Performance improvement of microcrystalline thin film silicon solar cells by back reflector with high resistivity and low absorption

2011 37th IEEE Photovoltaic Specialists Conference Pub Date : 2011-06-19 DOI:10.1109/PVSC.2011.6186034

S. Kim, H. C. Lee, W. Y. Kim, J. W. Park, J. Chung, S. Ahn, H. Lee

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引用次数: 3

Abstract

In this paper, a series of microcrystalline silicon (μc-Si:H) solar cells were fabricated on different back reflectors by very high frequency plasma enhanced chemical vapor deposition (VHF-PECVD). The results indicated that the performance of μc-Si:H solar cells strongly depended on their back reflector structures. First of all, the various Al:ZnO films with different optical and electrical properties were fabricated, and the effects on the performance of μc-Si:H solar cells as the back reflector materials were investigated. Unlike the previous studies for a-Si:H solar cells, all the μc-Si:H cells with various Al:ZnO back reflectors are showing similar I-V characteristics. However, it was interesting result that the back reflector with highest resistivity, fabricated by oxygen reactive sputtering, showed the best fill factor. As the next step, the n-μc-SiO layer with high resistivity was introduced as the new back reflector materials substituting for the conventional Al:ZnO. The optimal deposition condition for the n-μc-SiO layer was selected considering the low refractive index under 1.85, the reasonable electrical resistivity around 1E+3 Ω·cm and low absorption spectra near IR region. For the new back reflector structures, all the cell parameters were increased drastically at n-μc-SiO thicker than 300 nm, and a conversion efficiency of as high as 9.3 % (Voc: 0.501 V, Jsc: 27.4 mA/cm2, F.F: 0.68) was obtained. The performance gain for Voc and F.F was more obvious in the thicker back reflectors, suggesting that the high-resistivity n-μc-SiO layer could reduce the shunt current at the back contacts of μc-Si:H cells.

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利用高阻低吸收背反射器改善微晶硅薄膜太阳能电池的性能

本文采用甚高频等离子体增强化学气相沉积(VHF-PECVD)技术，在不同的背向反射镜上制备了一系列微晶硅(μc-Si:H)太阳电池。结果表明，μc-Si:H太阳能电池的性能很大程度上取决于其背反射结构。首先，制备了具有不同光电性能的Al:ZnO薄膜，研究了其作为背反射材料对μc-Si:H太阳能电池性能的影响。不同于以往对a-Si:H太阳能电池的研究，所有具有不同Al:ZnO背反射体的μc-Si:H电池都表现出相似的I-V特性。然而，有趣的结果是，氧反应溅射制备的电阻率最高的后反射镜具有最佳的填充系数。下一步，引入具有高电阻率的n-μc-SiO层作为替代传统Al:ZnO的新型背反射材料。考虑到n-μc-SiO层的折射率在1.85以下，电阻率在1E+3 Ω·cm左右，红外区吸收光谱较低，选择了最佳沉积条件。当n-μc-SiO厚度大于300 nm时，电池各项参数均显著提高，转换效率高达9.3% (Voc: 0.501 V, Jsc: 27.4 mA/cm2, F.F: 0.68)。在较厚的背反射器中，Voc和F.F的性能增益更为明显，说明高电阻率n-μc-SiO层可以减小μc-Si:H电池背接触处的分流电流。

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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2011 37th IEEE Photovoltaic Specialists Conference

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