Title :
Lasing mechanism of InGaN-GaN-AlGaN MQW laser diode grown on SiC by low-pressure metal-organic vapor phase epitaxy
Author :
Domen, K. ; Kuramata, A. ; Soejima, R. ; Horino, K. ; Kubota, S. ; Tanahashi, T.
Author_Institution :
Fujitsu Labs. Ltd., Atsugi, Japan
Abstract :
We studied the lasing mechanism of an InGaN-GaN-AlGaN multiquantum-well (MQW) laser diode by making various optical characterizations on the diode. Excitation power dependence of photoluminescence (PL) intensity was obtained to investigate the carrier recombination process of the laser. Surface emission and edge emission were compared by optical pumping to clarify where the lasing lines were located in relation to the absorption continuum. From the results, we demonstrate that lasing phenomena in our laser are dominated by free carriers. PL mapping was also taken on the same laser chip to examine the in-cavity bandgap inhomogeneity. We found a very large bandgap scattering of 100 meV. We also found that the wavelength distribution has a periodic modulation. We clarified that the various stimulated emission lines observed in our lasers are caused by the in-cavity spatial bandgap inhomogeneity of the InGaN MQW
Keywords :
III-V semiconductors; aluminium compounds; gallium compounds; indium compounds; optical pumping; photoluminescence; quantum well lasers; semiconductor growth; vapour phase epitaxial growth; 100 meV; InGaN-GaN-AlGaN; InGaN-GaN-AlGaN MQW laser diode; PL mapping; SiC; absorption continuum; carrier recombination process; edge emission; excitation power dependence; free carriers; in-cavity bandgap inhomogeneity; in-cavity spatial bandgap inhomogeneity; laser chip; lasing lines; lasing mechanism; lasing phenomena; low-pressure metal-organic vapor phase epitaxy; optical characterizations; optical pumping; periodic modulation; photoluminescence intensity; stimulated emission lines; surface emission; very large bandgap scattering; wavelength distribution; Diode lasers; Laser excitation; Optical pumping; Optical scattering; Photoluminescence; Photonic band gap; Pump lasers; Quantum well devices; Silicon carbide; Stimulated emission;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/2944.704106
