Title :
Two photon induced lasing in 1550 nm quantum dash optical gain media
Author :
Capua, A. ; Saal, A. ; Reithmaier, J.P. ; Yvind, K. ; Eisenstein, G.
Author_Institution :
Electr. Eng. Dept., Technion - Israel Inst. of Technol., Haifa, Israel
Abstract :
We report on a unique lasing mechanism observed in quantum dash Gain media. While the gain media is electrically pumped below lasing threshold, a strong optical pulse excites carriers by two photon absorption into high energy states of the quantum dashes and wetting layer. Fast inter band carrier relaxation and capture processes into the ground states of the quantum dashes result in increased gain followed by lasing at the gain peak irrespective of the stimulating pulse wavelength. The temporal response of the lasing line is examined on a 40 GHz scope and full characterization of the pulse by the XFROG scheme is performed. We show the lasing mechanism to be governed mainly by the wetting layer dynamics and extract a direct measurement of the carrier-carrier scattering time constant.
Keywords :
ground states; optical pumping; quantum dash lasers; quantum optics; wetting; XFROG scheme; capture processes; carrier-carrier scattering time constant; direct measurement; electrically pumped below lasing threshold; ground states; high energy states; inter band carrier relaxation; lasing line; lasing mechanism; optical pulse excites; photon absorption; photon induced lasing; quantum dash gain media; quantum dash optical gain media; quantum dashes; size 1550 nm; stimulating pulse wavelength; temporal response; wetting layer dynamics; Measurement by laser beam; Optical amplifiers; Optical filters; Optical pumping; Optical scattering; Quantum dots; Semiconductor device measurement;
Conference_Titel :
Optical Communication (ECOC), 2011 37th European Conference and Exhibition on
Conference_Location :
Geneva
Print_ISBN :
978-1-4577-1918-9
