Optical Annealing of Black Silicon

Abstract

Silicon hyperdoped with chalcogens using femtosecond (fs) laser irradiation (“black silicon”) shows strong broad-band absorption due to intermediate band formation and surface texturing; thus, this material has promise for advanced optoelectronic devices such as silicon-based infrared photodetectors and intermediate band solar cells. To reduce structural defects and form a rectifying junction after fs laser irradiation, however, annealing is necessary, which deactivates the optical effect of the dopant. Here, we investigated the use of laser-based optical annealing using nanosecond (ns) excimer pulses and found that it removes amorphous material resulting from the black silicon fabrication process while maintaining high above-bandgap and sub-bandgap absorption. We also studied the effect of ns optical annealing on the surface morphology of black silicon.

FormalPara Abstract

Silicon hyperdoped with chalcogens using femtosecond (fs) laser irradiation (“black silicon”) shows strong broad-band absorption due to intermediate band formation and surface texturing; thus, this material has promise for advanced optoelectronic devices such as silicon-based infrared photodetectors and intermediate band solar cells. To reduce structural defects and form a rectifying junction after fs laser irradiation, however, annealing is necessary, which deactivates the optical effect of the dopant. Here, we investigated the use of laser-based optical annealing using nanosecond (ns) excimer pulses and found that it removes amorphous material resulting from the black silicon fabrication process while maintaining high above-bandgap and sub-bandgap absorption. We also studied the effect of ns optical annealing on the surface morphology of black silicon.