedron and icosahedron for metals and sphere, cube and rod for oxides.