Abstract
Hydrogenated nanocrystalline silicon (nc-Si:H) thin film has received a great deal of attention as a promising material for flat panel display transistors, solar cells, etc. However, the multiphase structure of nc-Si:H leads to many defects. One of the major challenges is how to reduce the defects conveniently. In this work, we developed a simple and effective method to deposit low-defect-density nc-Si:H thin film. This method is simply by tuning the deposition pressure in a high-pressure range in plasma-enhanced chemical vapor deposition (PECVD) process. Microstructures of the nc-Si:H were characterized by Raman, AFM, and SEM. Furthermore, we focused on the defect density which was the key characteristic for photovoltaic materials and achieved the defect density of 3.766 × 1016 cm−3. This defect density is lower than that of previous studies on the fabrication of low-defect-density nc-Si:H by other complex methods in PECVD process. The minority carrier lifetime of nc-Si:H is thus greatly improved. Moreover, we demonstrated the mechanism about the effect of deposition pressure on the ion bombardment and proved that the defect density is the key characteristic for nc-Si:H photovoltaic material.
Highlights
An important landmark in the progress of thin film silicon technology is the development of high-quality hydrogenated nanocrystalline silicon
We have demonstrated the mechanism about the effect of deposition pressure on the ion bombardment, while previous reports just gave general discussions
Each spectrum under certain pressure can be deconvoluted into three Gaussian peaks: (1) a broad Gaussian distribution around 480 cm−1, which is attributed to the transverse optical (TO1) mode of amorphous silicon; (2) a peak near 520 cm−1, which belongs to the asymmetric TO2 vibrational mode of crystalline silicon [13, 14]; and (3) the peak around 506 cm−1 which is attributed to the intermediate range order
Summary
An important landmark in the progress of thin film silicon technology is the development of high-quality hydrogenated nanocrystalline silicon (nc-Si:H). As a result, increasing deposition pressure could raise the atomic hydrogen content. The electron density ne increases with the deposition pressure P.
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