Monodisperse nanospheres and spherical structures derived from them, such as core-shell or hollow nanospheres, have become a new study focus because their potential applications in optics, electrics, catalysis, sensors, and so forth. [1][2][3][4] Many researchers are working on the preparation of new monodisperse nanospheres and their functional transformation. [5][6][7][8][9][10][11][12][13][14] The traditional monodisperse micro-or nanospheres are amorphous silica and polymer colloids which were prepared by controlled hydrolyzation of tetraethyl orthosilicate and emulsion polymerization. [5][6][7][8] Using these colloidal templates, the Caruso group has prepared many kinds of porous hollow spheres and core-shell nanospheres through the "layer-by-layer" method, such as coating the spheres with noble-metal nanoparticles, metal oxide nanoparticles, polyelectrolytes, or biomolecules with specific electronic, optical, catalytic, and biological applications. 2,10 In recent years, much progress has been made on the preparation of monodisperse inorganic nanospheres. [11][12][13] For example, the Xia group has developed the glycol refluxing method to synthesize monodisperse metal micro or nanospheres, such as Bi, Pb, Se, metal alloys, and their functional core-shell structures. 11 Our group has developed the hydrothermal or solvothermal method to synthesize monodisperse micro-and nanospheres, such as chalcogenide, carbon, single-crystalline magnetic ferrite, and so forth. [12][13][14] By the template of carbon colloids, many hollow spheres, such as Ga 2 O 3 , GaN, WO 3 , and so forth have been prepared with special optical or sensor properties. 14 From above, it is concluded that because the intrinsic properties of monodisperse nanospheres can be finely tuned by changing parameters such as diameter, chemical composition, bulk structure, and crystallinity, searching for novel methods and preparing more kinds of monodisperse nanospheres are still required for some special applications. 6 Cuprous oxide (Cu 2 O), a p-type semiconductor with unique optical and magnetic properties, has potential applications in solar energy conversion, electronics, magnetic storage, catalysis, and gas sensors. CuO is also a potential material with many applications in catalysis, gas sensing, and lithium-copper oxide electrochemical cells. [15][16][17][18] CuO was the first kind of humidity sensing material found by Braver et al. in 1931. It was reported that Cu 2 O films had gas sensing activity at ∼200 °C. 16 Considering the potential applications of copper-based materials, many kinds of morphologies have been reported, such as wires, monodisperse nanocubes, octahedral nanocages, hollow nanospheres, and so forth. 15,17,18 Typically, the Zeng group used a solvothermal method in N,N-dimethylformamide (DMF) at 150-180 °C for 20-40 h to get hollow Cu 2 O nanospheres. They found the formation process of Cu 2 O hollow spheres included formation of CuO nanocrystals, aggregation of primary CuO nanocrystals, and the reductive transformation to C...
