Development of amorphous silicon-germanium and nanocrystalline silicon based multi-junction solar cell technology for GW-scale manufacturing

2013 IEEE 39th Photovoltaic Specialists Conference (PVSC) Pub Date : 2013-06-16 DOI:10.1109/PVSC.2013.6744128

Xixiang Xu, Jinyan Zhang, Chongyan Lian, A. Hu, X. Ru, Cao Yu, C. Peng, M. Qu, Xinghong Zhou, Jianqiang Wang, Xiaohua Xu, F. Lin, Xiaodang Zhang, Ying Zhao, Yinchun Zhang, Hongqing Shan, Yuanmin Li

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Abstract

Though thin film silicon has evolved into an important technology for photovoltaic industry, further increasing its conversion efficiency remains to be a key task. In this work, we report the progress we have made in developing compatible nanocrystalline Si (nc-Si) technology with our existing amorphous silicon germanium (a-SiGe) based multi-junction solar cell manufacturing lines. We have conducted experiments mainly on two types of nc-Si based solar cell structures, a-Si/a-SiGe/nc-Si triple-junction and a-Si/nc-Si double-junction device. Currently we are attaining initial total area efficiency of 10.7% and 12.4% for the triple- and double-junction structures, respectively, on substrate size of 0.79 m2 (1.245 m × 0.635 m). Experimental results including study of crystalline volume fraction along nc-Si growth, individual component cell optimization and current match, development of superior tunnel-junction and contact layers are presented.

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基于非晶硅锗和纳米晶硅的多结太阳能电池技术的发展

虽然薄膜硅已经发展成为光伏产业的重要技术，但进一步提高其转换效率仍然是一个关键的任务。在这项工作中，我们报告了我们在开发兼容纳米晶硅(nc-Si)技术与我们现有的基于非晶硅锗(a-SiGe)的多结太阳能电池生产线方面所取得的进展。我们主要对两种基于nc-Si的太阳能电池结构进行了实验，a-Si/a-SiGe/nc-Si三结器件和a-Si/nc-Si双结器件。目前，我们在0.79 m2 (1.245 m × 0.635 m)的衬底上获得了三结和双结结构的初始总面积效率分别为10.7%和12.4%。实验结果包括nc-Si生长过程中晶体体积分数的研究，单个组件电池优化和电流匹配，优越隧道结和接触层的开发。

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2013 IEEE 39th Photovoltaic Specialists Conference (PVSC)

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