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J Electr Electron Mater : Journal of Electrical and Electronic Materials

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"Co-firing"

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"Co-firing"

The Analysis on the Effect of Improving Aspect Ratio and Electrode Spacing of the Crystalline Silicon Solar Cell
Min Young Kim, Ju Eok Park, Hae Sung Cho, Dae Sung Kim, Seong Kyun Byeon, Dong Gun Lim
J Electr Electron Mater 2014;27(4):209-216.   Published online April 1, 2014
The screen printed technique is one of the electrode forming technologies for crystalline silicon solar cell. It has the advantage that can raise the production efficiency due to simple process. The electrode technology is the core process because the electrode feature is given a substantial factor (for solar cell efficiency). In this paper, we tried to change conditions such as squeegee angle 55∼75°, snap off 0.5∼1.75mm, printing pressure 0.6∼0.3 MPa and 1.6∼2.0 mm finger spacing. As a result, the screen printing process showed an improved performance with an increased height higher finger height. Optimization of fabrication process has achieved 17.48% efficiency at screen mesh of 1.6 mm finger spacing.
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Energy Materials : Co-firing Optimization of Crystalline Silicon Solar Cell Using Rapid Thermal Process
Byoung Jin Oh, In Hwan Yeo, Dong Gun Lim
J Electr Electron Mater 2012;25(3):236-240.   Published online March 1, 2012
Limiting thermal exposure time using rapid thermal processing(RTP) has emerged as promising simplified process for manufacturing of solar cell in a continuous way. This paper reports the simplification of co-firing using RTP. Actual temperature profile for co-firing after screen printing is a key issue for high-quality metal-semiconductor contact. The plateau time during the firing process were varied at 450℃ for 10~16 sec. Glass frit in Ag paste etch anti-reflection layer with plateau time. Glass frit in Ag paste is important for the Ag/Si contact formation and performances of crystalline Si solar cell. We achieved 17.14% efficiency with optimum conditions.
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