Nanoscale Res Lett 2013, 8:158–163.CrossRef Competing interests The authors declare that they have no competing interests. Authors’ contributions MB fabricated all the samples, performed the XRD and transmission measurements, and wrote the manuscript. DW performed the

PL and FESEM measurements. JW participated in the discussion and manuscript CBL0137 ic50 writing. JS and QL contributed in the preparation of some samples. YY, QY, and SJ contributed with valuable discussions. All authors read and approved the final manuscript.”
“Background SIS3 purchase dye-sensitized solar cells (DSSCs) have attracted considerable interests due to their simpler fabrication and low production costs compared with conventional silicon-based solar cells [1, 2]. A traditional DSSC consists of a transparent photoanode with dye-sensitized mesoporous thin-film-like TiO2 or ZnO, I−/I3 − redox electrolyte, and a counter electrode (CE) with a catalytic layer deposited

on FTO substrate. As one of the most check details crucial components of DSSC, the CE works as a catalyst for the reduction of I3 − to I−, and the materials used in catalytic layer and conductive substrates significantly affect the performance and costs of the DSSCs. Platinized FTO is the most common material for CE as it has good conductivity and high catalytic activity. However, noble metal platinum is expensive, scarce, and easy to be eroded by the I−/I3 − electrolyte [3, 4]. Moreover, the Pt catalytic layer is usually prepared by thermal annealing or electrodeposition method, and both methods require high temperature (450°C), which is beyond the sustaining ability of plastic substrates to realize the flexible DSSCs. The common FTO substrates are very expensive and hard, also preventing the production of flexible DSSCs. Therefore, it is imperative to develop Pt- and

FTO-free CEs with low cost and good catalytic activity for DSSCs. Many reported materials have been used as the substitute for Pt-based CEs like conductive polymers (polyaniline [5], ploypyrrole [6], poly(3,4-ethylenedioxy-thiophene) (PEDOT) [7], carbon AMP deaminase materials (graphene [8], carbon black [9], carbon nanotube [10], etc.), and most of them have lower catalytic activity than Pt [11]. In order to achieve a cost-effective Pt-free CE, PEDOT:PSS has attracted much attention because of good catalytic activity, better film-forming property, low cost, and easy coating [12–14]. Modified PEDOT:PSS has potential to replace TCO in organic electronics for its high conductivity [15]. Though with many of strengths, the catalytic ability of DSSC with PEDOT:PSS/FTO CE still exists a distance from Pt/FTO CE and needs to be further improved. Consequently, in this work, a hierarchical TiO2-PEDOT:PSS/PEDOT:PSS/glass CE was used in the fabrication of DSSC. The TiO2-PEDOT:PSS layer was fabricated utilizing the mixture of PEDOT:PSS and TiO2 nanoparticles. The neat PEDOT:PSS layer acts as a high conductive electrode in order to develop charge passageway.