Simulation and Analysis of Methylammonium Lead Iodide (CH_3NH_3PbI_3) Perovskite Solar Cell with Au Contact Using SCAPS 1D Simulator

摘要

Hybrid organic-inorganic perovskite solar cells have attracted the attention of researchers and scientists throughout the world. From 2009, when actual research work began on photovoltaic perovskite applications, a lab power conversion efficiency above 23.3% have been achieved. Whereas, silicon solar cells have only achieved power conversion efficiencies around 17.5% in both residential and commercial applications. A typical perovskite solar cell consists of 6 main layers of different materials: a glass layer, a thin layer of fluorine-doped tin oxide substrate (FTO), an electron transport layer of TiO_2, a perovskite active layer known as methylammonium lead iodide (CH_3NH_3PbI_3), a hole transport layer of Spiro-Ometad, and a gold (Au) electrode. This paper summarizes the research that focused on the selective use of the perovskite solar cell's composite materials, specifically, the Spiro-Ometad layer, the methylammonium lead iodide layer (CH_3NH_3PbI_3), and the TiO_2 layer with a variation of the thickness of the perovskite layer. Initial simulation results show a power conversion efficiency of 20.34% when using a gold (Au) electrode. Further research is needed, in which new technology for device fabrication will create homogeneous thin-film layers that will be tested for increased efficiency.