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This paper reports that the optical emission spectroscopy (OES) is
used to monitor the plasma during the deposition process of
hydrogenated microcrystalline silicon films in a very high frequency
plasma enhanced chemical vapour deposition system. The OES
intensities (SiH\sj{*}, H微晶硅 VHF-PECVD 发射光谱学 薄膜物理学 microcrystalline silicon,
VHF-PECVD, optical emission spectroscopy 2005-11-09 2005-11-092005-12-12 This paper reports that the optical emission spectroscopy (OES) is used to monitor the plasma during the deposition process of hydrogenated microcrystalline silicon films in a very high frequency plasma enhanced chemical vapour deposition system. The OES intensities (Sill^*, H^* and H^*β) are investigated by varying the deposition parameters. The result shows that the discharge power, silane concentrations and substrate temperature affect the OES intensities. When the discharge power at silane concentration of 4% increases, the OES intensities increase first and then are constant, the intensities increase with the discharge power monotonously at silane concentration of 6%. The SiH^* intensity increases with silane concentration, while the intensities of H^*α and H^*β increase first and then decrease. When the substrate temperature increases, the SiH^* intensity decreases and the intensities of H^*α and H^*β are constant. The correlation between the intensity ratio of IH^*α/ISiH^* and the crystalline volume fraction (Xc) of films is confirmed. 相似文献
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Hydrogenated silicon (Si:H) thin films for application in solar cells were deposited
by using very high frequency plasma enhanced chemical vapour deposition (VHF PECVD)
at a substrate temperature of about 170℃. The electrical, structural, and
optical properties of the films were investigated. The deposited films were then
applied as i-layers for p-i-n single junction solar cells. The current--voltage
(I-V) characteristics of the cells were measured before and after the light
soaking. The results suggest that the films deposited near the transition region
have an optimum properties for application in solar cells. The cell with an i-layer
prepared near the transition region shows the best stable performance. 相似文献
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Effect of substrate temperature on the growth and properties of boron-doped microcrystalline silicon films 下载免费PDF全文
Highly conductive boron-doped hydrogenated microcrystalline silicon (\mu
c-Si:H) films are prepared by very high frequency plasma enhanced chemical
vapour deposition (VHF PECVD) at the substrate temperatures $T_{\rm S})$
ranging
from 90$^\circ$C to 270$^\circ$C. The effects of $T_{\rm S}$ on the growth and
properties of the films are investigated. Results indicate that the growth
rate, the electrical (dark conductivity, carrier concentration and Hall
mobility) and structural (crystallinity and grain size) properties are all
strongly dependent on $T_{\rm S}$. As $T_{\rm S}$ increases, it is
observed that 1)
the growth rate initially increases and then arrives at a maximum value of
13.3 nm/min at $T_{\rm S}$=210$^\circ$C, 2) the crystalline volume fraction
($X_{\rm c})$ and the grain size increase initially, then reach their maximum
values at $T_{\rm S}$=140$^\circ$C, and finally decrease, 3) the dark
conductivity ($\sigma _{\rm d})$, carrier concentration and Hall mobility have
a similar dependence on $T_{\rm S}$ and arrive at their maximum values at
$T_{\rm S}$=190$^\circ$C. In addition, it is also observed that at a lower
substrate temperature $T_{\rm S}$, a higher dopant concentration is required in
order to obtain a maximum $\sigma _{\rm d}$. 相似文献
5.
Influence of the deposition parameters on the transition region of hydrogenated silicon films growth 下载免费PDF全文
Hydrogenated microcrystalline and amorphous silicon thin films were prepared by very high frequency plasmaenhanced chemical vapour deposition (VHF PECVD) by using a mixture of silane and hydrogen as source gas. The influence of deposition parameters on the transition region of hydrogenated silicon films growth was investigated by varying the silane concentration (SC), plasma power (Pw), working pressure (P), and substrate temperature (Ts). Results suggest that SC and Ts are the most critical factors that affect the film structure transition from microcrystalline to amorphous phase. A narrow region in the range of SC and Ts, in which the rapid phase transition takes place, was identified. It was found that at lower P or higher Pw, the transition region is shifted to larger SC. In addition, the dark conductivity and photoconductivity decrease with SC and show sharp changes in the transition region. It proposed that the transition process and the transition region are determined by the competition between the etching effect of atomic hydrogen and the growth of amorphous phase. 相似文献
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Effect of substrate temperature and pressure on properties of microcrystalline silicon films 下载免费PDF全文
In this paper intrinsic microcrystalline silicon films have been prepared by very high
frequency plasma enhanced chemical vapour deposition (VHF-PECVD) with
different substrate temperature and pressure. The film properties were
investigated by using Raman spectra, x-ray diffraction, scanning
electron microscope (SEM), and optical
transmittance measurements, as well as dark conductivity. Raman results
indicate that increase of substrate temperature improves the microcrystallinity
of the film. The crystallinity is improved when the pressure increases from
50Pa to 80Pa and the structure transits from microcrystalline to amorphous
silicon for pressure higher than 80Pa. SEM reveals the effect of substrate
temperature and pressure on surface morphology. 相似文献
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