Size and shape fine-tuning of SnO2 nanoparticles for highly efficient and stable dye-sensitized solar cells

Innovative solution routes led to two types of tin dioxide nanocrystals, i.e. 10-15 nm spheroid cassiterite nanoparticles and 50-150 nm anisotropic cassiterite particles showing octahedral facets. Nanoporous SnO2 electrodes of various architectures (mono- or bilayered) were then processed by the screen-printing method using suitable combinations of these SnO2 particles; the final texture, composition and morphology of the photoanodes obtained depending upon the nature of the post-treatment (with or without TiCl4). After sensitization by the ruthenium dye N719, ATR-FTIR studies revealed that chemisorption of the dye onto porous cassiterite SnO2 layers took place through a bridging coordination mode. As-prepared dye-sensitized photoanodes, when embedded in DSC devices containing a liquid electrolyte, led to a record overall power conversion efficiency (PCE) of 3.2% for pure SnO2 composed of both kinds of particles and to very promising PCE above 4% for photoanodes post-treated with TiCl4. The remarkable photovoltaic performances of the photoanodes including both kinds of particles, associated or not with a TiCl4 post-treatment, were due to improved V-oc and FF, and were related to: (i) lower charge transfer resistance at the SnO2-N719-electrolyte interface; (ii) onset of dark current occurring at higher potential; (iii) enhanced electron lifetimes as determined by transient V-oc decay measurements. Finally, the most striking feature of this study concerns the improvement of the power conversion efficiency upon aging under ambient conditions and the amazing long-term stability of DSCs fabricated from different SnO2-based photoanodes since standard devices built from N719 dye and I-3(-)/I- electrolytes usually show fast decrease of efficiency.