ETL engineering in lead-free new Ca3PBr3 perovskite type structure of anti-perovskite derivative material for stable and effective photovoltaic solar cells
Md. Hafizur Rahman, Hosnaara Full, Md. Azizur Rahman, Sheikh Rashel Al Ahmed, Lamia Ben Farhat, Safa Ezzine and Md. Ferdous Rahman
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Abstract
This study explores the structural, electronic, mechanical, optical, and photovoltaic properties of the Ca3PBr3 anti-perovskite derivative material using DFT and SCAPS-1D simulations. The results confirm its high stability through tolerance factor and phonon dispersion analysis, further supported by mechanical stability studies. Bandgap calculations reveal a direct bandgap of 1.65 eV (PBE) and 2.63 eV (HSE) at the Γ-point, indicating semiconducting behavior. Optical analysis highlights strong absorption in the visible to ultraviolet range, as shown by its dielectric functions, absorption coefficients, and conductivity. SCAPS-1D modeling assessed solar cell performance with ETLs such as WS2, CdS, TiO2, and ZnS, optimizing parameters like absorber thickness, acceptor density, defect density, QE, and J–V characteristics. Under optimal conditions, FTO/ETL (WS2, CdS, TiO2, ZnS)/Ca3PBr3/Au devices achieved efficiencies of 19.39%, 18.69%, 17.21%, and 17.46%, respectively. The study highlights WS2 as a promising ETL for designing efficient and durable Ca3PBr3-based solar cells.
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