1. Multi-core cable-like TiO2nanofibrous membranes for dye-sensitized solar cells
- Author
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Bin Ding, Takayuki Naka, Seimei Shiratori, Hiroshi Kokubo, and Hiroki Tsuchihira
- Subjects
Photocurrent ,Materials science ,Polyvinyl acetate ,Mechanical Engineering ,Energy conversion efficiency ,Bioengineering ,General Chemistry ,Hot pressing ,chemistry.chemical_compound ,Dye-sensitized solar cell ,Membrane ,chemistry ,Mechanics of Materials ,Specific surface area ,Electrode ,General Materials Science ,Electrical and Electronic Engineering ,Composite material - Abstract
Multi-core cable-like TiO2 nanofibres were fabricated by calcination of composite polyvinyl acetate (PVAc)/titania nanofibres with a hot pressing pre-treatment. This resultant novel fibre structure was composed of sheaths of 200?nm in diameter and 25?nm in wall thickness, and cores filled with 24?nm thick TiO2 fibrils. The formation of multi-core cable-like structures of fibres is considered to be due to the enhanced phase separation of PVAc-rich and TiO2-rich phases during the hot pressing process. The BET results showed that the specific surface area of pressed TiO2 membranes was much higher than that of unpressed TiO2 membranes. In this study, the novel multi-core cable-like TiO2 fibrous membranes were used as electrode materials for dye-sensitized solar cells (DSSCs). It was observed that the photocurrent and conversion efficiency of the electrodes increased concurrently with increasing applied pressure and average membrane thickness in the range of 1?9??m. The maximum short circuit photocurrent and energy conversion efficiency were 16.09?mA?cm?2 and 5.77% when the membrane had an average thickness of 9.21??m and 8?MPa applied pressure.
- Published
- 2007
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