Title :
Quantum cascade lasers with double-quantum-well superlattices
Author :
Wanke, M.C. ; Capasso, F. ; Gmachl, C. ; Tredicucci, A. ; Sivco, D.L. ; Hutchinson, A.L. ; Cho, A.Y.
Author_Institution :
Lucent Technol. Bell Labs., Murray Hill, NJ, USA
fDate :
4/1/2001 12:00:00 AM
Abstract :
A quantum-cascade laser using a double-quantum-well graded superlattice as the active region is presented. Each SL period consists of two strongly coupled quantum wells resulting in the splitting of the lowest miniband into two minibands. These two minibands can be designed to be flat and to contain delocalized, spatially symmetric wavefunctions under an applied electric field which in turn leads to a high optical dipole for the interminiband transition. In addition, the new design allows independent control of the energy levels of the lowest two minibands, their width and the splitting separating them, enhancing design flexibility. Using a cascade design of 55 pairs of alternated active regions and injectors, pulsed laser action is achieved at /spl lambda/=11.6 μm. Peak output powers reach 120 mW at 7 K and approximately 12 mW at the maximum operating temperature of 195 K."
Keywords :
III-V semiconductors; gallium arsenide; indium compounds; laser transitions; quantum well lasers; semiconductor superlattices; symmetry; 11.6 mum; 12 mW; 120 mW; 195 K; 7 K; InGaAs; active region; alternated active regions; applied electric field; cascade design; delocalized spatially symmetric wavefunctions; design flexibility; double-quantum-well superlattices; energy levels; high optical dipole; interminiband transition; maximum operating temperature; miniband; peak output powers; pulsed laser action; quantum cascade lasers; strongly coupled quantum wells; Energy states; Laser transitions; Optical design; Optical superlattices; Power generation; Power lasers; Quantum cascade lasers; Quantum well lasers; Semiconductor lasers; Stationary state;
Journal_Title :
Photonics Technology Letters, IEEE
