Properties of Functional Decorative Silicon Oxide Films Prepared by PECVD

doi:10.11901/1005.3093.2018.607

Chinese Journal of Materials Research

2019, Vol. 33

Issue (6): 467-474 DOI: 10.11901/1005.3093.2018.607

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Properties of Functional Decorative Silicon Oxide Films Prepared by PECVD

Dong ZHANG¹,Peiling KE¹(

),Aiying WANG¹(

),Xiangyong WANG²,Li ZHI²

1. Key Laboratory of Marine Materials and Related Technologies, Zhejiang Key Laboratory of Marine Materials and Protective Technologies, Ningbo Institute of Materials Technology and Engineering, Chinese Academy of Sciences, Ningbo 315201, China
2. Ningbo Zhong-Jun Sen-Chi Auto Parts Limited by Share Ltd. , Cixi 315300, China

Cite this article:

Dong ZHANG,Peiling KE,Aiying WANG,Xiangyong WANG,Li ZHI. Properties of Functional Decorative Silicon Oxide Films Prepared by PECVD. Chinese Journal of Materials Research, 2019, 33(6): 467-474.

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Abstract

Silicon oxide films were prepared on silicon- and quartz-substrate by plasma enhanced chemical vapor deposition (PECVD) technique. The dependence of composition, structure and properties of the films were investigated on the location of substrates in the reaction chamber, namely, which were fixed onto either cathode- or anode-electrode plate. Meanwhile, the preparation of functional decorative silicon oxide films with high transparency and scratch resistance was assessed in terms of processing parameters. The results show that the film synthesized on the substrate attached to anode is organosilicon oxide of Si (CH₃)_nO with transmittance of as high as 90%~98% in the wavelength range of 380-780 nm, unfortunately, the film is loose with hardness of only 2 GPa. However, the hardness of the film can be increased to 6 GPa by increasing the substrate temperature, as a result, the transmittance of the film decreases slightly; The film synthesized on the substrate attached to the cathode composes of inorganic silicon oxide and amorphous carbon. That film is compact with hardness of up to 15 GPa, but poor transmittance in the wavelength range of 380~780 nm. Increasing the O₂-flux can promote the reaction of carbon and oxygen to produce carbon dioxide, thereby to eliminate the amorphous carbon. Therefore, the transmittance of the film increases to 99%, but the hardness decreases down to 9 GPa.

Key words: surface and interface in the materials silicon oxide films PECVD functional decoration

Received: 12 October 2018

ZTFLH:

TB34

Fund: Ningbo Municipal Key Technologies R & D Program of China(No. 2017B10042);Cixi Municipal Technologies R & D Program of China(No. 2015A07)

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	Dong ZHANG
	Peiling KE
	Aiying WANG
	Xiangyong WANG
	Li ZHI

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https://www.cjmr.org/EN/10.11901/1005.3093.2018.607 OR https://www.cjmr.org/EN/Y2019/V33/I6/467

Fig.1 Schematic diagram of silicon oxide films preparation equipment

Fig.2 Cross-sectional micro-morphology of cathode films (a, b) and anode films (c, d)

Fig.3 Infrared absorption spectra of anode films and cathode films

Fig.4 Raman spectra of anode films and cathode films

Fig.5 Si2p peak in XPS spectrum of anode films and cathode films

Fig.6 Transmittance of anode films and cathode films in visible light range

Fig.7 Nanoindentation test results of anode films and cathode films

Fig.8 Cross-sectional micro-morphology of anode film formed at 250℃

Fig.9 Infrared absorption spectra of anode films prepared at different temperatures

Fig.10 Si2p peak in XPS spectrum of anode films prepared at different temperatures

Fig.11 Nanoindentation test results of anode films prepared at different temperatures

Fig.12 Transmittance of anode films in visible light range prepared at different temperatures

Fig.13 Cross-sectional micro-morphology of cathode film after increasing oxygen reaction gas

Fig.14 Infrared absorption spectra of cathode films at different gas sources

Fig.15 Si2p peak in XPS spectrum of cathode films at different gas sources

Fig.16 Transmittance of cathode films in visible light range at different gas sources

Fig.17 Nanoindentation test results of cathode films at different gas sources

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