Airbrush Coated PEDOT:PSS Back Contacts for Silicon Solar Cells

2020 2nd International Conference on Photovoltaic Science and Technologies (PVCon) Pub Date : 2020-11-30 DOI:10.1109/PVCon51547.2020.9757726

Deniz Turkay, Batuhan Ülkütaşır, Kerem Artuk, Elif Cüce, K. Tsoi, S. Yerci

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Abstract

In this work, we demonstrate the use of an in-house built automated airbrush system to spray coat PEDOT:PSS layers on p-type silicon surfaces. We identify the effects of chemical additives on spraying reliability and show that the addition of a fluorosurfactant can provide a clog-free operation that is suitable for laboratory use. Next, we analyze the influence of hot plate temperature and nozzle height on the saturation current density (J0s) of PEDOT:PSS on mirror polished silicon. The silicon surface has either a wet chemically grown silicon oxide or the oxide stripped away by dipping into a hydrofluoric (HF) acid solution. For the samples with chemical oxides, J0s values below 30 fA/cm2 are achieved at an optimal hot plate temperature of ~180 °C. For HF-dipped samples, the J0s values are larger than 75 fA/cm2 and there is no clear dependency on plate temperature. Finally, we demonstrate the device performance using 2×2 cm2 silicon solar cells with double side pyramid texturing, phosphorus diffused front emitters and spray-coated PEDOT:PSS back contacts deposited on single side HF processed surfaces. We achieve the best cell performances at 100 °C and demonstrate a power conversion efficiency of 16.2%.

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喷枪涂覆PEDOT:PSS硅太阳能电池背面触点

在这项工作中，我们演示了使用内部构建的自动喷枪系统在p型硅表面喷涂PEDOT:PSS层。我们确定了化学添加剂对喷涂可靠性的影响，并表明添加含氟表面活性剂可以提供适合实验室使用的无堵塞操作。其次，我们分析了热板温度和喷嘴高度对镜面抛光硅表面PEDOT:PSS饱和电流密度(J0s)的影响。硅表面要么是湿的化学生长的氧化硅，要么是通过浸入氢氟酸溶液剥离掉的氧化物。对于含有化学氧化物的样品，在~180℃的最佳热板温度下，J0s值低于30 fA/cm2。对于浸hf的样品，J0s值大于75 fA/cm2，并且与板温没有明显的相关性。最后，我们使用2×2 cm2双面金字塔结构的硅太阳能电池，磷扩散前发射器和喷涂的PEDOT:PSS后触点沉积在单面HF加工表面上，展示了器件的性能。我们在100°C下实现了最佳电池性能，并证明了16.2%的功率转换效率。

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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来源期刊

2020 2nd International Conference on Photovoltaic Science and Technologies (PVCon)

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