Title :
Carrier transport in laser heterostructures
Author :
Kazarinov, R.F. ; Pinto, M.R.
Author_Institution :
AT&T Bell Labs., Murray Hill, NJ, USA
fDate :
1/1/1994 12:00:00 AM
Abstract :
We present two-dimensional numerical simulation of carrier transport in laser structures, which allows calculation of the efficiency of injected carrier consumption by the active region and the dependence of the laser current on applied voltage. It also allows calculation of the current, carrier, and potential distribution in a laser structure. This was done by use of PADRE, a program developed for the modeling of heterostructure electronic devices, which was supplemented with additional calculations of the laser optical properties. We applied this program to investigate the effect on the laser quantum efficiency of thermionic emission of electrons from the active layer. The temperature and current dependence of the laser internal quantum efficiency has been analyzed. This study allowed us to understand the performance of lasers with nearly ideal current-blocking structures
Keywords :
carrier density; digital simulation; electron-hole recombination; electronic engineering computing; laser theory; physics computing; semiconductor device models; semiconductor lasers; thermionic electron emission; PADRE; active region; applied voltage; carrier transport; current dependence; heterostructure electronic devices; injected carrier consumption efficiency; laser current; laser heterostructures; laser internal quantum efficiency; laser optical properties; laser quantum efficiency; laser structures; nearly ideal current-blocking structures; potential distribution; temperature dependence; thermionic electron emission; two-dimensional numerical simulation; Current density; Electron emission; Heterojunctions; Laser modes; Numerical simulation; Radiative recombination; Semiconductor lasers; Spontaneous emission; Thermionic emission; Voltage;
Journal_Title :
Quantum Electronics, IEEE Journal of
