Copper as conducting layer in advanced front side metallization processes for crystalline silicon solar cells, exceeding 20% on printed seed layers

J. Bartsch, A. Mondon, C. Schetter, M. Horteis, S. Glunz
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引用次数: 22

Abstract

Our work deals with the creation of copper-containing stack systems for the front side metallization of silicon solar cells. In this contribution, we give an overview of different approaches from our labs. We have developed processes to apply nickel diffusion barriers onto seed layers and directly onto silicon with both electrolytic and electroless processes. These are reinforced by a light-induced copper plating process. On aerosol-printed seed layers, cell efficiencies equal to those of reference cells with advanced silver metallization have been achieved with a nickel/copper/tin stack system (16.8% on 5×5cm2 industrial Cz-material, 20.3% on FZ high-efficiency substrates, 2×2cm2). As the long term stability of the resulting cells is a critical factor, there is need for a method to characterize this aspect. We developed a thermally accelerated ageing procedure, mirroring the total copper diffusion during a typical cell life cycle. Solar cells with advanced metal stack systems have shown no significant decrease in performance during this thermal stress test.
在先进的晶硅太阳能电池正面金属化工艺中,铜作为导电层,在印刷种子层中超过20%
我们的工作涉及为硅太阳能电池的正面金属化创建含铜堆栈系统。在这篇文章中,我们概述了来自我们实验室的不同方法。我们已经开发了将镍扩散屏障应用于种子层的工艺,并通过电解和化学工艺直接应用于硅上。这些都是通过光诱导镀铜工艺加强。在气溶胶印刷的种子层上,电池效率等于采用镍/铜/锡堆系统的先进银金属化参考电池的效率(在5×5cm2工业cz材料上为16.8%,在FZ高效衬底上为20.3%,2×2cm2)。由于所得到的细胞的长期稳定性是一个关键因素,因此需要一种方法来表征这方面。我们开发了一种热加速老化程序,反映了典型细胞生命周期中铜的总扩散。采用先进金属堆系统的太阳能电池在热应力测试中没有表现出明显的性能下降。
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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