Reduction in a-Si:H density utilizing a secondary plasma

IF 2.3 2区物理与天体物理 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Journal of Micro/Nanolithography, MEMS, and MOEMS Pub Date : 2019-10-01 DOI:10.1117/1.JMM.18.4.044502

Jan Uhilg, D. Barlaz, D. Ruzic

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Abstract

Abstract. Following the need to improve packaging and contact layers for photovoltaics and other optoelectronic applications, a renewed interest in the fabrication of thin, low-density silicon films has arisen. We demonstrate a reactive sputtering technique utilizing a secondary plasma to crack hydrogen gas during physical vapor deposition of silicon layers. Cracking efficiency of the gas varies heavily with pressure and power from under 10% to nearly 100% conversion to hydrogen radicals. Radicals incorporated into the film produce amorphous silicon films with densities as low as 1.73 g / cm3, compared to 2.2 g / cm3 in their nonhydrogenated counterparts. Reduced density films likewise have a reduction in index of refraction comparable to other hydrogenated amorphous silicon produced by other techniques with indices close to 2 across the visible portion of the spectrum. Our work represents a useful, scalable advance in the production of amorphous hydrogenated silicon for a variety of applications requiring large areas.

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利用二次等离子体降低a- si:H密度

摘要由于需要改进光伏和其他光电应用的封装和接触层，人们对制造薄而低密度的硅薄膜产生了新的兴趣。我们展示了一种反应溅射技术，利用二次等离子体在硅层的物理气相沉积过程中裂解氢气。氢气自由基的裂解效率随压力和功率变化很大，从低于10%到接近100%。自由基加入到薄膜中产生密度低至1.73 g / cm3的非晶硅薄膜，而非氢化的薄膜密度为2.2 g / cm3。同样，低密度薄膜的折射率降低，与其他技术生产的其他氢化非晶硅相比，在光谱可见部分的折射率接近2。我们的工作代表了非晶氢化硅生产的有用的、可扩展的进步，适用于各种需要大面积的应用。

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