Hydrogenated Nano-Crystalline Silicon Thin Films in SiO2 Matrix for Next Generation Solar Cells Using Glow Discharged Decomposition

Journal of Materials Science Research Pub Date : 2018-12-31 DOI:10.5539/JMSR.V8N1P25

M. Syed, C. Hynes, Brittany Anderson, T. S. Ahmadi, B. Goh, Nur Fatin Farhanah binti Nazarudin, M. Syed, A. Ali

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Abstract

Hydrogenated Nanocrystalline Silicon (nc-Si:H) thin films using SiH4/H2 mixture by glow discharged decomposition were investigated on c-Si and glass substrates. The effects of substrate temperature on the Structural, Optical and Electrical properties of the films were investigated by X-ray diffraction, Raman scattering, FT/IR, Optical transmission and Atomic Force Microscopy (AFM). Substrate temperatures ([TSB]) of the films were changed from 100oC to 250oC. It has been revealed the strong dependence on the film’s properties with the substrate temperatures. XRD and Raman measurements were shown that the higher substrate temperature (250oC) exhibits the highest crystalline volume fraction ([ρ] = 95%) and the lowest crystalline size ([Ω] = 3.5 nm) as well, having the highest H-content and the lowest O-content. At 250oC, the lowest mobility and the highest resistivity were also found to be ~37.5 cm2/v.s and 7.35 Ω-cm. Refractive index and the optical energy gap (Eg) were estimated by 3.8 and 1.9 eV having the growth rate of 4.2 nm/min. At 250oC, it was resulted in a blue shift of the absorption edge having uniform grain distributions. Results indicate that in situ hydrogen cleaning effects is prominent and localized orderly high density Si-Si bonds are exhibiting quantum size effects at highest substrate temperature.

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利用辉光放电分解技术制备新一代太阳能电池的SiO2基氢化纳米晶硅薄膜

在c-Si衬底和玻璃衬底上研究了以SiH4/H2混合物为基材，通过辉光分解制备氢化纳米晶硅薄膜。采用x射线衍射、拉曼散射、红外光谱、透射光谱和原子力显微镜(AFM)研究了衬底温度对薄膜结构、光学和电学性能的影响。薄膜的衬底温度([TSB])从100℃变化到250℃。结果表明，薄膜的性能与衬底温度密切相关。XRD和Raman测试结果表明，衬底温度越高(250℃)，晶体体积分数越高([ρ] = 95%)，晶粒尺寸越小([Ω] = 3.5 nm)， h含量越高，o含量越低。在250℃时，迁移率最低，电阻率最高，为~37.5 cm2/v。S和7.35 Ω-cm。折射率和光能隙(Eg)分别为3.8和1.9 eV，增长率为4.2 nm/min。在250℃时，吸收边出现蓝移，晶粒分布均匀。结果表明，在最高衬底温度下，原位氢清洗效应显著，局域有序高密度Si-Si键表现出量子尺寸效应。

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Journal of Materials Science Research

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