A Comprehensive Computational Photovoltaic Study of Lead-free Inorganic NaSnCl3-based Perovskite Solar Cell: Effect of Charge Transport Layers and Material Parameters
Abstract
Lead-free all-inorganic halide perovskite solar cells (PSCs) have emerged as a promising alternative to toxic lead-based solar cells and organic solar cells, which have limited stability. This work explores such a PSC with sodium tin chloride (NaSnCl3) as the absorber, due to its significant potential for optoelectronic applications. To investigate this potential, a comprehensive computational analysis of NaSnCl3-based solar cells is performed using the one-dimensional solar cell capacitance simulator (SCAPS -1D). Simulations are performed for device structures with front contact/Indium Tin Oxide (ITO)/electron transport layer (ETL)/NaSnCl3/hole transport layer (HTL)/back contact configuration, where TiO2, SnS2, IGZO, ZnSe, CdS, GaSe, ZnSnN2, WS2, PCBM, STO, and CSTO are utilized as ETLs and CNTS, GO, Mg-CuCrO2, Spiro-OMeTAD, CdTe, GaAs, MoTe2, BaSi2, and P3HT are utilized as HTLs. Based on the obtained power conversion efficiency (PCE), six best ETL-HTL combinations with SnS2, STO, WS2, IGZO, ZnSe and CSTO as ETLs and MoTe2 as HTL are chosen for further analysis. The effects of different material and device parameters, such as thickness and doping density; effective density of states; bulk and interface defects; series and shunt resistance; and operating conditions, such as temperature and light intensity are investigated. Using the optimized material parameters, SnS2 ETL and MoTe2 HTL-based solar cell show the best performance with open circuit voltage, Voc = 1.196V, short circuit current density, Jsc = 35.82 mA/cm2, fill factor, FF = 89.72% and PCE = 38.42%. This detailed study provides valuable insights for the fabrication of high efficiency NaSnCl3-based solar cells.
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