Title :
Engineering of the nonradiative transition rates in modulation-doped multiple-quantum wells
Author :
Veliadis, J.V.D. ; Khurgin, J.B. ; Ding, Y.J.
Author_Institution :
Dept. of Electr. & Comput. Eng., Johns Hopkins Univ., Baltimore, MD, USA
fDate :
7/1/1996 12:00:00 AM
Abstract :
The feasibility of the enhancement of the acoustic-phonon limited intersubband transition rate through impurity scattering has been theoretically investigated in double asymmetric-coupled quantum wells. The dependence of the acoustic-phonon rate on the barrier thickness and the effect of the position of the δ-doped region on the impurity rate have been treated rigorously. A 10-Å-doped region with a 10 10-cm-2-sheet density can enhance the acoustic-phonon transition limit by more than an order of magnitude. This allows for the design of intersubband lasers in which population inversion between acoustic-phonon limited discrete conduction-band states is achieved by impurity scattering and control of barrier thickness
Keywords :
conduction bands; impurity scattering; laser theory; laser transitions; phonons; population inversion; quantum well lasers; δ-doped region; acoustic-phonon limited discrete conduction-band states; acoustic-phonon limited intersubband transition rate; acoustic-phonon rate; acoustic-phonon transition limit; barrier thickness; double asymmetric-coupled quantum wells; impurity rate; impurity scattering; intersubband laser design; modulation-doped multiple-quantum wells; nonradiative transition rates; population inversion; quantum well lasers; sheet density; Acoustic scattering; Epitaxial layers; Impurities; Laser transitions; Optical scattering; Optical superlattices; Particle scattering; Phonons; Stationary state; Stimulated emission;
Journal_Title :
Quantum Electronics, IEEE Journal of
