利用基于氮铱的过氧化物提高太阳能电池效率:利用 DFT 和 SETFOS 进行器件优化研究

IF 6 2区 工程技术 Q2 ENERGY & FUELS
Arati Dikhit, Sukanta Kumar Tripathy
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引用次数: 0

摘要

目前,能产生具有适合光伏应用带隙的三维过氧化物的有机阳离子只有甲基铵(MA)和甲脒(FA)。然而,这些过氧化物晶石在高温和潮湿条件下容易降解。多项计算分析发现,氮杂环丁烷(AZ)是合成有机-无机包晶石的第三种有前途的候选物质。要探索以 AZ 为阳离子的过氧化物太阳能电池(PSCs)的运行机制和效率潜力,需要对材料和器件进行全面研究。本研究将 DFT 和 SETFOS 结合起来,研究了基于含 AZ 阳离子的过氧化物的 PSCs。根据 DFT 计算和分析的结果,确定 AZPbI3、AZSnCl3、AZSnBr3 和 AZSnI3 为 AZ(Pb/Sn)X3(X = Cl、Br、I)系列中合适的包晶,因为它们具有有利的容限因子,计算带隙分别为 1.87 eV、1.67 eV、1.1 eV 和 0.8 eV。此外,还使用 SETFOS 对太阳能电池 (SC) 进行了数值模拟,并为每种包晶吸收剂优化了 ETL 和 HTL。此外,还对器件的最佳传输层和吸收层厚度进行了定制。采用 ITO/PCBM/AZPbI3/CFTS/Ag、ITO/IGZO/AZSnCl3/CuI/Ag、ITO/CeO2/AZSnBr3/CuI/Ag 和 ITO/CeO2/AZSnI3/PEDOT:PSS/Ag 结构的优化器件的 PCE 分别达到了 19.48%、26.1%、16.5% 和 12.01%。此外,本研究还考察了量子效率(QE)和温度对光伏性能的影响。这项综合研究的结果为在适当的时候制造高效、稳定的基于 AZ 的 PSC 奠定了坚实的基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Enhancing the solar cell efficiency with Azetidinium based Perovskites: An investigation for device optimization using DFT and SETFOS

Enhancing the solar cell efficiency with Azetidinium based Perovskites: An investigation for device optimization using DFT and SETFOS
Presently, organic cations that yield 3D perovskites with band gaps appropriate for PV applications comprise solely methylammonium (MA) and formamidinium (FA). However, these perovskites are prone to degradation at elevated temperatures and humid conditions. Multiple computational analyses have discovered azetidinium (AZ) as a promising third candidate for the synthesis of organic–inorganic perovskites. Exploring the operational mechanism and efficiency potential of perovskite solar cells (PSCs) based on AZ as cation requires a comprehensive investigation of both the material and device. In this study, DFT and SETFOS are combined to investigate PSCs based on perovskites with AZ cations. The structural, optoelectronic characteristics of the perovskites were computed and analysed based on DFT which identifies AZPbI3, AZSnCl3, AZSnBr3 and AZSnI3 as suitable perovskites within the AZ(Pb/Sn)X3 (X = Cl, Br, I) family based on their favourable tolerance factors and calculated bandgaps of 1.87 eV, 1.67 eV, 1.1 eV and 0.8 eV, respectively. Further, numerical simulation for solar cells (SCs) is executed using SETFOS, with an optimized ETL and HTL for each of the perovskite absorbers. In addition, the devices are also tailored for their best thicknesses of transport layers and absorber layers. The optimized devices with architectures ITO/PCBM/AZPbI3/CFTS/Ag, ITO/IGZO/AZSnCl3/CuI/Ag, ITO/CeO2/AZSnBr3/CuI/Ag and ITO/CeO2/AZSnI3/PEDOT:PSS/Ag achieved PCEs of 19.48 %, 26.1 %, 16.5 %, and 12.01 % respectively. Along with, this study examines quantum efficiency (QE) and the impact of temperature on PV performance. Results of this comprehensive study lay the groundwork for a promising research path towards manufacturing high-efficiency, stable AZ based PSCs in due course.
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来源期刊
Solar Energy
Solar Energy 工程技术-能源与燃料
CiteScore
13.90
自引率
9.00%
发文量
0
审稿时长
47 days
期刊介绍: Solar Energy welcomes manuscripts presenting information not previously published in journals on any aspect of solar energy research, development, application, measurement or policy. The term "solar energy" in this context includes the indirect uses such as wind energy and biomass
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