Abstract Composition dependent band gap engineering enables the ternary CdS1-xSex quantum dot to be a promising candidate for quantum dot solar cell (QDSCs). Up to date, using precursor containing Cd2+, S2− and Se2−, the hot-injection solvothermal synthesis, the successive ion layer absorption and reaction, and the chemical bath deposition methods, have been developed to prepare the CdS1-xSex QDs. However, it is difficult for these processes to accurately control the CdS1-xSex QDs synthesis. Ion exchange, as a secondary transformation synthesis method, provides a new pathway to design complex nanostructures. In the present study, a series of CdS1-xSex QD-sensitized mesoporous TiO2 films with controlled composition and light harvesting were synthesized using a hydrothermal anion exchange reaction (HAER) method. The composition stoichiometry of CdS1-xSex QDs together with their band gaps in the range of 550–750 nm, were easily controlled by simply tuning the HAER temperature and time duration, while maintaining a similar morphology and crystal structure. Using these CdS1-xSex QD-sensitized TiO2 films as photoanodes for solar cells, a high power conversion efficiency of 4.03% based on CdS0.75Se0.25 QDs was achieved under simulated AM1.5 100 mW cm−2 illumination.

Load

Load