Performance Enhancement of PbS‐TBAI Quantum Dot Solar Cell with MoTe2 as Hole Transport Layer

Jyoti Singh, Sachin Singh, V. Srivastava, Sadanand, R. Yadav, P. Lohia, D. K. Dwivedi
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引用次数: 7

Abstract

Novel solar power technologies are constantly evolving and improving, and this is seen as a potential way to meet the increasing demand for electricity and energy on a global scale. Quantum dot solar cells (QDSCs) are one of the most optimistic third‐generation solar cells. Because of the superior qualities, such as its size, tuneable bandgap, high stability, and extremely low cost, quantum dots (QDs) have drawn a lot of attention in photovoltaic applications for highly effective solar cells. Herein, WO3 is utilized as the electron transport layer (ETL), MoTe2 as the hole transport layer (HTL), and lead sulfate treated with tetrabutylammonium iodide (PbS‐TBAI) as the QD absorber layer. Overall optimization still represents an obstacle to raise the efficiency of QDSC. Temperature, series–shunt resistance, and absorber layer thickness are optimized, and further analysis is done for overall optimization on the contour plot of electron affinities of HTL and ETL. For all aspects of simulation work, the SCAPS‐1D simulator program is employed. Fill factor 85.96%, open‐circuit voltage 923.7 mV, short‐circuit density 38.61 mA cm−2, and power conversion efficiency 30.66% are the values of the optimized performance parameters. The improved high efficiency of the proposed device can pave for the fabrication of QDSC.
以MoTe2作为空穴传输层对PbS - TBAI量子点太阳能电池性能的增强
新型太阳能发电技术正在不断发展和改进,这被视为满足全球范围内日益增长的电力和能源需求的潜在途径。量子点太阳能电池(Quantum dot solar cells, qdsc)是目前最具前景的第三代太阳能电池之一。由于量子点具有体积小、带隙可调、稳定性高、成本极低等优点,在高效太阳能电池的光伏应用中受到了广泛的关注。本文采用WO3作为电子输运层(ETL), MoTe2作为空穴输运层(HTL),经四丁基碘化铵(PbS‐TBAI)处理的硫酸铅作为QD吸收层。整体优化仍然是提高QDSC效率的障碍。对温度、串并联电阻、吸收层厚度进行了优化,并对HTL和ETL的电子亲和线图进行了整体优化分析。对于仿真工作的各个方面,采用了SCAPS‐1D模拟器程序。优化后的性能参数为:填充系数85.96%,开路电压923.7 mV,短路密度38.61 mA cm−2,功率转换效率30.66%。提高了器件的高效率,为QDSC的制备奠定了基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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