Lizhu Liu

Chemical conversion synthesis of ZnS shell on ZnO nanowire arrays: morphology evolution and its effect on dye-sensitized solar cell.

Heterostructured ZnO/ZnS core/shell nanowire arrays have been successfully fabricated to serve as photoanode for the dye-sensitized solar cells (DSSCs) by a facile two-step approach, combining hydrothermal deposition and liquid-phase chemical conversion process. The morphology evolution of the ZnS coated on the ZnO nanowires and its effect on the performance of the DSSCs were systematically investigated by varying the reaction time during the chemical conversion process. The results show that the compact ZnS shell can effectively promote the photogenerated electrons transfer from the excited dye molecules to the conduction band of the ZnO, simultaneously suppress the recombination for the injected elelctrons from the dye and the redox electrolyte. As reaction time goes by, the surface of the nanowires becomes coarse because of the newly formed ZnS nanoparticles, which will enhance the dye loading, resulting in increment of the short-circuit current density (J(SC)) . Open-circuit photovoltage decay measurements also show that the electron lifetime (τ(n)) in the ZnO/ZnS core/shell nanostructures can be significantly prolonged because of the lower surface trap density in the ZnO after ZnS coating. For the ZnO/ZnS core/shell nanostructures, the J(SC) and η can reach a maximum of 8.38 mA/cm(2) and 1.92% after 6 h conversion time, corresponding to 12- and 16-fold increments of as-synthesized ZnO, respectively.

Zn-catalysed growth and optical properties of modulated ZnO hierarchical nanostructures

Modulated ZnO hierarchical nanostructures have been successfully synthesised by the one-step thermal evaporation method. The ZnO hierarchical nanostructures consist of large quantities of high-dense nanowires strewn with some small balls, and these balls are connected with wires by short rods. The composition detection results show that the ball is metallic Zn, which further confirms that Zn can serve as the catalyst for vapour–liquid–solid growth of the ZnO hierarchical nanostructures. The photoluminescence spectrum of the modulated ZnO hierarchical nanostructures includes a weak ultraviolet peak centred at 380 nm and a strong green emission centred at 500 nm, which can be attributed to the exciton emission at the near-band edge and a mass of singly ionised oxygen vacancies in products, respectively.