ausblenden:
Schlagwörter:
SENSITIZED SOLAR-CELLS; TRANSMISSION ELECTRON-MICROSCOPY; ENHANCED
PHOTOCATALYTIC ACTIVITY; TRANSITION-METAL OXIDES; LITHIUM ION BATTERIES;
ENERGY-LOSS; 3-DIMENSIONAL RECONSTRUCTION; REFLECTION SPECTROSCOPY;
INFRARED-SPECTROSCOPY; NANOROD ARRAYS;
Zusammenfassung:
Titanium dioxide nanowire (NW) arrays are incorporated in many devices for energy conversion, energy storage, and catalysis. A common approach to fabricate these NWs is based on hydrothermal synthesis strategies. A drawback of this low-temperature method is that the NWs have a high density of defects, such as stacking faults, dislocations; and oxygen vacancies. These defects compromise the performance of devices. Here, we report a postgrowth thermal, annealing procedure to remove these lattice defects and propose a mechanism to explain the underlying changes in the structure of the NWs. A detailed transmission electron microscopy study including in situ observation at elevated temperatures reveals a two-stage process. Additional spectroscopic analyses and X-ray diffraction, experiments clarify the underlying mechanisms. In an early, low-temperature stage, the as-grown mesocrystalline NW converts to a single crystal by the dehydration of surface-bound OH groups. At temperatures above 500 degrees C , condensation of oxygen vacancies takes place, which leads to the fabrication of NWs with internal voids. These voids are faceted and covered with Ti3+-rich amorphous TiOx.