This may be the reason behind the low cell performance. Figure 8 Photocurrent density-voltage curves of selenium solar cells with various H 2 SeO 3 concentrations. The annotation selleck chemical numbers in Figure 8 suggest the H2SeO3 concentrations. Conclusion 3-D selenium ETA solar cells using an extremely thin absorber Se layer on nanocrystalline TiO2 electrodes were fabricated by electrochemical deposition method. The crystallinity of the selenium layer after annealing at 200°C for 3 min in the air was significantly improved, and the band gap became narrower in comparison to the sample both with and without annealing at 100°C. The photovoltaic performance features of the best 3-D selenium ETA solar cells are J SC = 8.7 mA/cm2, V
www.selleckchem.com/p38-MAPK.html OC = 0.65 V, FF = 0.53, and η = 3.0%. These results are interesting for PV researchers because the fabrication method for this kind of solar cells is quite simple. However, in order to get a higher efficiency, the photocurrent density should be more improved. Acknowledgment Part of this work was funded by the Innovative Solar Cells Vorinostat concentration Project (NEDO, Japan). References 1. Nanu M, Schoonman
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