This paper reports the spectroscopic and electrochemical characterization of two π extended D A π A organic dyes, G1 and G2, along with a comparison with their donor free congeners, DTB T and DTB B. A collection of measurements has been carried out to provide insight into the different processes (injection, regeneration, and recombination) involved in the photovoltaic conversion. The study aims, in particular, at rationalizing how the presence of a bulky triarylamine donor group, along with the modification in the chemical structure of the π bridge, influences the operative cycle of dye sensitized solar cells. We demonstrated that the donor group contributes to the formation of a more robust organic layer uniformly covering the TiO2 surface, thus decreasing unfavorable charge recombination processes. In addition, the presence of the thiophene sulfur atom in one of the dye π extensions (G1), by favoring interactions with the triiodide in the electrolyte, triggers detrimental recombination pathways. We conclude from these observations that G2, the sensitizer with a non thiophene π extension, possesses the highest photovoltaic performances among the investigated sensitizers.
Beneficial Role of a Bulky Donor Moiety in π-Extended Organic Dyes for Mesoscopic TiO2 Sensitized Solar Cells
LISTORTI ANDREA;
2015-01-01
Abstract
This paper reports the spectroscopic and electrochemical characterization of two π extended D A π A organic dyes, G1 and G2, along with a comparison with their donor free congeners, DTB T and DTB B. A collection of measurements has been carried out to provide insight into the different processes (injection, regeneration, and recombination) involved in the photovoltaic conversion. The study aims, in particular, at rationalizing how the presence of a bulky triarylamine donor group, along with the modification in the chemical structure of the π bridge, influences the operative cycle of dye sensitized solar cells. We demonstrated that the donor group contributes to the formation of a more robust organic layer uniformly covering the TiO2 surface, thus decreasing unfavorable charge recombination processes. In addition, the presence of the thiophene sulfur atom in one of the dye π extensions (G1), by favoring interactions with the triiodide in the electrolyte, triggers detrimental recombination pathways. We conclude from these observations that G2, the sensitizer with a non thiophene π extension, possesses the highest photovoltaic performances among the investigated sensitizers.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.