To improve the performance of sensitized solar cells, we propose the waveguide-type sensitized solar cell based on sputtered oxide semiconductor thin films. Here, guided lights in the thin films are used to generate photocurrents instead of normally-incident lights. In this configuration the lights pass through a substantial number of dye molecules to enhance the light absorption.
We also propose integrated sensitized solar cell films, in which the waveguide-type sensitized solar cells are embedded in a light beam collecting film consisting of two stacked films; a film with tapered vertical waveguides and a film with planar waveguides having vertical mirrors. Incident lights are collected by the waveguides, and are guided to the solar cells. Expected advantages are as follows; reduction of semiconductor consumption, availability of optical circuit functions, and light-weight and flexible characteristics.
We previously succeeded in dye sensitization of vacuum-evaporated ZnO films by the liquid-phase molecular layer deposition (LP-MLD). To improve the film quality, we attempt to replace the ZnO films with sputtered films. Two sensitization processes are investigated for the sputtered ZnO thin films; (a) by a multi-dye stacked structure grown using LP-MLD and (b) by a ZnO/Cr₂O₃ multi-layer, which is regarded as a multiple quantum wells with different well widths. These structures are expected to widen the photocurrent spectra. For experimental results, they will be presented in the conference presentation.