有机和无机 Perovskite 太阳能电池电荷传输层制备技术综述

A. S. Yusuf, A. Ramalan, A. A. Abubakar
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引用次数: 0

摘要

有机和无机过氧化物太阳能电池中电荷传输层的奇妙行为激发了半导体二氧化锰纳米粒子(PSC)设计者的兴趣。本研究的目的是探讨在 PSC 中用作电荷传输层的二氧化锡薄膜的几种制造技术。为了理解纳米结构二氧化锡薄膜的属性与太阳能电池效率之间的联系,本研究特别关注二氧化锡薄膜的生产和特性。通过对二氧化锡组成的纳米胶体进行表面改性而产生的二氧化锡纳米流体的旋涂沉积一直是获得二氧化锡层的关键技术之一。另据报道,使用锡(IV)盐制备二氧化锡纳米粒子可获得高质量的二氧化锡薄膜。许多 PSC 论文[1]都声称光电转换效率约为 25.5%。采用二氧化锡材料的一个好处是,它们的导电率大大高于二氧化钛。这项工作还讨论了 SnO2 纳米粒子的生产,这是生成 SnO2 电荷传输材料的另一种方法,可通过称为锡(IV)的冷冻干燥前体过程来实现。二氧化锡晶体可在低至 700 摄氏度的温度下形成。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Review on Preparation Techniques of Charge Transport Layer for Organic and Inorganic Perovskite Solar Cells
The fascinating behavior of charge transport layer in organic and inorganic perovskite solar cells has piqued the interest of designers of semiconductor SnO2 nanoparticles (PSC). The goal of this research is to look at several techniques for manufacturing SnO2 films for use as charge transport layers in PSC. To comprehend the link between the attribute of nanostructured SnO2 films and the efficiency of solar cells, special attention is devoted to the production and properties of the SnO2 thin films. The spin-coating deposition of SnO2 nano fluids generated via surface modification of nano-colloids composed of SnO2 has been one of the key techniques for obtaining SnO2 layers. It has also been reported that preparing SnO2 nanoparticles using Tin (IV) salts results in a high-quality SnO2 film. Light-to-electricity conversion efficiency of about 25.5% has been claimed in many PSC papers [1]. One benefit of adopting SnO2 materials is that they have substantially greater conductivity than TiO2. This work also discusses the production of SnO2 nanoparticles, a different method of generating SnO2 charge transport materials that may be accomplished by the process of freeze-drying precursors known as Tin (IV). SnO2 crystal formation may be regulated at temperatures as low as 700C.
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