Enhancing the performance of lead-free CsInCl3 perovskite solar cells with Ag and Au plasmonic nanoparticles: A DFT and SCAPS-1D analysis
Muhammad Zulqarnain Abbasi, Anees Ur Rehman, Muhammad Sheraz, Wajahat Ullah Khan Tareen, Muhammad Kaleem, Shayan Tariq Jan, Ali Haider, Teong Chee Chuah
Abstract
• First-principles Density Functional Theory (DFT) calculations and SCAPS-1D simulations were conducted to analyze electronic, optical, and structural properties of CsInCl₃ perovskite solar cells. • Ag and Au plasmonic nanoparticles were introduced at the indium site, leading to a bandgap reduction from 1.632 eV (pure) to 1.404 eV (Ag-doped) and 1.10 eV (Au-doped). • Static refractive index increased from 1.96 (pure) to 2.04 (Ag-doped) and 2.17 (Au-doped), enhancing the optical response. • SCAPS-1D simulations demonstrated an increase in power conversion efficiency (PCE) from ∼17.1 % (pure CsInCl₃) to ∼25.5 % (Ag and Au-doped CsInCl₃). • Findings highlight the potential of Ag and Au doping in tuning CsInCl₃ for high-performance, non-toxic perovskite solar cells. The search for non-toxic, high-efficiency perovskites has driven the development of innovative material engineering strategies. Due to the toxic nature of lead (Pb), extensive research has been conducted to identify alternative solutions. While these alternatives show outstanding potential, they have yet to match the performance levels of MAPbI 3 . This study presents a novel method to improve both the electrical and optical properties of CsInCl 3 perovskite by adding Ag and Au plasmonic nanoparticles for the first time. We carefully examined the electronic, optoelectronic, and structural properties of doped CsInCl 3 using first-principles Density Functional Theory (DFT) calculations and SCAPS-1D simulations. We computed all properties using the GGA-PBE exchange-correlation functional and USP (ultrasoft pseudo-potential). When Ag and Au were added to the indium site, the band gap decreased from 1.632 eV (pure) to 1.404 eV Ag-doped and 1.10 eV Au-doped. Optical properties, calculated across the photon energy range of 0–20 eV, revealed a redshift in the absorption edge for Ag-doped CsInCl 3 , while Au-doped CsInCl 3 retained a similar absorption profile to the pure compound. The static refractive index increased from 1.96 for pure CsInCl 3 to 2.04 and 2.17 for Ag and Au-doped compounds, respectively, indicating improved optical response. The combined effects of engineered absorption and doping on electrical solar cell parameters were investigated using SCAPS-1D simulations, achieving a power conversion efficiency (PCE) of ∼25.5 %, significantly higher than the ∼17.1 % observed for pure CsInCl 3 perovskite material. These findings underscore the transformative potential of Ag and Au doping in tailoring CsInCl 3 for high-performance optoelectronic and photovoltaic applications, marking a significant step toward the development of next-generation, non-toxic perovskite solar cells.