Design and simulation of efficient tin based perovskite solar cells through optimization of selective layers: Theoretical insights

Within a decade, Perovskite solar cells (PSCs) have attained an efficiency of 25.8%. PSCs lack commercialization due to two main factors: (i) poor device stability (ii) toxicity. The tin (Sn) is a possible candidate to substitute toxic lead (Pb) in traditional PSCs; however, the performance of Sn-ba...

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Bibliographic Details
Published in:Optical materials 2022-03, Vol.125, p.112057, Article 112057
Main Authors: Roy, Priyanka, Raoui, Yassine, Khare, Ayush
Format: Article
Language:English
Subjects:
Barrier height
Defect density
HTMs
MASnI3
Perovskite solar cells
SCAPS
Thickness
VBO
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Summary:Within a decade, Perovskite solar cells (PSCs) have attained an efficiency of 25.8%. PSCs lack commercialization due to two main factors: (i) poor device stability (ii) toxicity. The tin (Sn) is a possible candidate to substitute toxic lead (Pb) in traditional PSCs; however, the performance of Sn-based PSCs is 13%, much lower than Pb-based PSCs due to several aspects. In this work, we have used drift-diffusion simulation to propose a pathway to improve the performance of lead-free PSCs using MASnI3 as a light harvester. The conventional charge selective layer, such as TiO2, requires high-temperature processing, which also is a major concern. As reported earlier, traditional transport layers contribute actively to the degradation of PSCs, affecting their stability. Therefore, we have used ZnO nanoparticles (NP) as electron transport material (ETM), and conducted an analysis using various organic and inorganic hole transport materials (HTMs) with spike and cliff structures. The impact of HTM thickness on the performance parameters of MASnI3 based PSCs with constant and variable charge acceptor concentrations was investigated. This work indicates that organic HTMs exhibit more thickness-dependent behavior than inorganic HTM for MASnI3 based PSCs. Furthermore, the suitable valence band offset (VBO) and barrier height at Perovskite/HTM and HTM/Back contact interfaces were studied for efficient energy level mismatch with absorber layer to boost the performance of MASnI3 based PSCs. The concept of selecting back contact for Sn-based PSCs using different HTMs was analyzed. The influence of temperature variation on the performance of PSCs using different HTM was analyzed. The hybrid configuration devices face the issue of interfacial recombination; thus, the impact of defect density at the HTM/MASnI3 interface on the performance of PSCs with various HTMs was investigated. Lastly, MASnI3 based PSC showed a power conversion efficiency (PCE) of 23.51% using the unmodified CuSCN based HTM and, CuI can also deliver an efficiency of 23.31% employed modified valence band energy level. [Display omitted] •Lead-free PSC has been numerically simulated using SCAPS software.•Organic HTMs are highly sensitive to thickness variation compared to inorganic HTMs.•The optimized VBO, barrier height, and back contact have been calculated.•The optimized Spike-type at the Perovskite/HTM interface is highly desired for efficient MASnI3 based PSCs.•MASnI3 based PSCs show a PCE of 23.51% an
ISSN:0925-3467
1873-1252
DOI:10.1016/j.optmat.2022.112057