Electrical property of iron-related defects in n-type dislocated Czochralski silicon crystal used for solar cells

Abstract: Interactions of iron atoms with dislocations in n-type Czochralski silicon have been studied by combining deep level transient spectroscopy (DLTS) and electron beam induced current (EBIC). The EBIC results indicate that dislocations facilitate the aggregation of iron atoms. The DLTS reveals three levels K1 (E c—0.17 eV), K2 (E c—0.35 eV) and K3 (E c—0.48 eV). The amplitudes of K2 and K3 peaks exhibit extended localized states. The origin of levels K2 and K3… Show more

“…6,8,9) Electron-beam-induced current (EBIC) is a powerful technique for revealing the recombination activity of defects in crystalline silicon. [10][11][12] By analyzing the dependence of EBIC contrast on temperatures, the electronic characteristics of energy levels induced by defects can be effectively studied. 13,14) Previous studies indicated that dislocationsrelated recombination sites might be mainly responsible for the carrier recombination at oxygen precipitates.…”

Electrical properties of oxygen precipitate-related defects in Czochralski silicon

“…6,8,9) Electron-beam-induced current (EBIC) is a powerful technique for revealing the recombination activity of defects in crystalline silicon. [10][11][12] By analyzing the dependence of EBIC contrast on temperatures, the electronic characteristics of energy levels induced by defects can be effectively studied. 13,14) Previous studies indicated that dislocationsrelated recombination sites might be mainly responsible for the carrier recombination at oxygen precipitates.…”

Electrical properties of oxygen precipitate-related defects in Czochralski silicon

Comprehensive characterization of efficiency limiting defects in the swirl-shaped region of Czochralski silicon