Synergistically improved photovoltaic performances of dye-sensitized solar cells with metal-free organic cosensitizer and hybrid rGO-TiO2 photoanode

The photovoltaic performances of the dye-sensitized solar cells were considerably improved via comprising the device structure with the metal-free organic dye cosensitizer and the hybrid photoanode. The cosensitizer was composed of Eosin Y and Coumarin (EY-CM) dyes, and the hybrid photoanode was constructed with the reduced graphene oxide-anchored titanium dioxide (rGO-TiO2) nanocomposites. Due to the aggregation of highly conductive rGO with semiconductive TiO2, the nanocomposites exhibited the decreased interfacial resistance; hence, the electron transport could be improved in the solid-state medium of the photoanode. Meanwhile, the cosensitization of EY-CM dyes could give rise to the increased photon absorbance at the wide spectral range; and their energy level alignment with rGO-TiO2 could lead to the enhanced hopping conduction of the photo -generated electrons. Furthermore, the configuration of rGO-TiO2/EY-CM allowed us to increase the electron injection lifetime, which could reduce the photocarrier recombination at the photoanode/sensitizer interface. Owing to the synergetic effects from both the rGO-TiO2 hybrid photoanode and the EY-CM cosensitizer, the fabricated dye-sensitized solar cell eventually showed the increased power conversion efficiency up to-6.14% under 1-Sun illumination with 100 mW/cm2.

Automated summary

The photovoltaic performances of dye-sensitized solar cells were greatly enhanced by incorporating metal-free organic dye cosensitizers and hybrid photoanodes. The hybrid photoanodes, made of reduced graphene oxide-anchored titanium dioxide nanocomposites, exhibited reduced interfacial resistance and improved electron transport. The cosensitization of Eosin Y and Coumarin dyes increased photon absorbance and enhanced hopping conduction of photo-generated electrons. The configuration of the hybrid photoanodes and cosensitizers increased electron injection lifetime and reduced photocarrier recombination, resulting in an increased power conversion efficiency of 6.14% under 1-Sun illumination.