三晶硅在太阳能电池加工过程中的扩散长度

Conference Record of the Twenty Sixth IEEE Photovoltaic Specialists Conference - 1997 Pub Date : 1997-12-31 DOI:10.1109/PVSC.1997.653942

W. Kusian, Hans-Christoph Ostendorf, J. Palm, A.L. Endros

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引用次数: 1

摘要

低成本和高效率正推动晶体硅太阳能电池向更薄晶圆方向发展。关于高效率的最佳晶圆厚度约为60-100 /spl mu/m。三晶硅是一种很有希望进入生产规模的材料。它显示出改进的机械稳定性，可以锯成更薄的晶圆。利用横向分辨的ELYMAT技术，通过在太阳能电池的每个工艺步骤后进行的扩散长度测量来研究电性能。根据损伤蚀刻工艺的不同，扩散长度L在100 ~ 300 μ m /spl μ m之间。对于碱性蚀刻晶圆，发现了L与蚀刻坑密度之间的相关性。扩散后，扩散长度增加到400 /spl mu/m和500 /spl mu/m之间，即使在后续处理步骤中也保持在该水平。

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Diffusion length of tri-crystalline silicon during solar cell processing

Low costs and high efficiency are driving the development of crystalline silicon solar cells towards thinner wafers. The optimum wafer thickness with respect to high efficiencies is around 60-100 /spl mu/m. Tri-crystalline silicon is a promising material to enter this region on production scale. It shows an improved mechanical stability and can be sawn into thinner wafers. The electric properties are investigated by diffusion length measurements performed after each solar cell process step with the laterally resolved ELYMAT technique. Depending on the damage etching process the diffusion length L is between 100 and 300 /spl mu/m. For alkaline etched wafers a correlation between L and the etch pit density is found. After emitter diffusion the diffusion length increases to values between 400 /spl mu/m and 500 /spl mu/m and stays at that level even for subsequent processing steps.

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Conference Record of the Twenty Sixth IEEE Photovoltaic Specialists Conference - 1997

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