Title :
Reorganized Porous Silicon Bragg Reflectors for Thin-Film Silicon Solar Cells
Author :
Duerinckx, F. ; Kuzma-Filipek, I. ; Van Nieuwenhuysen, K. ; Beaucarne, G. ; Poortmans, J.
Author_Institution :
IMEC, Heverlee
Abstract :
Stacks of porous silicon layers have been successfully applied to maximize internal reflection at the interface between a silicon substrate and an epitaxially grown layer. The stack is consist of alternating porous layers of high and low porosity, defined by the quarter-wavelength rule. During the hydrogen bake prior to epitaxial growth of the epitaxial layer, the porous silicon stack crystallizes in the form of thin quasi-monocrystalline silicon layers incorporating large voids. Experimental data of the measured external reflectance have been linked to the internal reflectance. An optical-path-length enhancement factor of seven was calculated in the wavelength range of 900-1200 nm. Application on thin-film epitaxial solar cells showed a 12% increase in short-circuit current and efficiency
Keywords :
Bragg gratings; elemental semiconductors; epitaxial growth; photovoltaic cells; porous materials; silicon; solar cells; thin film devices; 900 to 1200 nm; Si; epitaxial growth; epitaxially grown layer; hydrogen bake; optical-path-length enhancement factor; photovoltaic cells; porous silicon layers; porous silicon stack; reorganized porous silicon Bragg reflectors; silicon substrate; thin quasimonocrystalline silicon layers; thin-film silicon solar cells; Crystallization; Epitaxial growth; Epitaxial layers; Hydrogen; Optical reflection; Photovoltaic cells; Reflectivity; Semiconductor thin films; Silicon; Substrates; Bragg reflector; epitaxial layers; photovoltaic cells; porous silicon;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2006.883055
