Abstract

The present paper discusses the principle of dye-sensitized solar cells (DSCs) in terms of a new physics-based equivalent circuit model. This model is proposed following analysis by electrochemical impedance spectroscopy of the voltage dependence of the internal resistance elements of DSCs. The influence of these elements upon cell performance in areas such as short circuit current density ( J SC), open circuit voltage ( V OC) and fill factor (FF) was examined based on the equivalent circuit. It was demonstrated that the haze factor of TiO 2 electrodes is a useful index when fabricating light-confined TiO 2 electrodes to improve J SC, and that blocking the TiO 2 surface with molecules is an effective way of reducing interfacial charge recombination at the TiO 2 surface and of improving shunt resistance and V OC. FF was also improved by reduction of the internal series resistance, which is composed of the following three elements: the redox reaction resistance at the platinum counter electrode, the resistance of carrier transport by ions in the electrolyte, and resistance due to the sheet resistance of the transparent conducting oxide. Finally, the highest efficiency scores of 10.4% and 10.8% (aperture illumination area 1.004 cm 2 and 0.2227 cm 2, respectively) were confirmed by a public test center.

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