Affiliation:
1. Advanced Energy Materials and Solar Cell Research Laboratory Department of Electrical and Electronic Engineering Begum Rokeya University Rangpur 5400 Bangladesh
2. Department of Electrical and Electronic Engineering Bangamata Sheikh Fojilatunnesa Mujib Science & Technology University Jamalpur 2012 Bangladesh
3. Department of Chemistry College of Science King Khalid University Abha 61413 Saudi Arabia
4. Department of Physics College of Science University of Bisha Bisha 61922 Saudi Arabia
5. Department of Physics Pabna University of Science and Technology Pabna 6600 Bangladesh
6. Palestinian Ministry of Education and Higher Education Nablus P4060334 Palestine
Abstract
AbstractThe inimitable structural, electronic, and optical properties of inorganic cubic rubidium‐lead‐halide perovskite have obtained significant attention. In this research, novel rubidium‐lead‐iodide (RbPbI3)‐based perovskite solar cells incorporating Tin Sulfide (SnS2) is investigated as an efficient buffer layer, utilizing both Density Functional Theory (DFT) calculations and SCAPS‐1D simulator. Primarily, DFT is used to compute the bandgap, partial density of states (PDOS), and optical properties of the RbPbI3 absorber, which are then applied in the SCAPS‐1D simulator. An optimized Al/FTO/SnS2/RbPbI3/Au device is systematically studied. Additionally, the effect of various influencing factors are investigated such as layer bulk defect density, interface defect density, doping concentration, and thickness. The highest power conversion efficiency (PCE) of 31.11% is achieved for the SnS2 Electron Transport Layer (ETL), with a JSC of 32.47 mA cm−2, VOC of 1.10 V, and FF of 87.14% for the Al/FTO/SnS2/RbPbI3/Au structure. Characteristics of quantum efficiency (QE) are also analyzed. Therefore, SnS2 ETL demonstrates the robust potential for utilization in high‐performance photovoltaic cells based on RbPbI3 perovskite.
Funder
Deanship of Scientific Research, King Khalid University