Title :
Silicon-Based Light-Emitting Devices Based on Ge Self-Assembled Quantum Dots Embedded in Optical Cavities
Author :
Xu, Xuejun ; Narusawa, Sho ; Chiba, Taichi ; Tsuboi, Toshiki ; Xia, Jinsong ; Usami, Noritaka ; Maruizumi, Takuya ; Shiraki, Yasuhiro
Author_Institution :
Res. Center for Silicon Nano-Sci., Tokyo City Univ., Tokyo, Japan
Abstract :
Highly efficient light-emitting devices operating in 1.3-1.6 μm wavelength range are realized by combining optical cavities and Ge self-assembled quantum dots (QDs) grown on SOI wafers by molecular beam epitaxy (MBE). Different types of optical cavities, including photonic crystal (PhC) nanocavities, microdisks, and microrings, are fabricated to enhance the light emission efficiency at room temperature. Sharp resonant peaks with Q-factor on the order of 103 are observed in the micro-photoluminescence (μPL) spectrum. Through numerical simulation, these peaks are well identified as the corresponding cavity modes. The emission performances of these devices are also investigated by performing pumping-power- and geometric-parameter-dependent μPL measurements. The resonant wavelength, Q-factor, and emission intensity can be easily manipulated by these parameters.
Keywords :
Q-factor; elemental semiconductors; germanium; integrated optoelectronics; light emitting devices; micro-optics; microfabrication; molecular beam epitaxial growth; nanofabrication; nanophotonics; nanostructured materials; numerical analysis; optical fabrication; optical pumping; photoluminescence; photonic crystals; self-assembly; semiconductor quantum dots; silicon-on-insulator; Ge-Si; MBE; Q-factor; SOI wafers; cavity modes; emission intensity; emission performance; geometric-parameter-dependent microphotoluminescence measurements; light emission efficiency; microdisks; microphotoluminescence spectrum; microrings; molecular beam epitaxy; numerical simulation; optical cavities; photonic crystal nanocavities; pumping-power-dependent microphotoluminescence measurements; resonant wavelength; self-assembled quantum dots; silicon-based light-emitting devices; temperature 293 K to 298 K; wavelength 1.3 mum to 1.6 mum; Cavity resonators; Lattices; Optical device fabrication; Q factor; Quantum dots; Silicon; Stimulated emission; Ge self-assembled quantum dots (QDs); Light-emitting device; Purcell effect; microdisk; microring; photonic crystal (PhC) nanocavity;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2012.2206802
