Study of the photovoltaic properties of Cs and Cl co-doped FAPbI 3 based on first principles

Abstract

Abstract Formamidine lead iodide chalcogenide (FAPbI3) is often used as a light-absorbing layer in solar cells to alleviate the energy crisis because of its own good photovoltaic properties.however, the lack of stability is also an obstacle to the current development. It has been found that doping with different kinds of elements at different sites can enhance its stability and improve the photoelectric conversion efficiency of solar cells. In this paper, the geometry, electronic structure and optical properties of FA1 − xCsxPbI3−yCly were calculated using Cs and Cl co-doped with FAPbI3 using the first nature principle. The analysis revealed that the Goldschmidt factors of the doped system were between 0.962 and 0.974, indicating that the system could maintain a stable chalcogenide structure, and the doped system had lower energy and more stable structure. By calculating the energy bands, it is found that the doped ions have a more pronounced effect on the increase of the dispersion at the bottom of the conduction band than the decrease of the dispersion at the top of the valence band of the system, and the reduction of the effective mass of carriers is more favorable for transport. As for the optical properties, the right amount of doping is favorable to the improvement of light absorption, while the excess doping shortens the light absorption range and weakens the light absorption effect, in which FA0.875Cs0.125PbI2.958Cl0.125 has the largest light absorption coefficient. It is shown that the photoelectric properties of chalcogenide FAPbI3 can be effectively modulated by the co-doping of Cs and Cl, which can provide theoretical reference for the precise preparation of more efficient solar cells experimentally.