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Computational modelling and photovoltaic performance evaluation of various ETL/HTL engineered MASnI3 planar perovskite solar cell architectures using SCAPS-1D

S. Vaishnavi, G. Seetharaman

2025Energy Conversion and Management22 citationsDOIOpen Access PDF

Abstract

Perovskite solar cells (PSCs) are the cutting-edge photovoltaic technology heading towards commercialization. To deal with the trade-off between efficiency and sustainability, this report outlines the utilisation of solar cell capacitance simulator (SCAPS-1D) software to design methyl ammonium tin iodide (MASnI 3 ) intrinsic absorber based planar PSC having engineered with novel charge transport materials. To outperform the conventional TiO 2 /MASnI 3 /Spiro-OMeTAD PSC, three electron transport materials (ETMs) and six hole transport materials (HTMs) were employed. Twenty-one PSCs were configured, whose efficiencies vary between 14.28% and 24.28%. Notably, this is the first research to showcase the multifunctional perovskite oxide Barium titanate (BaTiO 3 ) as a viable ETM in MASnI 3 PSC. To comprehend the drift–diffusion characteristics, the crucial factors such as band offset, layer thickness, doping concentration, diffusion length, quantum efficiency, built-in-potential, current density–voltage (J-V) profile, Mott-Schottky, impedance and, dark J-V characteristics were systematically analysed. It is believed that, an excellent dielectric constant, good adhesion, high recombination resistance and strong electric field at BaTiO 3 /MASnI 3 interface ameliorate the fill factor, efficiency and, output power. Meanwhile, the activation energy of HTMs were evaluated and found CuO, MASnBr 3 to be distinct. Further, the impact of temperature, back contact, series (R s ) and shunt (R sh ) resistances, for the best PSC configurations were assessed. The proposed PSC architectures FTO/BaTiO 3 /MASnI 3 /CuO/Au and FTO/BaTiO 3 /MASnI 3 /MASnBr 3 /Au are thermally stable and exhibit a balanced interplay of R s and R sh leading to phenomenal efficiencies of 24.28% and 24.09% respectively. These research findings will enable the fabrication of lab-scale PSCs, and pave the way to large-scale implementation in the future.

Topics & Concepts

Photovoltaic systemPlanarPerovskite (structure)Materials scienceSolar cellOptoelectronicsPhotovoltaicsEngineering physicsElectronic engineeringComputer scienceEngineeringElectrical engineeringChemical engineeringComputer graphics (images)Perovskite Materials and ApplicationsConducting polymers and applicationsChalcogenide Semiconductor Thin Films
Computational modelling and photovoltaic performance evaluation of various ETL/HTL engineered MASnI3 planar perovskite solar cell architectures using SCAPS-1D | Litcius