后表面钝化层厚度对具有平面和散射金属反射器的高效太阳能电池的影响

Yang Yang, H. Mehrvarz, S. Pillai, M. Green, H. Kampwerth, A. Ho-baillie
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引用次数: 1

摘要

太阳能电池后表面反射器的设计是为了使低能量光子在太阳能装置内部经过多次反射才能逃逸,从而提高光的收集能力。本文研究了后表面SiO2钝化层厚度对前平面高效PERT(钝化发射极和后完全扩散)太阳能电池光学和电学性能的影响。制备了两种金属反射器:蒸发铝制备的传统平面反射器和自组装银纳米粒子制备的新型散射反射器。研究发现,在8 nm ~ 134 nm范围内,后置SiO2层厚度对光电流的依赖性表现为平面反射器和散射反射器的不对称性,且在所有SiO2厚度下,散射反射器的性能都明显优于平面反射器。采用134nm SiO2薄膜的平面反射镜最大电流增强幅度为12.1%,采用19nm SiO2薄膜的散射反射镜最大电流增强幅度为18.4%(从波长900 ~ 1200nm计算)。此外,通过增加一个分离的金属反射镜,散射反射镜的最大电流增强跳升至27.0%。计算了有效光程长度Z,研究了两种反射器在不同SiO2厚度下的光捕获(光学性质)。计算扩散长度L来跟踪电性能。结果表明,当使用平面Al反射镜时,较厚的SiO2对光学和电学性能都有好处。然而,对于散射反射器,更薄的SiO2对于光学增强是可取的,而更厚的SiO2对于电增益是可取的。考虑到这两种效应,19 nm SiO2是具有散射反射器的细胞的最佳选择。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The effect of rear surface passivation layer thickness on high efficiency solar cells with planar and scattering metal reflectors
Rear surface reflector of solar cell is designed to improve light collection capacity by allowing the low energy photons to go through multiple bounces inside the solar device before escaping. In this paper, we investigate the thickness effect of rear SiO2 surface passivation layer on both optical and electrical properties of front-planar high efficiency PERT (Passivated Emitter and Rear Totally-Diffused) solar cells. Two kinds of metal reflectors are fabricated: the conventional planar reflectors by evaporated Al and the novel scattering reflectors by self assembled Ag nanoparticles. We find that the thickness dependence of rear SiO2 layer (from 8 nm - 134 nm) on photocurrent shows an asymmetry for planar and scattering reflectors, moreover, the scattering reflectors perform much better than the planar reflectors under all tested SiO2 thicknesses. A maximum current enhancement (calculated from wavelength 900 nm to 1200 nm) of 12.1% is presented for planar reflector with 134 nm SiO2 film, and 18.4% for scattering reflector with the optimized 19 nm rear SiO2 film. Additionally, by adding a detached metal mirror, the maximum current enhancement from scattering reflector jumps to 27.0%. Effective optical path length Z is calculated to study the light trapping (optical properties) under various SiO2 thicknesses for both reflectors. Diffusion length L is calculated to track the electrical performance. It is shown that thicker SiO2 is of benefit for both optical and electrical properties when planar Al reflector is used. However, for scattering reflectors, thinner SiO2 is preferable for optical enhancement, but thicker SiO2 is desirable for electrical gain. 19 nm SiO2 is found to be the best choice for cells with scattering reflectors, considering both effects.
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