Title :
Intersubband absorption saturation in InGaAs-AlAs-AlAsSb coupled quantum wells
Author :
Gopal, Achanta Venu ; Simoyama, Takasi ; Yoshida, Haruhiko ; Kasai, Jun-ichi ; Mozume, Teruo ; Ishikawa, Hiroshi
Author_Institution :
Femtosecond Technol. Res. Assoc. (FESTA), Tsukuba, Japan
Abstract :
This paper gives saturation (switching) energy (IS) estimates in an all-optic switch material based on absorption saturation in InGaAs-AlAs-AlAsSb coupled-double quantum wells (cDQWs). A model based on density matrix theory for a 4-level system is used to simulate the pulsed excitation conditions of the experiment in the communication wavelength region. The theoretical estimates are compared with experimentally determined values. A comparison of the IS in two different cDQWs (one with an indium composition in the well of about 53% and without an AlAs stopping layer at the well-barrier interface and another with 72% indium and an AlAs stopping layer) clearly shows that the samples with high indium content are of a better quality compared to those with lattice-matched indium composition (53%). An order-of-magnitude reduction in the IS in an all-optic switch based on cDQWs with high indium content is reported.
Keywords :
III-V semiconductors; aluminium compounds; gallium arsenide; indium compounds; optical saturable absorption; optical switches; semiconductor quantum wells; 4-level system; AlAs stopping layer; InGaAs-AlAs-AlAsSb; InGaAs-AlAs-AlAsSb coupled-double quantum wells; all-optic switch material; communication wavelength region; density matrix theory; intersubband absorption saturation; lattice-matched indium composition; order-of-magnitude reduction; pulsed excitation conditions; quality; saturation energy estimates; switching energy; Absorption; Bit rate; Communication networks; Communication switching; Conducting materials; Energy management; Estimation theory; Indium phosphide; Switches; Venus;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2003.818309
