用严格耦合波分析方法研究超薄非晶硅太阳能电池的性能

IF 2.4 Q3 ENERGY & FUELS
R. S. Dubey, S. Saravanan
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引用次数: 0

摘要

与全球能源需求和环境安全以及健康危机有关的问题是人类面临的一些主要挑战,这些挑战使我们能够产生新的无污染和可持续的能源。为此,光学功能纳米结构可以在纳米级水平上被限制的光操纵。这些特性是太阳能转换的新兴和领先的候选者。光子(电介质)和等离子体(金属)纳米结构的结合是太阳能电池中更好光学性能的发展原因。在这里,增强薄有源区内的光捕获是主要目标。本文采用严格耦合波分析(RCWA)方法,研究了超薄非晶硅(a-Si)太阳能电池中正面ITO(矩形)和背面Ag(三角形)纳米光栅的影响。通过添加单纳米光栅和双纳米光栅结构,证明了光吸收、散射(大角度)、衍射和场分布(TE/TM)的改善。值得注意的是,等离子体(贵金属)纳米光栅位于单元结构的底部,作为背面反射器,这有助于全向反射,并由于增强了电荷载流子的收集而增加了光子的路径长度(寿命)。此外,所提出的太阳能电池结构已经与基于背面Ag、正面ITO和双纳米光栅的超薄膜非晶硅太阳能电池进行了优化和比较。最后,在光子和等离子体模式的帮助下证明了所获得的结果,并通过(双)电池结构的集成在50nm薄有源层中实现了23.82mA/cm2(TE)和22.75mA/cm2(TM)的最高电流密度(Jsc)
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ultrathin Film Amorphous Silicon Solar Cell Performance using Rigorous Coupled Wave Analysis Method
The issues related to global energy needs and environmental safeties as well as health crisis are some of the major challenges faced by the human, which make us to generate new pollution-free and sustainable energy sources. For that the optical functional nanostructures can be manipulated the confined light at the nanoscale level. These characteristics are emerging and leading candidate for the solar energy conversion. The combination of photonic (dielectric) and plasmonic (metallic) nanostructures are responsible for the development of better optical performance in solar cells. Here, the enhancement of light trapping within the thin active region is the primary goal. In this work, we have studied the influence of front-ITO (rectangular) and back-Ag (triangular) nanogratings were incorporated with ultrathin film amorphous silicon (a-Si) solar cell by using rigorous coupled wave analysis (RCWA) method. The improvement of light absorption, scattering (large angle), diffraction and field distributions (TE/TM) were demonstrated by the addition of single and dual nanogratings structures. Significantly, the plasmonic (noble metal) nanogratings are located at the bottom of the cell structure as a backside reflector which is helpful for the omni-directional reflection and increased the path length (life time) of the photons due to that the collection of the charge carriers were enhanced. Further, the proposed solar cell structure has optimized and compared to a back-Ag, front-ITO and dual nanogratings based ultrathin film amorphous silicon solar cell. Finally, the obtained results were evidenced for the assistance of photonic and plasmonic modes and achieved the highest current density (Jsc) of 23.82 mA/cm2(TE) and 22.75 mA/cm2 (TM) with in 50 nm thin active layers by integration of (dual) cell structures
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来源期刊
CiteScore
4.50
自引率
16.00%
发文量
83
审稿时长
8 weeks
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