Hydrogen passivation of multi-crystalline silicon solar cells

doi:10.1088/1009-1963/12/1/321

Abstract

Abstract The effects of hydrogen passivation on multi-crystalline silicon (mc-Si) solar cells are reported in this paper. Hydrogen plasma was generated by means of ac glow discharge in a hydrogen atmosphere. Hydrogen passivation was carried out with three different groups of mc-Si solar cells after finishing contacts. The experimental results demonstrated that the photovoltaic performances of the solar cell samples have been improved after hydrogen plasma treatment, with a relative increase in conversion efficiency up to 10.6%. A calculation modelling has been performed to interpret the experimental results using the model for analysis of microelectronic and photonic structures developed at Pennsylvania State University.

Keywords: multi-crystalline silicon solar cells plasma hydrogen passivation

Received: 21 June 2002
Revised: 19 September 2002
Accepted manuscript online:

PACS:	82.45.Bb	(Corrosion and passivation)
	84.60.Jt	(Photoelectric conversion)
	52.80.Hc	(Glow; corona)

Fund: Project supported by the State Key Development Programme for Basic Research of China (Grant No2000028201).

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Hu Zhi-Hua (胡志华), Liao Xian-Bo (廖显伯), Liu Zu-Ming (刘祖明), Xia Chao-Feng (夏朝凤), Chen Ting-Jin (陈庭金) Hydrogen passivation of multi-crystalline silicon solar cells 2003 Chinese Physics 12 112

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Hydrogen passivation of multi-crystalline silicon solar cells

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