Fluorine ion induced phase evolution of tin-based perovskite thin films: structure and properties

To study the effect of fluorine ions on the phase transformation of a tin-based perovskite, CsSnI(3−x)(F)(x) films were deposited by using thermal vacuum evaporation from a mixed powder of SnI(2), SnF(2) and CsI, followed by rapid vacuum annealing. The color evolution, structure, and properties of CsSnI(3−x)F(x) films aged in air were observed and analyzed. The results showed that the colors of the films changed from black to yellow, and finally presented as black again over time; the unstable B-γ-CsSnI(3−x)F(x) phase transformed into the Y-CsSnI(3−x)F(x) phase, which is then recombined into the Cs(2)SnI(6−x)F(x) phase with the generation of SnO(2) in air. Fluorine dopant inhibited the oxidation process. The postponement of the phase transformation is due to the stronger bonds between F and Sn than that between I and Sn. The color changing process of the CsSnI(3−x)F(x) films slowed that the hole concentrations increased and the resistivities decreased with the increase of the F dopant ratio. With the addition of SnF(2), light harvesting within the visible light region was significantly enhanced. Comparison of the optical and electrical properties of the fresh annealed CsSnI(3−x)F(x) films showed that the band gaps of the aged films widened, the hole concentrations kept the same order, the hole mobilities reduced and therefore, the resistivities increased. The double layer Cs(2)SnI(6−x)F(x) phase also showed ‘p’ type semi-conductor properties, which might be due to the incomplete transition of Sn(2+) to Sn(4+), i.e. Sn(2+) provides holes as the acceptor.